AD7124-4BBCPZ-RL7 - ANALOG DEVICES

4-Channel, Low Noise, Low Power, 24-Bit,

Sigma-Delta ADC with PGA and Reference

Data Sheet

AD7124-4

Rev. D Document Feedback

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FEATURES

3 power modes

RMS noise

Low power: 24 nV rms at 1.17 SPS, gain = 128 (255 µA typical)

Mid power: 20 nV rms at 2.34 SPS, gain = 128 (355 µA typical)

Full power: 23 nV rms at 9.4 SPS, gain = 128 (930 µA typical)

Up to 22 noise free bits in all power modes (gain = 1)

Output data rate

Full power: 9.38 SPS to 19,200 SPS

Mid power: 2.34 SPS to 4800 SPS

Low power: 1.17 SPS to 2400 SPS

Rail-to-rail analog inputs for gains > 1

Simultaneous 50 Hz/60 Hz rejection at 25 SPS (single cycle

settling)

Diagnostic functions (which aid safe integrity level (SIL)

certification)

Crosspoint multiplexed analog inputs

4 differential/7 pseudo differential inputs

Programmable gain (1 to 128)

Band gap reference with 10 ppm/°C drift maximum (70 µA)

Matched programmable excitation currents

Internal clock oscillator

On-chip bias voltage generator

Low-side power switch

General-purpose outputs

Multiple filter options

Internal temperature sensor

Self and system calibration

Sensor burnout detection

Automatic channel sequencer

Per channel configuration

Power supply: 2.7 V to 3.6 V and ±1.8 V

Independent interface power supply

Power-down current: 5 µA maximum

Temperature range: −40°C to +125°C

32-lead LFCSP/24-lead TSSOP

3-wire or 4-wire serial interface

SPI, QSPI, MICROWIRE, and DSP compatible

Schmitt trigger on SCLK

ESD: 4 kV

APPLICATIONS

Temperature measurement

Pressure measurement

Industrial process control

Instrumentation

Smart transmitters

FUNCTIONAL BLOCK DIAGRAM

TEMPERATURE

SENSOR

BANDGAP

REF

VBIAS

SERIAL

INTERFACE

AND

CONTROL

LOGIC

INTERNAL

CLOCK CLK

SCLK

DIN

SYNC

REGCAPD

IOVDD

AD7124-4

AVSS DGND

24-BIT

Σ-Δ ADC

X-MUX

REFIN1(+)

AVDD

AVSS

REFOUT

AVDD

AVSS

PSW

VARIABLE

DIGITAL

FILTER

DIAGNOSTICS

COMMUNICATIONS

POWER SUPPLY

SIGNAL CHAIN

DIGITAL

REFIN1(–)

REFIN2(+)

REFIN2(–)

BURNOUT

DETECT

EXCITATION

CURRENTS

POWER

SWITCH

GPOs

CHANNEL

SEQUENCER

CROSSPOINT

MUX

REGCAPAAVDD

1.9V

LDO

DIAGNOSTICS

AVDD

AVSS

DOUT/RDY

1.8V

LDO

ANALOG

BUFFERS

REFERENCE

BUFFERS

BUF

PGA2PGA1

AIN0/IOUT/VBIAS

AIN1/IOUT/VBIAS

AIN2/IOUT/VBIAS/P1

AIN3/IOUT/VBIAS/P2

AIN4/IOUT/VBIAS

AIN5/IOUT/VBIAS

AIN6/IOUT/VBIAS/REFIN2(+)

AIN7/IOUT/VBIAS/REFIN2(–)

13197-001

Figure 1.

AD7124-4 Data Sheet

Rev. D | Page 2 of 93

TABLE OF CONTENTS

Features .............................................................................................. 1

Applications ....................................................................................... 1

Functional Block Diagram .............................................................. 1

Revision History ............................................................................... 3

General Description ......................................................................... 5

Specifications ..................................................................................... 6

Timing Characteristics .............................................................. 11

Absolute Maximum Ratings .......................................................... 14

Thermal Resistance .................................................................... 14

ESD Caution ................................................................................ 14

Pin Configurations and Function Descriptions ......................... 15

Typical Performance Characteristics ........................................... 18

Terminology .................................................................................... 27

RMS Noise and Resolution............................................................ 28

Full Power Mode ......................................................................... 28

Mid Power Mode ........................................................................ 31

Low Power Mode ........................................................................ 34

Getting Started ................................................................................ 37

Overview ...................................................................................... 37

Power Supplies ............................................................................ 38

Digital Communication ............................................................. 38

Configuration Overview ........................................................... 40

ADC Circuit Information .............................................................. 45

Analog Input Channel ............................................................... 45

External Impedance When Using a Gain of 1 ........................ 46

Programmable Gain Array (PGA) ........................................... 47

Reference ..................................................................................... 47

Bipolar/Unipolar Configuration .............................................. 47

Data Output Coding .................................................................. 48

Excitation Currents .................................................................... 48

Bridge Power-Down Switch ...................................................... 49

Logic Outputs.............................................................................. 49

Bias Voltage Generator .............................................................. 49

Clock ............................................................................................ 49

Power Modes ............................................................................... 49

Standby and Power-Down Modes ............................................ 49

Digital Interface .......................................................................... 50

DATA_STATUS .......................................................................... 52

Serial Interface Reset (DOUT_RDY_DEL and CS_EN Bits) 52

Reset ............................................................................................. 52

Calibration................................................................................... 53

Span and Offset Limits .............................................................. 54

System Synchronization ............................................................ 54

Digital Filter .................................................................................... 55

Sinc4 Filter ................................................................................... 55

Sinc3 Filter ................................................................................... 57

Fast Settling Mode (Sinc4 + Sinc1 Filter) .................................. 59

Fast Settling Mode (Sinc3 + Sinc1 Filter) .................................. 61

Post Filters ................................................................................... 63

Summary of Filter Options ....................................................... 66

Diagnostics ...................................................................................... 67

Signal Chain Check .................................................................... 67

Reference Detect ......................................................................... 67

Calibration, Conversion, and Saturation Errors .................... 67

Overvoltage/Undervoltage Detection ..................................... 67

Power Supply Monitors ............................................................. 68

LDO Monitoring ........................................................................ 68

MCLK Counter ........................................................................... 68

SPI SCLK Counter...................................................................... 68

SPI Read/Write Errors ............................................................... 69

SPI_IGNORE Error ................................................................... 69

Checksum Protection ................................................................ 69

Memory Map Checksum Protection ....................................... 69

ROM Checksum Protection...................................................... 70

Burnout Currents ....................................................................... 71

Temperature Sensor ................................................................... 71

Grounding and Layout .................................................................. 72

Applications Information .............................................................. 73

Temperature Measurement Using a Thermocouple .............. 73

Temperature Measurement Using an RTD ............................. 74

Flowmeter .................................................................................... 76

On-Chip Registers .......................................................................... 78

Communications Register ......................................................... 79

Status Register ............................................................................. 79

ADC_CONTROL Register ....................................................... 80

Data Register ............................................................................... 82

IO_CONTROL_1 Register........................................................ 82

IO_CONTROL_2 Register........................................................ 84

ID Register................................................................................... 84

Error Register .............................................................................. 84

Data Sheet AD7124-4

Rev. D | Page 3 of 93

ERROR_EN Register .................................................................. 85

MCLK_COUNT Register .......................................................... 87

Channel Registers ........................................................................ 87

Configuration Registers ............................................................. 89

Filter Registers ............................................................................. 90

Offset Registers ............................................................................ 91

Gain Registers .............................................................................. 91

Outline Dimensions ........................................................................ 92

Ordering Guide ........................................................................... 93

REVISION HISTORY

6/2018—Rev. C to Rev. D

Changes to Features Section ............................................................ 1

Changes to General Description Section ....................................... 5

Added Table 1; Renumbered Sequentially ..................................... 5

Changes to Drift Parameter, External REFIN Voltage Parameter,

and Note 12, Table 3 .......................................................................... 8

Changes to Table 7 .......................................................................... 16

Changes to Figure 13 and Figure 15 ............................................. 18

Changes to Figure 44, Figure 45, and Figure 46 .......................... 23

Changes to Reference Section ........................................................ 37

Changes to Accessing the ADC Register Map Section and Reset

Column, Table 39 ............................................................................ 39

Changes to External Impedance When Using a Gain of 1

Section .............................................................................................. 46

Changes to Reference Section ........................................................ 47

Changes to Standby and Power-Down Modes Section .............. 49

Changes to Calibration Section ..................................................... 53

Change to Sinc3 Output Data Rate and Settling Time Section . 57

Change to Calibration, Conversion, and Saturation Errors

Section .......................................................................................................... 67

Changes to MCLK Counter Section ............................................. 68

Changes to Memory Map Checksum Protection Section ......... 69

Changes to Reset Column and Note 1, Table 64 ......................... 78

Changes to Description Column, Table 68 .................................. 81

Changes to ID Register Section ..................................................... 84

Changes to Description Column, Table 73 .................................. 87

Changes to Description Column, Table 74 .................................. 88

Changes to Configuration Registers Section ............................... 89

Updated Outline Dimensions ........................................................ 92

Changes to Ordering Guide ........................................................... 93

7/2016—Rev. B to Rev. C

Change to Features Section .............................................................. 1

Changes to Specifications Section and Table 2.............................. 5

Changes to Table 4 .......................................................................... 13

Change to Table 8 ............................................................................ 27

Changes to Table 9 and Table 10 ................................................... 28

Change to Table 25 .......................................................................... 32

Changes to Table 28 ........................................................................ 33

Change to Table 29 .......................................................................... 34

Changes to Accessing the ADC Register Map and Table 38 ..... 38

Changes to Diagnostics Section, Table 44, and Table 45 ........... 41

Added External Impedance When Using a Gain of 1 Section,

Figure 74, Figure 75, and Figure 76; Renumbered Sequentially ..... 45

Changes to Standby and Power-Down Modes Section .............. 48

Changes to Single Conversion Mode Section ............................. 50

Changes to Continuous Read Mode Section ............................... 51

Changes to Sinc4 Output Data Rate/Settling Time Section ....... 54

Changes to Sinc4 Zero Latency Section ........................................ 55

Changes to Sinc3 Output Data Rate and Settling Time Section ...... 56

Changes to Sinc3 Zero Latency Section ........................................ 57

Change to Output Data Rate and Settling Time, Sinc4 + Sinc1

Filter Section .................................................................................... 59

Change to Output Data Rate and Settling Time, Sinc3 + Sinc1

Filter Section .................................................................................... 60

Changes to SPI_IGNORE Error Section ...................................... 68

Added ROM Checksum Protection Section................................ 69

Changes to Table 63 ........................................................................ 77

Changes to ID Register Section and Error Register Section ..... 83

Changes to Table 70 and ERROR_EN Register Section ............ 84

Changes to Table 71 ........................................................................ 85

Changes to Table 73 ........................................................................ 87

12/2015—Rev. A to Rev. B

Changed +105°C to +125°C ......................................... Throughout

Changes to Table 2 ............................................................................ 5

Added Endnote 4, Table 2; Renumbered Sequentially ............... 10

Changes to Figure 17 Through Figure 22 .................................... 18

Changes to Figure 23 Through Figure 26 .................................... 19

Changes to Figure 30, Figure 33, and Figure 34 .......................... 20

Changes to Figure 37 Through Figure 40 .................................... 21

Changes to Figure 41 Through Figure 46 .................................... 22

Changes to Figure 47 and Figure 48 ............................................. 23

Changes to Figure 64 ...................................................................... 25

Changes to Figure 126 .................................................................... 69

Change to Table 17 .......................................................................... 30

Changes to Reference Section ....................................................... 36

Changes to Accessing the ADC Register Map Section and

Table 38 ............................................................................................. 38

Change to Table 63 .......................................................................... 76

Change to ID Register Section ...................................................... 82

Change to Table 73 .......................................................................... 85

Change to Table 73 .......................................................................... 86

Changes to the Ordering Guide .................................................... 90

7/2015—Rev. 0 to Rev. A

Change to Data Sheet Title .............................................................. 1

Changes to Internal Reference Drift Parameter, Table 2 ............. 7

Changes to Figure 30 ...................................................................... 20

Change to Digital Outputs Section ............................................... 37

AD7124-4 Data Sheet

Rev. D | Page 4 of 93

Change to Single Conversion Mode Section............................... 49

Changes to Calibration Section .................................................... 51

Changes to Figure 83 ...................................................................... 53

Changes to Figure 91 ...................................................................... 56

Changes to Figure 99 ...................................................................... 58

Changes to Figure 105 .................................................................... 60

Changes to Reference Detect Section and Figure 119 ............... 65

Change to Table 70 ......................................................................... 83

Changes to Table 71 ....................................................................... 84

5/2015—Revision 0: Initial Version

Data Sheet AD7124-4

Rev. D | Page 5 of 93

GENERAL DESCRIPTION

The AD7124-4 is a low power, low noise, completely integrated

analog front end for high precision measurement applications.

The device contains a low noise, 24-bit Σ-Δ analog-to-digital

converter (ADC), and can be configured to have four differential

inputs or seven single-ended or pseudo differential inputs. The

on-chip low gain stage ensures that signals of small amplitude

can be interfaced directly to the ADC.

One of the major advantages of the AD7124-4 is that it gives the

user the flexibility to employ one of three integrated power

modes. The current consumption, range of output data rates,

and rms noise can be tailored with the power mode selected.

The device also offers a multitude of filter options, ensuring that

the user has the highest degree of flexibility.

The AD7124-4 can achieve simultaneous 50 Hz and 60 Hz

rejection when operating at an output data rate of 25 SPS (single

cycle settling), with rejection in excess of 80 dB achieved at lower

output data rates.

The AD7124-4 establishes the highest degree of signal chain

integration. The device contains a precision, low noise, low

drift internal band gap reference, and also accepts an external

differential reference, which can be internally buffered. Other

key integrated features include programmable low drift excitation

current sources, burnout currents, and a bias voltage generator,

which sets the common-mode voltage of a channel to AVDD/2.

The low-side power switch enables the user to power down

bridge sensors between conversions, ensuring the absolute

minimal power consumption of the system. The device also

allows the user the option of operating with either an internal

clock or an external clock.

The integrated channel sequencer allows several channels to be

enabled simultaneously, and the AD7124-4 sequentially converts

on each enabled channel, simplifying communication with the

device. As many as 16 channels can be enabled at any time; a

channel being defined as an analog input or a diagnostic such as

a power supply check or a reference check. This unique feature

allows diagnostics to be interleaved with conversions. The

AD7124-4 also supports per channel configuration. The device

allows eight configurations or setups. Each configuration

consists of gain, filter type, output data rate, buffering, and

reference source. The user can assign any of these setups on a

channel by channel basis.

The AD7124-4 also has extensive diagnostic functionality

integrated as part of its comprehensive feature set. These

diagnostics include a cyclic redundancy check (CRC), signal

chain checks, and serial interface checks, which lead to a more

robust solution. These diagnostics reduce the need for external

components to implement diagnostics, resulting in reduced

board space needs, reduced design cycle times, and cost savings.

The failure modes effects and diagnostic analysis (FMEDA) of a

typical application has shown a safe failure fraction (SFF) greater

than 90% according to IEC 61508.

The device operates with a single analog power supply from 2.7 V

to 3.6 V or a dual 1.8 V power supply. The digital supply has a

range of 1.65 V to 3.6 V. It is specified for a temperature range

of −40°C to +125°C. The AD7124-4 is housed in a 32-lead

LFCSP package and a 24-lead TSSOP package.

Note that, throughout this data sheet, multifunction pins, such

as DOUT/RDY, are referred to either by the entire pin name or

by a single function of the pin, for example, RDY, when only

that function is relevant.

The AD7124-4 B grade has operational and performance

differences from the AD7124-4. Table 1 lists these differences.

Unless otherwise noted, all references to AD7124-4 refer to the

device and not to the B grade.

Table 1. Differences Between the AD7124-4 and the AD7124-4 B Grade

Parameter AD7124-4 AD7124-4 B Grade

LFCSP Package Height

0.75 mm

0.95 mm

Internal Reference Drift 15 ppm/°C 10 ppm/°C

Excitation Currents in Standby Mode Disabled Remain active if enabled

Gain of 1, High Impedance Loads Impacts settling time when switching channels Does not impact settling time when switching channels

Table 2. AD7124-4 Overview

Parameter Low Power Mode Mid Power Mode Full Power Mode

Maximum Output Data Rate 2400 SPS 4800 SPS 19,200 SPS

RMS Noise (Gain = 128) 24 nV 20 nV 23 nV

Peak-to-Peak Resolution at 1200 SPS

(Gain = 1)

16.4 bits 17.1 bits 18 bits

Typical Current (ADC + PGA) 255 µA 355 µA 930 µA

AD7124-4 Data Sheet

Rev. D | Page 6 of 93

SPECIFICATIONS

AVDD = 2.9 V to 3.6 V (full power mode), 2.7 V to 3.6 V (mid and low power mode), IOVDD = 1.65 V to 3.6 V, AVSS = DGND = 0 V,

REFINx(+) = 2.5 V, R E F I N x (−) = AVSS, master clock = 614.4 kHz, all specifications TMIN to TMAX, unless otherwise noted.

Table 3.

Parameter1 Min Typ Max Unit Test Conditions/Comments

ADC

Output Data Rate, fADC

Low Power Mode 1.17 2400 SPS

Mid Power Mode 2.34 4800 SPS

Full Power Mode 9.38 19,200 SPS

No Missing Codes2

Bits

FS3 > 2, sinc4 filter

24 Bits FS3 > 8, sinc3 filter

Resolution See the RMS Noise and Resolution

section

RMS Noise and Update Rates See the RMS Noise and Resolution

section

Integral Nonlinearity (INL) −4 ±1 +4 ppm of FSR Gain = 12

−15 ±2 +15 ppm of FSR Gain > 14

Offset Error5

Before Calibration ±15 µV Gain = 1 to 8

200/gain µV Gain = 16 to 128

After Internal Calibration/System

Calibration

In order of

noise

Offset Error Drift vs. Temperature6

Low Power Mode 10 nV/°C Gain = 1 or gain > 16

80 nV/°C Gain = 2 to 8

40 nV/°C Gain = 16

Mid Power Mode 10 nV/°C Gain = 1 or gain > 16

nV/°C

Gain = 2 to 8

20 nV/°C Gain = 16

Full Power Mode 10 nV/°C

Gain Error5, 7

Before Internal Calibration −0.0025 +0.0025 % Gain = 1, TA = 25°C

−0.3 % Gain > 1

After Internal Calibration −0.016 +0.004 +0.016 % Gain = 2 to 8, TA = 25°C

±0.025 % Gain = 16 to 128

After System Calibration In order of

noise

Gain Error Drift vs. Temperature 1 2 ppm/°C

Power Supply Rejection AIN = 1 V/gain, external reference

Low Power Mode 87 dB Gain = 2 to 16

96 dB Gain = 1 or gain > 16

Mid Power Mode2 92 dB Gain = 2 to 16

100 dB Gain = 1 or gain > 16

Full Power Mode 99 dB

Common-Mode Rejection8

At DC

= 1 V, gain = 1

105 115 dB AIN = 1 V/gain, gain 2 or 4

1029, 2 dB AIN = 1 V/gain, gain 2 or 4

115 120 dB AIN = 1 V/gain, gain ≥ 8

1059, 2 dB AIN = 1 V/gain, gain ≥ 8

Sinc3, Sinc4 Filter2

At 50 Hz, 60 Hz 120 dB 10 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

At 50 Hz 120 dB 50 SPS, 50 Hz ± 1 Hz

At 60 Hz

120

60 SPS, 60 Hz ± 1 Hz

Data Sheet AD7124-4

Rev. D | Page 7 of 93

Parameter1 Min Typ Max Unit Test Conditions/Comments

Fast Settling Filters2

At 50 Hz 115 dB First notch at 50 Hz, 50 Hz ± 1 Hz

At 60 Hz 115 dB First notch at 60 Hz, 60 Hz ± 1 Hz

Post Filters2

At 50 Hz, 60 Hz 130 dB 20 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

130 dB 25 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

Normal Mode Rejection2

Sinc4 Filter

External Clock

At 50 Hz, 60 Hz 120 dB 10 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

80 dB 50 SPS, REJ6010=1, 50 Hz ± 1 Hz,

60 Hz ± 1 Hz

At 50 Hz

120

50 SPS, 50 Hz ± 1 Hz

At 60 Hz 120 dB 60 SPS, 60 Hz ± 1 Hz

Internal Clock

At 50 Hz, 60 Hz 98 dB 10 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

66 dB 50 SPS, REJ6010 = 1, 50 Hz ± 1 Hz,

60 Hz ± 1 Hz

At 50 Hz 92 dB 50 SPS, 50 Hz ± 1 Hz

At 60 Hz 92 dB 60 SPS, 60 Hz ± 1 Hz

Sinc3 Filter

External Clock

At 50 Hz, 60 Hz 100 dB 10 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

65 dB 50 SPS, REJ6010 = 1, 50 Hz ± 1 Hz,

60 Hz ± 1 Hz

At 50 Hz

100

50 SPS, 50 Hz ± 1 Hz

At 60 Hz 100 dB 60 SPS, 60 Hz ± 1 Hz

Internal Clock

At 50 Hz, 60 Hz 73 dB 10 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

52 dB 50 SPS, REJ6010 = 1, 50 Hz ± 1 Hz,

60 Hz ± 1 Hz

At 50 Hz 68 dB 50 SPS, 50 Hz ± 1 Hz

At 60 Hz 68 dB 60 SPS, 60 Hz ± 1 Hz

Fast Settling Filters

External Clock

At 50 Hz 40 dB First notch at 50 Hz, 50 Hz ± 0.5 Hz

At 60 Hz 40 dB First notch at 60 Hz, 60 Hz ± 0.5 Hz

Internal Clock

At 50 Hz 24.5 dB First notch at 50 Hz, 50 Hz ± 0.5 Hz

At 60 Hz 24.5 dB First notch at 60 Hz, 60 Hz ± 0.5 Hz

Post Filters

External Clock

At 50 Hz, 60 Hz 86 dB 20 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

25 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

Internal Clock

At 50 Hz, 60 Hz 67 dB 20 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

50 dB 25 SPS, 50 Hz ± 1 Hz, 60 Hz ± 1 Hz

ANALOG INPUTS11

Differential Input Voltage Ranges12 ±VREF/gain V VREF = REFINx(+) − REFINx(−), or

internal reference

Absolute AIN Voltage Limits2

Gain = 1 (Unbuffered) AVSS − 0.05 AVDD + 0.05 V

Gain = 1 (Buffered) AVSS + 0.1 AVDD − 0.1 V

Gain > 1 AVSS − 0.05 AVDD + 0.05 V

AD7124-4 Data Sheet

Rev. D | Page 8 of 93

Parameter1 Min Typ Max Unit Test Conditions/Comments

Analog Input Current

Gain > 1 or Gain = 1 (Buffered)

Low Power Mode

Absolute Input Current ±1 nA

Differential Input Current ±0.2 nA

Analog Input Current Drift 25 pA/°C

Mid Power Mode

Absolute Input Current

±1.2

Differential Input Current ±0.4 nA

Analog Input Current Drift 25 pA/°C

Full Power Mode

Absolute Input Current ±3.3 nA

Differential Input Current

±1.5

Analog Input Current Drift 25 pA/°C

Gain = 1 (Unbuffered) Current varies with input voltage

Absolute Input Current ±2.65 µA/V

Analog Input Current Drift 1.1 nA/V/°C

REFERENCE INPUT

Internal Reference

Initial Accuracy 2.5 − 0.2% 2.5 2.5 + 0.2% V TA = 25°C

Drift 2 10 ppm/°C TSSOP

AD7124-4 2 15 ppm/°C LFCSP

AD7124-4 B Grade 2 10 ppm/°C LFCSP

Output Current 10 mA

Load Regulation 50 µV/mA

Power Supply Rejection 85 dB

External Reference

External REFIN Voltage2 0.5 2.5 AVDD V REFIN = REFINx(+) − REFINx(−)

Absolute REFIN Voltage Limits2 AVSS − 0.05 AVDD + 0.05 V Unbuffered

+ 0.1

− 0.1

Buffered

Reference Input Current

Buffered

Low Power Mode

Absolute Input Current ±0.5 nA

Reference Input Current Drift

pA/°C

Mid Power Mode

Absolute Input Current ±1 nA

Reference Input Current Drift 10 pA/°C

Full Power Mode

Absolute Input Current ±3 nA

Reference Input Current Drift 10 pA/°C

Unbuffered

Absolute Input Current ±12 µA

Reference Input Current Drift 6 nA/°C

Normal Mode Rejection Same as for analog inputs

Common-Mode Rejection 100 dB

Data Sheet AD7124-4

Rev. D | Page 9 of 93

Parameter1 Min Typ Max Unit Test Conditions/Comments

EXCITATION CURRENT SOURCES (IOUT0/IOUT1) Available on any analog input pin

Output Current 50/100/250/

500/750/1000

µA

Initial Tolerance ±4 % TA = 25°C

Drift 50 ppm/°C

Current Matching ±0.5 % Matching between IOUT0 and

IOUT1, VOUT = 0 V

Drift Matching2 5 30 ppm/°C

Line Regulation (AVDD) 2 %/V AVDD = 3 V ± 5%

Load Regulation 0.2 %/V

Output Compliance2 AVSS − 0.05 AVDD − 0.37 V 50 µA/100 µA/250 µA/500 µA

current sources, 2% accuracy

− 0.05

− 0.48

750 µA and 1000 µA current

sources, 2% accuracy

BIAS VOLTAGE (VBIAS) GENERATOR Available on any analog input pin

VBIAS AVSS + (AVDD −

AVSS)/2

VBIAS Generator Start-Up Time 6.7 µs/nF Dependent on the capacitance

connected to AINx

TEMPERATURE SENSOR

Accuracy ±0.5 °C

Sensitivity 13,584 Codes/°C

LOW-SIDE POWER SWITCH

On Resistance (RON) 7 10 Ω

Allowable Current2 30 mA Continuous current

BURNOUT CURRENTS

AIN Current 0.5/2/4 µA Analog inputs must be buffered

DIGITAL OUTPUTS (P1 AND P2)

Output Voltage

High, VOH AVDD − 0.6 V ISOURCE = 100 µA

Low, VOL 0.4 V ISINK = 100 µA

DIAGNOSTICS

Power Supply Monitor Detect Level

Analog Low Dropout Regulator (ALDO) 1.6 V AVDD − AVSS ≥ 2.7 V

Digital LDO (DLDO) 1.55 V IOVDD ≥ 1.75 V

Reference Detect Level 0.7 1 V REF_DET_ERR bit active if VREF < 0.7 V

AINM/AINP Overvoltage Detect Level AVDD + 0.04 V

AINM/AINP Undervoltage Detect Level AVSS − 0.04 V

INTERNAL/EXTERNAL CLOCK

Internal Clock

Frequency

614.4 − 5%

614.4

614.4 + 5%

kHz

Duty Cycle 50:50 %

External Clock

Frequency 2.4576 MHz Internal divide by 4

Duty Cycle Range 45:55 to 55:45 %

LOGIC INPUTS2

Input Voltage

Low, VINL 0.3 × IOVDD V 1.65 V ≤ IOVDD < 1.9 V

0.35 × IOVDD V 1.9 V ≤ IOVDD < 2.3 V

0.7

2.3 V ≤ IOV

≤ 3.6 V

High, VINH 0.7 × IOVDD V 1.65 V ≤ IOVDD < 1.9 V

0.65 × IOVDD V 1.9 V ≤ IOVDD < 2.3 V

1.7 V 2.3 V ≤ IOVDD < 2.7 V

2 V 2.7 V ≤ IOVDD ≤ 3.6 V

Hysteresis 0.2 0.6 V 1.65 V ≤ IOVDD ≤ 3.6 V

Input Currents −1 +1 µA VIN = IOVDD or GND

Input Capacitance 10 pF All digital inputs

AD7124-4 Data Sheet

Rev. D | Page 10 of 93

Parameter1 Min Typ Max Unit Test Conditions/Comments

LOGIC OUTPUTS (INCLUDING CLK)

Output Voltage2

High, VOH IOVDD − 0.35 V ISOURCE = 100 µA

Low, V

0.4

SINK

= 100 µA

Floating State Leakage Current −1 +1 µA

Floating State Output Capacitance 10 pF

Data Output Coding

Offset binary

SYSTEM CALIBRATION2

Calibration Limit

Full Scale (FS) 1.05 × FS V

Zero Scale −1.05 × FS V

Input Span 0.8 × FS 2.1 × FS V

POWER SUPPLY VOLTAGES FOR ALL POWER

MODES

AVDD to AVSS

Low Power Mode 2.7 3.6 V

Mid Power Mode

2.7

3.6

Full Power Mode 2.9 3.6 V

IOVDD to GND 1.65 3.6 V

AVSS to GND −1.8 0 V

IOVDD to AVSS 5.4 V

POWER SUPPLY CURRENTS11, 13

IAVDD, External Reference

Low Power Mode

Gain = 12

125

140

µA

All buffers off

Gain = 1 IAVDD Increase per AINx Buffer2 15 25 µA

Gain = 2 to 8 205 250 µA

Gain = 16 to 128 235 300 µA

IAVDD Increase per Reference Buffer2 10 20 µA All gains

Mid Power Mode

Gain = 12 150 170 µA All buffers off

Gain = 1 IAVDD Increase per AINx Buffer2 30 40 µA

Gain = 2 to 8 275 345 µA

Gain = 16 to 128 330 430 µA

IAVDD Increase per Reference Buffer2 20 30 µA All gains

Full Power Mode

Gain = 12 315 350 µA All buffers off

Gain = 1 I

AVDD

Increase per AINx Buffer2

135

µA

Gain = 2 to 8 660 830 µA

Gain = 16 to 128 875 1200 µA

IAVDD Increase per Reference Buffer2 85 120 µA All gains

IAVDD Increase

Due to Internal Reference

µA

Independent of power mode; the

reference buffers are not required

when using this reference

Due to VBIAS2 15 20 µA Independent of power mode

Due to Diagnostics2 4 5 µA

IIOVDD

Low Power Mode 20 35 µA

Mid Power Mode 25 40 µA

Full Power Mode 55 80 µA

Data Sheet AD7124-4

Rev. D | Page 11 of 93

Parameter1 Min Typ Max Unit Test Conditions/Comments

POWER-DOWN CURRENTS13 Independent of power mode

Standby Current

IAVDD 7 15 µA LDOs on only

IOVDD

µA

Power-Down Current

IAVDD 1 3 µA

IOVDD

µA

1 Temperature range = −40°C to +125°C.

2 These specifications are not production tested but are supported by characterization data at the initial product release.

3 FS is the decimal equivalent of the FS[10:0] bits in the filter registers.

4 The integral nonlinearity is production tested in full power mode only. For other power modes, the specification is supported by characterization data at the initial

product release.

5 Following a system or internal zero-scale calibration, the offset error is in the order of the noise for the programmed gain and output data rate selected. A system full-

scale calibration reduces the gain error to the order of the noise for the programmed gain and output data rate.

6 Recalibration at any temperature removes these errors.

7 Gain error applies to both positive and negative full-scale. A factory calibration is performed at gain = 1, TA = 25°C.

8 When gain > 1, the common-mode voltage is between (AVSS + 0.1 + 0.5/gain) and (AVDD − 0.1 − 0.5/gain).

9 Specification is for a wider common-mode voltage between (AVSS − 0.05 + 0.5/gain) and (AVDD − 0.1 − 0.5/gain).

10 REJ60 is a bit in the filter registers. When the first notch of the sinc filter is at 50 Hz, a notch is placed at 60 Hz when REJ60 is set to 1. This gives simultaneous 50 Hz and

60 Hz rejection.

11 When the gain is greater than 1, the analog input buffers are enabled automatically. The buffers can only be disabled when the gain equals 1.

12 When VREF = (AVDD − AVSS), the typical differential input equals 0.92 × VREF/gain for the low and mid power modes and 0.86 × VREF/gain for full power mode when gain > 1.

13 The digital inputs are equal to IOVDD or DGND with excitation currents and bias voltage generator disabled.

TIMING CHARACTERISTICS

AVDD = 2.9 V to 3.6 V (full power mode), 2.7 V to 3.6 V (mid and low power mode), IOVDD = 1.65 V to 3.6 V, AV SS = DGND = 0 V,

Input Logic 0 = 0 V, Input Logic 1 = IOVDD, unless otherwise noted.

Table 4.

Parameter1, 2 Min Typ Max Unit Test Conditions/Comments

t3 100 ns SCLK high pulse width

t4 100 ns SCLK low pulse width

t12 Delay between consecutive read/write operations

3/MCLK3 ns Full power mode

12/MCLK ns Mid power mode

24/MCLK ns Low power mode

t13 µs DOUT/RDY high time if DOUT/RDY is low and the next

conversion is available

6 µs Full power mode

25 µs Mid power mode

50 µs Low power mode

t14 SYNC low pulse width

3/MCLK

Full power mode

12/MCLK

Mid power mode

24/MCLK ns Low power mode

READ OPERATION

t1 0 80 ns CS falling edge to DOUT/RDY active time

t24 0 80 ns SCLK active edge5 to data valid delay

t56, 7 10 80 ns Bus relinquish time after CS inactive edge

t6 0 ns SCLK inactive edge to CS inactive edge

t78 SCLK inactive edge to DOUT/RDY high

10 ns The DOUT_RDY_DEL bit is cleared, the CS_EN bit is

cleared

110 ns The DOUT_RDY_DEL bit is set, the CS_EN bit is cleared

t7A7 t5 ns Data valid after CS inactive edge, the CS_EN bit is set

AD7124-4 Data Sheet

Rev. D | Page 12 of 93

Parameter1, 2 Min Typ Max Unit Test Conditions/Comments

WRITE OPERATION

t8 0 ns CS falling edge to SCLK active edge5 setup time

t9 30 ns Data valid to SCLK edge setup time

t10 25 ns Data valid to SCLK edge hold time

t11 0 ns CS rising edge to SCLK edge hold time

1 These specifications were sample tested during the initial release to ensure compliance. All input signals are specified with tR = tF = 5 ns (10% to 90% of IOVDD and

timed from a voltage level of IOVDD/2.

2 See Figure 3, Figure 4, Figure 5, and Figure 6.

3 MCLK is the master clock frequency.

4 These specifications are measured with the load circuit shown in Figure 2 and defined as the time required for the output to cross the VOL or VOH limits.

5 The SCLK active edge is the falling edge of SCLK.

6 These specifications are derived from the measured time taken by the data output to change by 0.5 V when loaded with the circuit shown in Figure 2. The measured

number is then extrapolated back to remove the effects of charging or discharging the 25 pF capacitor. The times quoted in the timing characteristics are the true bus

relinquish times of the device and, therefore, are independent of external bus loading capacitances.

7 RDY returns high after a read of the ADC. In single conversion mode and continuous conversion mode, the same data can be read again, if required, while RDY is high,

although subsequent reads must not occur close to the next output update. In continuous read mode, the digital word can be read only once.

8 When the CS_EN bit is cleared, the DOUT/RDY pin changes from its DOUT function to its RDY function, following the last inactive edge of the SCLK. When CS_EN is set,

the DOUT pin continues to output the LSB of the data until the CS inactive edge.

Timing Diagrams

IOV

TO OUTPUT PIN

SOURCE

(100µA)

SINK

(100µA)

25pF

13197-002

Figure 2. Load Circuit for Timing Characterization

MSB LSB

DOUT/RDY (O)

SCL K ( I)

CS (I)

I = INPUT, O = OUTPUT

13197-003

Figure 3. Read Cycle Timing Diagram (CS_EN Bit Cleared)

Data Sheet AD7124-4

Rev. D | Page 13 of 93

MSB

DOUT/RDY (O)

SCLK (I)

CS (I)

I = INPUT, O = OUTPUT

LSB

13197-004

Figure 4. Read Cycle Timing Diagram (CS_EN Bit Set)

CS (I)

SCLK (I)

DIN ( I )

MSB LSB

I = INPUT, O = OUTPUT

13197-005

Figure 5. Write Cycle Timing Diagram

WRITE

DIN

DOUT/RDY

SCLK

WRITE

t12

READREAD

13197-006

Figure 6. Delay Between Consecutive Serial Operations

DIN

DOUT/RDY

SCLK

13197-007

Figure 7. DOUT/RDY High Time when DOUT/RDY is Initially Low and the Next Conversion is Available

SYNC (I)

MCL K ( I)

13197-008

Figure 8. SYNC Pulse Width

AD7124-4 Data Sheet

Rev. D | Page 14 of 93

ABSOLUTE MAXIMUM RATINGS

TA = 25°C, unless otherwise noted.

Table 5.

Parameter Rating

AVDD to AVSS −0.3 V to +3.96 V

IOVDD to DGND −0.3 V to +3.96 V

IOVDD to AVSS −0.3 V to +5.94 V

AVSS to DGND −1.98 V to +0.3 V

Analog Input Voltage to AVSS −0.3 V to AVDD + 0.3 V

Reference Input Voltage to AVSS −0.3 V to AVDD + 0.3 V

Digital Input Voltage to DGND

−0.3 V to IOV

+ 0.3 V

Digital Output Voltage to DGND −0.3 V to IOVDD + 0.3 V

AINx/Digital Input Current 10 mA

Operating Temperature Range −40°C to +125°C

Storage Temperature Range −65°C to +150°C

Maximum Junction Temperature 150°C

Lead Temperature, Soldering

Reflow 260°C

ESD Ratings

Human Body Model (HBM) 4 kV

Field-Induced Charged Device

Model (FICDM)

1250 V

Machine Model 400 V

Stresses at or above those listed under Absolute Maximum

Ratings may cause permanent damage to the product. This is a

stress rating only; functional operation of the product at these

or any other conditions above those indicated in the operational

section of this specification is not implied. Operation beyond

the maximum operating conditions for extended periods may

affect product reliability.

THERMAL RESISTANCE

θJA is specified for the worst case conditions, that is, a device

soldered in a circuit board for surface-mount packages.

Table 6. Thermal Resistance

Package Type θJA θJC Unit

32-Lead LFCSP 32.5 32.71 °C/W

24-Lead TSSOP

128

°C/W

ESD CAUTION

Data Sheet AD7124-4

Rev. D | Page 15 of 93

PIN CONFIGURATIONS AND FUNCTION DESCRIPTIONS

NOTES

1. DNC = DO NO T CO NNE CT.

2. CO NNE CT EX P OSE D P AD TO AVSS.

REGCAPD

AIN3/IOUT/VBIAS/P2

IOVDD

DGND

AIN0/IOUT/VBIAS

AIN1/IOUT/VBIAS

DNC

AIN2/IOUT/VBIAS/P1

REGCAPA

AVSS

REFOUT

AIN7/IOUT/VBIAS/REFIN2(–)

AIN6/IOUT/VBIAS/REFIN2(+)

DNC

AIN5/IOUT/VBIAS

CLK

SCLK

DIN

DOUT/RDY

SYNC

PSW

DNC

REFIN1(+)

REFIN1(–)

DNC

AIN4/IOUT/VBIAS

AD7124-4

TOP VIEW

(No t t o Scal e)

13197-009

Figure 9. 32-Lead LFCSP Pin Configuration

SCLK

CLK

DGND

IOV

REGCAPD

DIN

SYNC

PSW

REFOUT

REGCAPA

AIN0/IOUT/VBIAS

AIN1/IOUT/VBIAS

REFIN1(+)

AIN3/IOUT/VBIAS/P2

AIN2/IOUT/VBIAS/P1

AIN7/IOUT/VBIAS/REFIN2(–)

AIN6/IOUT/VBIAS/REFIN2(+)

REFIN1(–)

AIN4/IOUT/VBIAS

AIN5/IOUT/VBIAS

DOUT/RDY

AD7124-4

TOP VIEW

(No t t o Scal e)

13197-300

Figure 10. 24-Lead TSSOP Pin Configuration

Table 7. Pin Function Descriptions

Pin No.

Mnemonic Description

LFCSP TSSOP

1 5 REGCAPD Digital LDO Regulator Output. Decouple this pin to DGND with a 0.1 µF capacitor.

2 6 IOVDD Serial Interface Supply Voltage, 1.65 V to 3.6 V. IOVDD is independent of AVDD. Therefore,

the serial interface can operate at 1.65 V with AVDD at 3.6 V, for example.

DGND

Digital Ground Reference Point.

4 8 AIN0/IOUT/VBIAS Analog Input 0/Output of Internal Excitation Current Source/Bias Voltage. This input pin is

configured via the configuration registers to be the positive or negative terminal of a

differential or pseudo differential input. Alternatively, the internal programmable excitation

current source can be made available at this pin. Either IOUT0 or IOUT1 can be switched to

this output. A bias voltage midway between the analog power supply rails can be generated

at this pin.

5 9 AIN1/IOUT/VBIAS Analog Input 1/Output of Internal Excitation Current Source/Bias Voltage. This input pin is

configured via the configuration registers to be the positive or negative terminal of a

differential or pseudo differential input. Alternatively, the internal programmable excitation

current source can be made available at this pin. Either IOUT0 or IOUT1 can be switched to

this output. A bias voltage midway between the analog power supply rails can be generated

at this pin.

6, 7, 10,

11, 14, 15,

18, 19

N/A1 DNC Do Not Connect. Do not connect to these pins.

8 10 AIN2/IOUT/VBIAS/P1 Analog Input 2/Output of Internal Excitation Current Source/Bias Voltage/General-

Purpose Output 1. This input pin is configured via the configuration registers to be the

positive or negative terminal of a differential or pseudo differential input. Alternatively,

the internal programmable excitation current source can be made available at this pin.

Either IOUT0 or IOUT1 can be switched to this output. A bias voltage midway between the

analog power supply rails can be generated at this pin. This pin can also be configured as a

general-purpose output bit, referenced between AVSS and AVDD.

9 11 AIN3/IOUT/VBIAS/P2 Analog Input 3/Output of Internal Excitation Current Source/Bias Voltage/General-

Purpose Output 2. This input pin is configured via the configuration registers to be the

positive or negative terminal of a differential or pseudo differential input. Alternatively,

the internal programmable excitation current source can be made available at this pin.

Either IOUT0 or IOUT1 can be switched to this output. A bias voltage midway between the

analog power supply rails can be generated at this pin. This pin can also be configured as a

general-purpose output bit, referenced between AVSS and AVDD.

AD7124-4 Data Sheet

Rev. D | Page 16 of 93

Pin No.

Mnemonic Description

LFCSP TSSOP

12 12 REFIN1(+) Positive Reference Input. An external reference can be applied between REFIN1(+) and

REFIN1(−). REFIN1(+) can be anywhere between AVDD and AVSS + 0.5 V. The nominal

reference voltage (REFIN1(+) − REFIN1(−)) is 2.5 V, but the device functions with a

reference from 0.5 V to AVDD.

13 13 REFIN1(−) Negative Reference Input. This reference input can be anywhere between AVSS and

AVDD – 0.5 V.

16 14 AIN4/IOUT/VBIAS Analog Input 4/Output of Internal Excitation Current Source/Bias Voltage. This input pin is

configured via the configuration registers to be the positive or negative terminal of a

differential or pseudo differential input. Alternatively, the internal programmable excitation

current source can be made available at this pin. Either IOUT0 or IOUT1 can be switched to

this output. A bias voltage midway between the analog power supply rails can be generated

at this pin.

17 15 AIN5/IOUT/VBIAS Analog Input 5/Output of Internal Excitation Current Source/Bias Voltage. This input pin is

configured via the configuration registers to be the positive or negative terminal of a

differential or pseudo differential input. Alternatively, the internal programmable excitation

current source can be made available at this pin. Either IOUT0 or IOUT1 can be switched to

this output. A bias voltage midway between the analog power supply rails can be generated

at this pin.

20 16 AIN6/IOUT/VBIAS/

REFIN2(+)

Analog Input 6/Output of Internal Excitation Current Source/Bias Voltage/Positive

Reference Input. This input pin is configured via the configuration registers to be the

positive or negative terminal of a differential or pseudo differential input. Alternatively,

the internal programmable excitation current source can be made available at this pin.

Either IOUT0 or IOUT1 can be switched to this output. A bias voltage midway between the

analog power supply rails can be generated at this pin. This pin also functions as a positive

reference input for REFIN2(±). REFIN2(+) can be anywhere between AVDD and AVSS + 0.5 V.

The nominal reference voltage (REFIN2(+) to REFIN2(−)) is 2.5 V, but the device functions with

a reference from 0.5 V to AVDD.

21 17 AIN7/IOUT/VBIAS/

REFIN2(−)

Analog Input 7/Output of Internal Excitation Current Source/Bias Voltage/Negative

Reference Input. This input pin is configured via the configuration registers to be the

positive or negative terminal of a differential or pseudo differential input. Alternatively,

the internal programmable excitation current source can be made available at this pin.

Either IOUT0 or IOUT1 can be switched to this output. A bias voltage midway between the

analog power supply rails can be generated at this pin. This pin also functions as the

negative reference input for REFIN2(±). This reference input can be anywhere between AVSS

and AVDD – 0.5 V.

22 18 REFOUT Internal Reference Output. The buffered output of the internal 2.5 V voltage reference is

available on this pin.

23 19 AVSS Analog Supply Voltage. The voltage on AVDD is referenced to AVSS. The differential

between AVDD and AVSS must be between 2.7 V and 3.6 V in mid or low power mode and

between 2.9 V and 3.6 V in full power mode. AVSS can be taken below 0 V to provide a dual

power supply to the AD7124-4. For example, AVSS can be tied to −1.8 V and AVDD can be

tied to +1.8 V, providing a ±1.8 V supply to the ADC.

24 20 REGCAPA Analog LDO Regulator Output. Decouple this pin to AVSS with a 0.1 µF capacitor.

25 21 PSW Low-Side Power Switch to AVSS.

Analog Supply Voltage, Relative to AV

27 23 SYNC Synchronization Input. This pin is a logic input that allows synchronization of the digital

filters and analog modulators when using a number of AD7124-4 devices. When SYNC is

low, the nodes of the digital filter, the filter control logic, and the calibration control logic

are reset, and the analog modulator is held in a reset state. SYNC does not affect the digital

interface but does reset RDY to a high state if it is low.

DOUT/

RDY

Serial Data Output/Data Ready Output. DOUT/

RDY

functions as a serial data output pin to

access the output shift register of the ADC. The output shift register can contain data from

any of the on-chip data or control registers. In addition, DOUT/RDY operates as a data ready

pin, going low to indicate the completion of a conversion. If the data is not read after the

conversion, the pin goes high before the next update occurs. The DOUT/RDY falling edge

can also be used as an interrupt to a processor, indicating that valid data is available. With

an external serial clock, the data can be read using the DOUT/RDY pin. When CS is low,

the data/control word information is placed on the DOUT/RDY pin on the SCLK falling

edge and is valid on the SCLK rising edge.

Data Sheet AD7124-4

Rev. D | Page 17 of 93

Pin No.

Mnemonic Description

LFCSP TSSOP

29 1 DIN Serial Data Input to the Input Shift Register on the ADC. Data in the input shift register is

transferred to the control registers within the ADC, with the register selection bits of the

communications register identifying the appropriate register.

30 2 SCLK Serial Clock Input. This serial clock input is for data transfers to and from the ADC. The SCLK pin

has a Schmitt-triggered input, making the interface suitable for opto-isolated applications. The

serial clock can be continuous with all data transmitted in a continuous train of pulses.

Alternatively, it can be a noncontinuous clock with the information being transmitted to

or from the ADC in smaller batches of data.

31 3 CLK Clock Input/Clock Output. The internal clock can be made available at this pin.

Alternatively, the internal clock can be disabled, and the ADC can be driven by an external

clock. This allows several ADCs to be driven from a common clock, allowing simultaneous

conversions to be performed.

32 4 CS Chip Select Input. This is an active low logic input that selects the ADC. Use CS to select the

ADC in systems with more than one device on the serial bus or as a frame synchronization

signal in communicating with the device. CS can be hardwired low if the serial peripheral

interface (SPI) diagnostics are unused, allowing the ADC to operate in 3-wire mode with

SCLK, DIN, and DOUT interfacing with the device.

EP Exposed Pad. Connect the exposed pad to AVSS.

1 N/A means not applicable.

AD7124-4 Data Sheet

Rev. D | Page 18 of 93

TYPICAL PERFORMANCE CHARACTERISTICS

2500

500

1000

1500

2000

7FFFCE

7FFFCF

7FFFD0

7FFFD1

7FFFD2

7FFFD3

7FFFD4

7FFFD5

7FFFD6

7FFFD7

7FFFD8

7FFFD9

7FFFDA

7FFFDB

7FFFDC

OCCURRENCE

CODES (HEX)

10,000 SAMPL E S

13197-010

Figure 11. Noise Histogram Plot (Full Power Mode, Post Filter, Output Data

Rate = 25 SPS, Gain = 1)

1200

1000

800

600

400

200

7FFFC6

7FFFC7

7FFFC8

7FFFC9

7FFFCA

7FFFCB

7FFFCC

7FFFCD

7FFFCE

7FFFCF

7FFFD0

7FFFD1

7FFFD2

7FFFD3

7FFFD4

7FFFD5

7FFFD6

7FFFD7

7FFFD8

7FFFD9

7FFFDA

7FFFDB

7FFFDC

7FFFDE

7FFFDD

7FFFDF

7FFFE0

7FFFE1

7FFFE2

7FFFE3

OCCURRENCE

CODES (HEX)

10,000 SAMPL E S

13197-012

Figure 12. Noise Histogram Plot (Mid Power Mode, Post Filter, Output Data

Rate = 25 SPS, Gain = 1)

400

350

300

250

200

150

100

7FFF2A

7FFF64

7FFF75

7FFF86

7FFF97

7FFFA8

7FFFB8

7FFFC9

7FFFDA

7FFFEB

7FFFFC

80000C

80001D

80002E

80003F

800050

800060

800071

800082

800093

8000A4

8000B4

8000C5

OCCURRENCE

CODES (HEX)

10,000 SAMPL E S

13197-013

Figure 13. Noise Histogram Plot (Low Power Mode, Post Filter, Output Data

Rate = 25 SPS, Gain = 1)

350

300

250

200

150

100

7FFFE9

7FFFFA

800002

800009

800011

800019

800020

800028

800030

800038

80003F

800047

80004F

800057

80005E

800066

80006E

800075

80007D

800085

80008D

800094

80009C

8000A4

OCCURRENCE

CODES (HEX)

10,000 SAMPL E S

13197-011

Figure 14. Noise Histogram Plot (Full Power Mode, Post Filter, Output Data

Rate = 25 SPS, Gain = 128)

700

600

500

400

300

200

100

7FFFC1

7FFFC3

7FFFC5

7FFFC7

7FFFC9

7FFFCB

7FFFCD

7FFFCF

7FFFD1

7FFFD3

7FFFD5

7FFFD7

7FFFD9

7FFFDB

7FFFDD

7FFFDF

7FFFE1

7FFFE3

7FFFE5

7FFFE7

7FFFE9

7FFFEB

7FFFED

7FFFF0

7FFFF2

OCCURRENCE

CODES (HEX)

10,000 SAMPL E S

13197-014

Figure 15. Noise Histogram Plot (Mid Power Mode, Post Filter, Output Data

Rate = 25 SPS, Gain = 128)

400

100

150

200

250

300

350

7FFEED

7FFF03

7FFF1A

7FFF30

7FFF47

7FFF5D

7FFF74

7FFF8A

7FFFA1

7FFFB8

7FFFCE

7FFFFB

7FFFE5

800012

800028

80003F

800055

80006C

800083

800099

8000B0

8000C6

8000F3

80010A

800121

8000DD

OCCURRENCE

CODES (HEX)

10,000 SAMPL E S

13197-015

Figure 16. Noise Histogram Plot (Low Power Mode, Post Filter, Output Data

Rate = 25 SPS, Gain = 128)

Data Sheet AD7124-4

Rev. D | Page 19 of 93

–60

–40

–20

–40 –25 –10 5 20 35 50 65 80 95 110 125

OFF SET ER ROR ( µV )

TEMPERATURE (°C)

100 UNITS

13197-017

Figure 17. Input Referred Offset Error vs. Temperature

(Gain = 8, Full Power Mode)

–60

–40

–20

–40 –25 –10 5 20 35 50 65 80 95 110 125

OFF S ET ERROR (µV)

TEMPERATURE (°C)

100 UNITS

13197-018

Figure 18. Input Referred Offset Error vs. Temperature

(Gain = 8, Mid Power Mode)

–60

–40

–20

–40 –25 –10 5 20 35 50 65 80 95 110 125

OFF SET ER ROR ( µV )

TEMPERATURE (°C)

100 UNI TS

13197-019

Figure 19. Input Referred Offset Error vs. Temperature

(Gain = 8, Low Power Mode)

–60

–40

–20

–40 –25 –10 5 20 35 50 65 80 95 110 125

OFF SET ER ROR ( µV )

TEMPERATURE (°C)

100 UNITS

13197-020

Figure 20. Input Referred Offset Error vs. Temperature

(Gain = 16, Full Power Mode)

–60

–40

–20

–40 –25 –10 5 20 35 50 65 80 95 110 125

OFF SET ERROR (µV)

TEMPERATURE (°C)

100 UNITS

13197-021

Figure 21. Input Referred Offset Error vs. Temperature

(Gain = 16, Mid Power Mode)

–60

–40

–20

–40 –25 –10 5 20 35 50 65 80 95 110 125

OFF SET ERROR (µV)

TEMPERATURE (°C)

100 UNITS

13197-022

Figure 22. Input Referred Offset Error vs. Temperature

(Gain = 16, Low Power Mode)

AD7124-4 Data Sheet

Rev. D | Page 20 of 93

–40 –25 –10 520 35 50 65 80 95 110 125

–60

–40

–20

OFF SET ERROR (µV)

TEMPERATURE (°C)

100 UNITS

13197-023

Figure 23. Input Referred Offset Error vs. Temperature

(Gain = 1, Analog Input Buffers Enabled)

–0.0015

–0.0010

–0.0005

0.0005

0.0010

–40 –25 –10 520 35 50 65 80 95 110 125

GAI N E RROR (%)

TEMPERATURE (°C)

56 UNITS

13197-024

Figure 24. Input Referred Gain Error vs. Temperature (Gain = 1)

–0.010

–0.005

0.005

0.010

0.015

–40 –25 –10 520 35 50 65 80 95 110 125

GAI N E RROR (%)

TEMPERATURE (°C)

56 UNITS

13197-025

Figure 25. Input Referred Gain Error vs. Temperature (Gain = 8)

–0.005

0.005

0.010

0.015

0.020

0.025

0.030

0.035

0.040

0.045

–40 –25 –10 520 35 50 65 80 95 110 125

GAI N E RROR (%)

TEMPERATURE (°C)

56 UNITS

13197-026

Figure 26. Input Referred Gain Error vs. Temperature (Gain = 16)

–2

–1

–3

–2.5 –2.0 –1.5 –1.0 –0.5 00.5 1.0 1.5 2.0 2.5

INL (PPM OF F SR)

ANALOG INPUT VOLTAGE × GAIN (V)

GAI N = 1

GAI N = 8

GAI N = 16

13197-026

Figure 27. INL vs. Differential Input Signal (Analog Input × Gain),

ODR = 50 SPS, External 2.5 V Reference

–4

–3

–2

–1

–2.5 –1.5 –0.5

0.5 1.5 2.5

INL (ppm of FSR)

ANALOG INPUT VOLTAGE × GAIN ( V )

GAI N = 1

GAI N = 8

GAI N = 16

13197-227

Figure 28. INL vs. Differential Input Signal (Analog Input × Gain),

ODR = 50 SPS, Internal Reference

Data Sheet AD7124-4

Rev. D | Page 21 of 93

2.498680

2.498879

2.499078

2.499277

2.499476

2.499675

2.499874

2.500073

2.500272

2.500471

2.500671

COUNTS

INIT I AL ACCURA CY ( V )

109 UNI T S

13197-027

Figure 29. Internal Reference Voltage Histogram

13197-030

2.4965

2.4970

2.4975

2.4980

2.4985

2.4990

2.4995

2.5000

2.5005

2.5010

2.5015

2.5020

–40–25–105 203550658095110125

INTERN

L REFERENCE VO LTAGE (V)

TEMPERATURE (°C)

30 UNITS

Figure 30. Internal Reference Voltage vs. Temperature

–4.262140

–4.089392

–3.916644

–3.743986

–3.571148

–3.398400

–3.225652

–3.052904

–3.880156

–2.707408

–2.534660

OCCURRENCE

EXCITATION CURRENT A CCU RAC Y (%)

109 UNITS

13197-030

Figure 31. IOUTx Current Initial Accuracy Histogram (500 μA)

–1.01835

–0.99035

–0.96235

–0.93435

–0.90635

–0.87835

–0.85035

–0.82235

–0.79435

–0.76635

–0.85035

OCCURRENCE

EXCITATION CURRENT M ATCHING (%)

109 UNITS

13197-031

Figure 32. IOUTx Current Initial Matching Histogram (500 μA)

460

465

470

475

480

485

490

–40 –25 –10 5 20 35 50 65 80 95 110 125

EXCIT

TION CURRENT (µA)

TE MPER ATURE (° C)

29 UNITS

13197-033

Figure 33. Excitation Current Drift (500 μA)

–1.2

–1.0

–0.8

–0.6

–0.4

–0.2

–40 –25 –10 5 20 35 50 65 80 95 110 125

EXCIT

TION CURRENT M ISM

TCH (%)

TEMPERAT URE (°C)

29 UNITS

13197-034

Figure 34. Excitation Current Drift Matching (500 μA)

AD7124-4 Data Sheet

Rev. D | Page 22 of 93

1.0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

00.33 0.66 0.99 1.651.32 1.98 2.31 2.64 2.97 3.30

EXCI TAT IO N CURRE NT (NO RM ALI ZED)

LOAD

(V)

50µA

100µA

250µA

500µA

750µA

1mA

13197-034

Figure 35. Output Compliance (AVDD = 3.3 V)

1.000

0.950

0.955

0.960

0.965

0.970

0.975

0.980

0.985

0.990

0.995

00.33 0.66 0.99 1.651.32 1.98 2.31 2.64 2.97 3.30

EXCI TAT IO N CURRE NT (NO RM ALI ZED)

LOAD

(V)

50µA

100µA

250µA

500µA

750µA

13197-035

Figure 36. Output Compliance (AVDD = 3.3 V)

200

400

600

800

1000

1200

–40 –25 –10 520 35 50 65 80 95 110 125

ANALOG CURRE NT (µA)

TEMPERATURE (°C)

GAI N = 1, AIN BUFFE RS OF F

GAI N = 2 TO 8

GAI N = 1, AIN BUFFE RS ON

GAI N = 16 TO 128

13197-037

Figure 37. Analog Current vs. Temperature (Full Power Mode)

100

150

200

250

300

350

400

450

–40 –25 –10 520 35 50 65 80 95 110 125

ANALOG CURRE NT (µA)

TEMPERATURE (°C)

GAI N = 1, AIN BUFFE RS OF F

GAI N = 2 TO 8

GAI N = 1, AIN BUFFE RS ON

GAI N = 16 TO 128

13197-038

Figure 38. Analog Current vs. Temperature (Mid Power Mode)

100

150

200

250

300

350

–40 –25 –10 520 35 50 65 80 95 110 125

ANALOG CURRE NT (µA)

TEMPERATURE (°C)

GAI N = 1, AIN BUFFE RS OF F

GAI N = 1, AIN BUFFE RS ON

GAI N = 2 TO 8

GAI N = 16 TO 128

13197-039

Figure 39. Analog Current vs. Temperature (Low Power Mode)

TEMPERATURE (°C)

–40 –25 –10 520 35 50 65 80 95 110 125

DIGITAL CURRENT (µA)

FULL POWER

MID POWER

LOW POWER

13197-040

Figure 40. Digital Current vs. Temperature

Data Sheet AD7124-4

Rev. D | Page 23 of 93

–14

–12

–10

–8

–6

–4

–2

–40 –25 –10 520 35 50 65 80 95 110 125

CURRENT ( nA)

TEMPERATURE (°C)

GAI N = 1

GAI N = 4

GAI N = 16

GAI N = 64

GAI N = 2

GAI N = 8

GAI N = 32

GAI N = 128

13197-041

Figure 41. Absolute Analog Input Current vs. Temperature (Full Power Mode)

–10

–8

–6

–4

–2

–40 –25 –10 520 35 50 65 80 95 110 125

CURRENT ( nA)

TEMPERATURE (°C)

GAI N = 1

GAI N = 4

GAI N = 16

GAI N = 64

GAI N = 2

GAI N = 8

GAI N = 32

GAI N = 128

13197-042

Figure 42. Absolute Analog Input Current vs. Temperature (Mid Power Mode)

–9

–8

–7

–6

–5

–4

–3

–2

–1

–40 –25 –10 520 35 50 65 80 95 110 125

CURRENT ( nA)

TEMPERATURE (°C)

GAI N = 1

GAI N = 4

GAI N = 16

GAI N = 64

GAI N = 2

GAI N = 8

GAI N = 32

GAI N = 128

13197-043

Figure 43. Absolute Analog Input Current vs. Temperature (Low Power Mode)

–7

–6

–5

–4

–3

–2

–1

–40 –25 –10 520 35 50 65 80 95 110 125

CURRENT ( nA)

TEMPERATURE (°C)

GAI N = 1

GAI N = 4

GAI N = 16

GAI N = 64

GAI N = 2

GAI N = 8

GAI N = 32

GAI N = 128

13197-044

Figure 44. Differential Analog Input Current vs. Temperature (Full Power Mode)

–6

–5

–4

–3

–2

–1

–40 –25 –10 520 35 50 65 80 95 110 125

CURRENT ( nA)

TEMPERATURE (°C)

GAI N = 1

GAI N = 4

GAI N = 16

GAI N = 64

GAI N = 2

GAI N = 8

GAI N = 32

GAI N = 128

13197-045

Figure 45. Differential Analog Input Current vs. Temperature (Mid Power Mode)

–6

–5

–4

–3

–2

–1

–40 –25 –10 520 35 50 65 80 95 110 125

CURRENT ( nA)

TEMPERATURE (°C)

GAI N = 1

GAI N = 4

GAI N = 16

GAI N = 64

GAI N = 2

GAI N = 8

GAI N = 32

GAI N = 128

13197-046

Figure 46. Differential Analog Input Current vs. Temperature (Low Power Mode)

AD7124-4 Data Sheet

Rev. D | Page 24 of 93

–4.0

–3.5

–3.0

–2.5

–2.0

–1.5

–1.0

–0.5

–40 –25 –10 520 35 50 65 80 95 110 125

CURRENT ( nA)

TEMPERATURE (°C)

FULL POWER

MID POWER

LOW POWER

13197-047

Figure 47. Reference Input Current vs. Temperature (Reference Buffers Enabled)

–0.6

–0.4

–0.2

0.2

0.4

0.6

0.8

1.0

1.2

–40 –30 –20 –10 015 25 40 50 60 70 85 95 105 115 125

TEMPERATURE SE NS OR ERROR (%)

TEMPERATURE (°C)

32 UNITS

13197-048

Figure 48. Temperature Sensor Accuracy

10 110 100 1k 10k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RATE, SETTLED (SPS)

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-048

Figure 49. Peak-to-Peak Resolution vs. Output Data Rate (Settled), Sinc4 Filter

(Full Power Mode)

10 110 100 1k 10k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RATE, SETTLED (SPS)

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-049

Figure 50. Peak-to-Peak Resolution vs. Output Data Rate (Settled), Sinc3 Filter

(Full Power Mode)

10 110 100 1k 10k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RAT E ( S P S )

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-050

Figure 51. Peak-to-Peak Resolution vs. Output Data Rate, Sinc4 + Sinc1 Filter

(Full Power Mode)

10 110 100 1k 10k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RAT E ( S P S )

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-051

Figure 52. Peak-to-Peak Resolution vs. Output Data Rate, Sinc3 + Sinc1 Filter

(Full Power Mode)

Data Sheet AD7124-4

Rev. D | Page 25 of 93

10 110 100 1k 100k

10k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RATE, SETTLED (SPS)

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-052

Figure 53. Peak-to-Peak Resolution vs. Output Data Rate (Settled), Sinc4 Filter

(Mid Power Mode)

10 110 100 1k 100k10k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RATE, SETTLED (SPS)

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-053

Figure 54. Peak-to-Peak Resolution vs. Output Data Rate (Settled), Sinc3 Filter

(Mid Power Mode)

10 110 100 1k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RAT E ( S P S )

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-054

Figure 55. Peak-to-Peak Resolution vs. Output Data Rate, Sinc4 + Sinc1 Filter

(Mid Power Mode)

10 110 100 1k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RAT E ( S P S )

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-055

Figure 56. Peak-to-Peak Resolution vs. Output Data Rate, Sinc3 + Sinc1 Filter

(Mid Power Mode)

10 110 100 1k 10k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RATE, SETTLED (SPS)

G = 1 AIN BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-056

Figure 57. Peak-to-Peak Resolution vs. Output Data Rate (Settled), Sinc4 Filter

(Low Power Mode)

110 100 1k 10k

PEAK-TO-PEAK RESOLUTION (Bits)

OUTPUT DATA RATE, SETTLED (SPS)

G = 1 AIN BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-057

Figure 58. Peak-to-Peak Resolution vs. Output Data Rate (Settled), Sinc3 Filter

(Low Power Mode)

AD7124-4 Data Sheet

Rev. D | Page 26 of 93

10 1101001k

PEAK-T O-PEAK RESOL UTION (Bi ts)

OUTPUT DATA RATE (SPS)

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-058

Figure 59. Peak-to-Peak Resolution vs. Output Data Rate, Sinc4 + Sinc1 Filter

(Low Power Mode)

10 1101001k

PEAK-TO-PEAK RESOL UTION (Bits)

OUTPUT DATA RATE (SPS)

G = 1 BUFF OFF

G = 1

G = 2

G = 4

G = 8

G = 16

G = 32

G = 64

G = 128

13197-059

Figure 60. Peak-to-Peak Resolution vs. Output Data Rate, Sinc3 + Sinc1 Filter

(Low Power Mode)

100

150

200

250

300

350

400

0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0

WAIT TIME IN STANDBY MODE (Seconds)

ANALOG CURRENT (µA)

GAIN = 1, LOW POWER

GAIN = 8, LOW POWER

GAIN = 16, LOW POWER

GAIN = 1, MID POWER

GAIN = 8, MID POWER

GAIN = 16, MID POWER

GAIN = 1, FULL POWER

GAIN = 8, FULL POWER

GAIN = 16, FULL POWER

13197-200

Figure 61. Analog Current vs. Wait Time in Standby Mode, ADC in Single

Conversion Mode (50 SPS)

0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0

DIGITAL CURRENT (µ A)

WAIT TIME IN STANDBY MODE (Seconds)

GAIN = 1, LOW POWER

GAIN = 8, LOW POWER

GAI N = 16, LOW POWER

GAIN = 1, MID POWER

GAIN = 8, MID POWER

GAI N = 16, MI D P OWE R

GAIN = 1, FULL POWER

GAIN = 8, FULL POWER

GAI N = 16, FULL PO WER

13197-201

Figure 62. Digital Current vs. Wait Time in Standby Mode, ADC in Single

Conversion Mode (50 SPS)

200

400

600

800

1000

–0.08 –0.06 –0.04 –0.02 0 0.02 0.04 0.06 0.08

RMS NOISE (nV)

ANAL OG IN P UT V OLTAG E (V)

LOW POW E R, EX T E RNAL REF

MID POWE R, EXTERNAL REF

FULL POWE R , E X TERNAL RE F

LOW POW E R I NTE RNAL REF

MID PO W ER, I NTERNAL REF

FULL POWER, INTERNAL REF

13197-202

Figure 63. RMS Noise vs. Analog Input Voltage for the Internal Reference and

External Reference (Gain = 32, 50 SPS)

–3

–2

–1

–40 –25 –10 5 20 35 50 65 80 95 110 125

OSCILL

TOR ERROR (%)

TEMPERATURE (°C)

29 UNI T S

13197-064

Figure 64. Internal Oscillator Error vs. Temperature

Data Sheet AD7124-4

Rev. D | Page 27 of 93

TERMINOLOGY

AINP

AINP refers to the positive analog input.

AINM

AINM refers to the negative analog input.

Integral Nonlinearity (INL)

INL is the maximum deviation of any code from a straight line

passing through the endpoints of the transfer function. The

endpoints of the transfer function are zero scale (not to be

confused with bipolar zero), a point 0.5 LSB below the first code

transition (000 … 000 to 000 … 001), and full scale, a point

0.5 LSB above the last code transition (111 … 110 to 111 …

111). The error is expressed in ppm of the full-scale range.

Gain Error

Gain error is the deviation of the last code transition (111 …

110 to 111 … 111) from the ideal AINP voltage (AINM +

VREF/gain − 3/2 LSBs). Gain error applies to both unipolar

and bipolar analog input ranges.

Gain error is a measure of the span error of the ADC. It

includes full-scale errors but not zero-scale errors. For unipolar

input ranges, it is defined as full-scale error minus unipolar

offset error; whereas for bipolar input ranges, it is defined as

full-scale error minus bipolar zero error.

Offset Error

Offset error is the deviation of the first code transition from the

ideal AINP voltage (AINM + 0.5 LSB) when operating in the

unipolar mode.

In bipolar mode, offset error is the deviation of the midscale

transition (0111 … 111 to 1000 … 000) from the ideal AINP

voltage (AINM − 0.5 LSB).

Offset Calibration Range

In the system calibration modes, the AD7124-4 calibrates offset

with respect to the analog input. The offset calibration range

specification defines the range of voltages that the AD7124-4

can accept and still calibrate offset accurately.

Full-Scale Calibration Range

The full-scale calibration range is the range of voltages that the

AD7124-4 can accept in the system calibration mode and still

calibrate full scale correctly.

Input Span

In system calibration schemes, two voltages applied in sequence

to the AD7124-4 analog input define the analog input range.

The input span specification defines the minimum and

maximum input voltages from zero to full scale that the

AD7124-4 can accept and still calibrate gain accurately.

AD7124-4 Data Sheet

Rev. D | Page 28 of 93

RMS NOISE AND RESOLUTION

Table 8 through Table 37 show the rms noise, peak-to-peak

noise, effective resolution, and noise-free (peak-to-peak)

resolution of the AD7124-4 for various output data rates, gain

settings, and filters. The numbers given are for the bipolar input

range with an external 2.5 V reference. These numbers are

typical and are generated with a differential input voltage of 0 V

when the ADC is continuously converting on a single channel.

It is important to note that the effective resolution is calculated

using the rms noise, whereas the peak-to-peak resolution (shown

in parentheses) is calculated based on peak-to-peak noise

(shown in parentheses). The peak-to-peak resolution represents

the resolution for which there is no code flicker.

Effective Resolution = Log2(Input Range/RMS Noise)

Peak-to-Peak Resolution = Log2(Input Range/Peak-to-Peak

Noise

FULL POWER MODE

Sinc4

Table 8. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Full Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output Data

Rate (Zero

Latency

Mode) (SPS)

f3dB

(Hz) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 9.4 2.34 2.16 0.24 (1.5) 0.15 (0.89) 0.091 (0.6) 0.071 (0.41) 0.045 (0.26) 0.031 (0.17) 0.025 (0.15) 0.023 (0.14)

1920 10 2.5 2.3 0.23 (1.5) 0.14 (0.89) 0.094 (0.6) 0.076 (0.42) 0.048 (0.27) 0.03 (0.19) 0.025 (0.16) 0.025 (0.15)

960 20 5 4.6 0.31 (2.1) 0.22 (1.3) 0.13 (0.89) 0.1 (0.6) 0.069 (0.41) 0.044 (0.26) 0.035 (0.22) 0.034 (0.22)

480 40 10 9.2 0.42 (3) 0.3 (2.1) 0.19 (1.4) 0.14 (0.97) 0.09 (0.63) 0.063 (0.39) 0.053 (0.34) 0.043 (0.27)

384 50 12.5 11.5 0.48 (3.2) 0.33 (2.1) 0.2 (1.3) 0.16 (1.1) 0.1 (0.75) 0.068 (0.43) 0.059 (0.42) 0.048 (0.28)

320 60 15 13.8 0.51 (3.3) 0.35 (2.4) 0.23 (1.3) 0.17 (1.2) 0.11 (0.78) 0.077 (0.5) 0.064 (0.41) 0.056 (0.35)

240 80 20 18.4 0.6 (4.8) 0.41 (3) 0.28 (1.8) 0.19 (1.3) 0.13 (0.86) 0.09 (0.54) 0.072 (0.48) 0.063 (0.45)

120 160 40 36.8 0.86 (6.9) 0.55 (4.1) 0.37 (2.5) 0.29 (2) 0.2 (1.2) 0.13 (0.84) 0.11 (0.7) 0.098 (0.6)

60 320 80 73.6 1.2 (8.9) 0.76 (6.1) 0.53 (4.1) 0.4 (2.7) 0.26 (1.8) 0.18 (1.2) 0.15 (0.95) 0.14 (0.86)

30 640 160 147.2 1.7 (13) 1.1 (8.8) 0.74 (5.7) 0.57 (4.1) 0.38 (2.9) 0.26 (2) 0.22 (1.6) 0.19 (1.4)

1280

320

294.4

2.4 (19)

1.6 (13)

1.1 (8.4)

0.82 (6)

0.55 (4)

0.38 (2.5)

0.3 (2.3)

0.26 (1.8)

8 2400 600 552 3.3 (25) 2.3 (16) 1.5 (12) 1.2 (8) 0.76 (6) 0.53 (4) 0.43 (3.2) 0.37 (2.7)

4 4800 1200 1104 4.9 (38) 3.4 (25) 2.4 (20) 2 (13) 1.3 (9.1) 0.83 (6.4) 0.68 (4.8) 0.58 (4.3)

2 9600 2400 2208 8.8 (76) 6.8 (61) 4.9 (34) 4.3 (27) 2.6 (21) 1.7 (13) 1.3 (12) 1.2 (9.4)

1 19,200 4800 4416 72 (500) 38 (270) 21 (150) 13 (95) 7.5 (57) 4.4 (33) 3.3 (26) 2.8 (23)

Table 9. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Full Power Mode

Filter

Word

(Dec.)

Output

Data Rate

(SPS)

Output Data Rate

(Zero Latency

Mode) (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 9.4 2.34 24 (21.7) 24 (21.4) 23.7 (21) 23.1 (20.5) 22.7 (20.2) 22.3 (19.8) 21.6 (19) 20.7 (18.1)

1920 10 2.5 24 (21.7) 24 (21.4) 23.7 (21) 23 (20.5) 22.6 (20.1) 22.3 (19.7) 21.6 (19) 20.7 (18.1)

960 20 5 23.9 (21.2) 23.5 (20.8) 23.2 (20.4) 22.5 (20) 22.1 (19.5) 21.8 (19.2) 21.1 (18.4) 20.1 (17.4)

480 40 10 23.5 (20.7) 23 (20.3) 22.6 (19.8) 22.1 (19.3) 21.7 (18.9) 21.2 (18.6) 20.5 (17.8) 19.8 (17.1)

384 50 12.5 23.3 (20.5) 22.9 (20.2) 22.5 (19.6) 21.9 (19.1) 21.5 (18.7) 21.1 (18.5) 20.4 (17.7) 19.6 (17)

320 60 15 23.2 (20.3) 22.8 (20) 22.4 (19.5) 21.8 (19) 21.4 (18.6) 21 (18.3) 20.2 (17.6) 19.4 (16.6)

240 80 20 23 (20) 22.6 (19.7) 22.1 (19.3) 21.6 (18.9) 21.2 (18.5) 20.7 (18.1) 20 (17.3) 19.2 (16.4)

120 160 40 22.5 (19.5) 22.1 (19.2) 21.7 (18.9) 21 (18.3) 20.6 (18) 20.1 (17.5) 19.5 (16.9) 18.6 (16)

60 320 80 22 (19.1) 21.6 (18.6) 21.2 (18.2) 20.6 (17.8) 20.2 (17.4) 19.7 (17) 19 (16.3) 18.1 (15.5)

30 640 160 21.5 (18.5) 21.1 (18.1) 20.7 (17.7) 20.1 (17.2) 19.7 (16.8) 19.2 (16.3) 18.5 (15.6) 17.6 (14.8)

15 1280 320 21 (18) 20.5 (17.6) 20.2 (17.2) 19.5 (16.7) 19.1 (16.3) 18.7 (15.9) 18 (15.1) 17.2 (14.4)

8 2400 600 20.5 (17.5) 20.1 (17.2) 19.7 (16.7) 19 (16.2) 18.6 (15.7) 18.2 (15.3) 17.5 (14.6) 16.7 (13.8)

4 4800 1200 20 (17) 19.5 (16.5) 19 (16) 18.3 (15.6) 17.9 (15.1) 17.5 (14.6) 16.8 (14) 16 (13.2)

9600

2400

19.1 (16)

18.5 (15.3)

18 (15.1)

17.2 (14.5)

16.9 (13.9)

16.5 (13.5)

15.9 (12.7)

15 (12)

19,200

4800

16.1 (13.3)

16 (13.2)

15.9 (13)

15.5 (12.7)

15.4 (12.4)

15.1 (12.2)

14.6 (11.5)

13.8 (10.8)

Data Sheet AD7124-4

Rev. D | Page 29 of 93

Sinc3

Table 10. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Full Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output

Data Rate

(Zero

Latency

Mode)

(SPS)

f3dB

(Hz) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 9.4 3.13 2.56 0.23 (1.5) 0.15 (0.89) 0.096 (0.58) 0.07 (0.38) 0.046 (0.25) 0.033 (0.16) 0.023 (0.11) 0.017 (0.09)

1920 10 3.33 2.72 0.24 (1.5) 0.15 (0.89) 0.096 (0.6) 0.07 (0.4) 0.05 (0.26) 0.034 (0.17) 0.023 (0.12) 0.018 (0.09)

1280 20 5 5.44 0.31 (1.8) 0.18 (1.2) 0.12 (0.82) 0.09 (0.55) 0.059 (0.35) 0.041 (0.24) 0.033 (0.18) 0.027 (0.14)

640 30 10 8.16 0.4 (2.6) 0.26 (1.6) 0.17 (1.2) 0.11 (0.82) 0.088 (0.52) 0.055 (0.36) 0.048 (0.27) 0.039 (0.22)

384 50 16.67 13.6 0.53 (3.3) 0.3 (2.2) 0.2 (1.6) 0.17 (1.1) 0.1 (0.75) 0.075 (0.51) 0.062 (0.39) 0.056 (0.33)

320 60 20 16.32 0.55 (3.6) 0.37 (2.4) 0.24 (1.8) 0.19 (1.3) 0.12 (0.8) 0.084 (0.54) 0.068 (0.44) 0.06 (0.37)

160 120 40 32.64 0.78 (5.1) 0.53 (3.4) 0.35 (2.3) 0.26 (1.8) 0.17 (1.1) 0.12 (0.85) 0.1 (0.66) 0.097 (0.55)

80 240 80 65.28 1.1 (7) 0.73 (4.9) 0.49 (3.2) 0.37 (2.6) 0.25 (1.6) 0.17 (1.2) 0.14 (1) 0.12 (0.78)

40 480 160 130.56 1.5 (11) 1.1 (6.8) 0.67 (4.5) 0.52 (3.7) 0.34 (2.2) 0.25 (1.7) 0.19 (1.4) 0.17 (1.2)

960

320

261.12

2.3 (16)

1.5 (9.8)

0.99 (6.6)

0.75 (5.1)

0.53 (3.5)

0.35 (2.4)

0.28 (2.1)

0.25 (1.8)

1920

640

522.24

3.2 (26)

2.2 (16)

1.5 (11)

1.1 (8.5)

0.73 (5.5)

0.49 (3.9)

0.4 (3.2)

0.35 (2.7)

3200

1066.67

870.4

4.9 (38)

3.2 (24)

2.1 (15)

1.6 (12)

1 (7.7)

0.68 (5.6)

0.56 (4.2)

0.48 (3.6)

3 6400 2133.33 1740.8 25 (170) 13 (89) 7.1 (54) 4.3 (35) 2.4 (18) 1.5 (11) 1.1 (8.4) 0.9 (6.7)

2 9600 3200 2611.2 110 (820) 54 (390) 28 (210) 14 (110) 7.4 (57) 3.9 (27) 2.3 (17) 1.7 (13)

1 19,200 6400 5222.4 890 (6500) 430 (3000) 220 (1500) 110 (790) 55 (390) 28 (190) 14 (100) 7.6 (56)

Table 11. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate, Full Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output Data

Rate (Zero

Latency Mode)

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 9.4 3.13 24 (21.7) 24 (21.4) 23.6 (21) 23.1 (20.6) 22.7 (20.3) 22.2 (19.9) 21.7 (19.3) 21 (18.7)

1920 10 3.33 24 (21.7) 24 (21.4) 23.6 (21) 23.1 (20.6) 22.6 (20.2) 22.2 (19.8) 21.7 (19.3) 21 (18.7)

1280 20 5 24 (21.4) 23.7 (21) 23.2 (20.5) 22.7 (20.1) 22.3 (19.8) 21.9 (19.3) 21.2 (18.7) 20.5 (18.1)

640 30 10 23.6 (20.9) 23.2 (20.5) 22.8 (20) 22.2 (19.5) 21.8 (19.2) 21.4 (18.7) 20.6 (18.1) 19.9 (17.4)

384 50 16.67 23.2 (20.5) 22.8 (20.1) 22.4 (19.6) 21.8 (19.1) 21.4 (18.7) 21 (18.2) 20.3 (17.6) 19.4 (16.9)

320 60 20 23.1 (20.4) 22.7 (20) 22.3 (19.4) 21.7 (18.9) 21.3 (18.6) 20.8 (18.1) 20.1 (17.4) 19.3 (16.7)

160 120 40 22.6 (19.9) 22.2 (19.5) 21.8 (19) 21.2 (18.4) 20.8 (18.1) 20.3 (17.5) 19.6 (16.9) 18.7 (16.1)

80 240 80 22.1 (19.4) 21.7 (19) 21.3 (18.6) 20.7 (17.9) 20.3 (17.6) 19.8 (17) 19.1 (16.3) 18.3 (15.6)

480

160

21.6 (18.8)

21.2 (18.5)

20.8 (18.1)

20.2 (17.4)

19.8 (17.1)

19.3 (16.5)

18.6 (15.8)

17.8 (15)

960

320

21.1 (18.3)

20.7 (18)

20.3 (17.5)

19.7 (16.9)

19.2 (16.4)

18.8 (16)

18.1 (15.2)

17.3 (14.4)

10 1920 640 20.6 (17.6) 20.1 (17.2) 19.7 (16.8) 19.1 (16.2) 18.7 (15.8) 18.3 (15.3) 17.6 (14.6) 16.8 (13.8)

6 3200 1066.67 19.9 (17) 19.6 (16.6) 19.2 (16.3) 18.6 (15.6) 18.2 (15.3) 17.8 (14.8) 17.1 (14.2) 16.3 (13.4)

3 6400 2133.33 17.6 (14.8) 17.6 (14.8) 17.4 (14.5) 17.2 (14.1) 17 (14.1) 16.7 (13.8) 16.3 (13.2) 15.4 (12.5)

2 9600 3200 15.5 (12.6) 15.5 (12.6) 15.4 (12.6) 15.4 (12.5) 15.4 (12.4) 15.3 (12.5) 15 (12.2) 14.5 (11.6)

1 19,200 6400 12.5 (9.7) 12.5 (9.7) 12.5 (9.7) 12.5 (9.6) 12.5 (9.6) 12.4 (9.6 12.4 (9.6) 12.3 (9.5)

Post Filters

Table 12. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Full Power Mode

Output Data Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

16.67 0.51 (3.3) 0.34 (2.1) 0.21 (1.3) 0.16 (0.97) 0.11 (0.65) 0.075 (0.41) 0.062 (0.34) 0.051(0.3)

20 0.53 (3.3) 0.36 (2.1) 0.23 (1.3) 0.18 (1) 0.11 (0.65) 0.078 (0.45) 0.062 (0.34) 0.051 (0.3)

25 0.57 (3.6) 0.37 (2.2) 0.25 (1.6) 0.18 (1.2) 0.12 (0.75) 0.082 (0.47) 0.062 (0.38) 0.055 (0.31)

27.27 0.6 (3.9) 0.38 (2.2) 0.26 (1.6) 0.19 (1.2) 0.13 (0.82) 0.084 (0.55) 0.072 (0.44) 0.063 (0.43)

AD7124-4 Data Sheet

Rev. D | Page 30 of 93

Table 13. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Full Power Mode

Output Data Rate (SPS)

Gain = 1

Gain = 2

Gain = 4

Gain = 8

Gain = 16

Gain = 32

Gain = 64

Gain = 128

16.67 23.2 (20.5) 22.8 (20.2) 22.5 (19.9) 21.9 (19.3) 21.5 (18.9) 21 (18.5) 20.3 (17.8) 19.5 (17)

20 23.2 (20.5) 22.7 (20.2) 22.3 (19.9) 21.7 (19.2) 21.5 (18.9) 20.9 (18.4) 20.3 (17.8) 19.5 (17)

25 23.1 (20.4) 22.7 (20.1) 22.2 (19.6) 21.7 (19) 21.3 (18.7) 20.9 (18.3) 20.3 (17.7) 19.5 (17)

27.27 23 (20.3) 22.6 (20.1) 22.2 (19.5) 21.7 (19) 21.2 (18.5) 20.8 (18.1) 20.1 (17.4) 19.2 (16.5)

Fast Settling Filter (Sinc4 + Sinc1)

Table 14. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Full Power Mode (Average by 16)

Filter

Word

(Dec.)

Output

Data Rate

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

384 2.63 0.19 (1.2) 0.11 (0.75) 0.077 (0.52) 0.063 (0.34) 0.036 (0.21) 0.027 (0.17) 0.021 (0.11) 0.019 (0.098)

120 8.42 0.32 (2.1) 0.2 (1.3) 0.13 (0.97) 0.1 (0.63) 0.067 (0.46) 0.045 (0.28) 0.039 (0.23) 0.031 (0.2)

24 42.11 0.69 (4.6) 0.44 (3) 0.29 (2.1) 0.23 (1.6) 0.14 (0.99) 0.1 (0.72) 0.081 (0.54) 0.07 (0.49)

20 50.53 0.71 (5.1) 0.49 (3.1) 0.3 (2.2) 0.25 (1.7) 0.16 (1.1) 0.11 (0.78) 0.09 (0.6) 0.082 (0.57)

2 505.26 2.4 (18) 1.6 (10) 1.1 (8.3) 0.87 (5.5) 0.56 (3.5) 0.47 (2.9) 0.33 (2.1) 0.3 (2)

1 1010.53 4.8 (35) 3 (20) 1.9 (12) 1.4 (8.8) 0.89 (5.2) 0.57 (3.7) 0.49 (3) 0.44 (3)

Table 15. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Full Power Mode (Average by 16)

Filter Word

(Dec.)

Output Data Rate

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

384 2.63 24 (22) 24 (21.7) 23.9 (21.2) 23.3 (20.8) 23 (20.5) 22.5 (19.8) 21.8 (19.5) 21 (18.6)

120

8.42

23.9 (21.2)

23.6 (20.8)

23.3 (20.3)

22.5 (19.9)

22.2 (19.4)

21.9 (19.1)

20.9 (18.4)

20.2 (17.6)

42.11

22.8 (20)

22.4 (19.7)

22.1 (19.2)

21.4 (18.6)

21.1 (18.3)

20.5 (17.7)

19.9 (17.1)

19.1 (16.3)

50.53

22.7 (19.9)

22.3 (19.6)

22 (19.1)

21.2 (18.5)

20.9 (18.1)

20.4 (17.6)

19.7 (17)

18.9 (16.1)

2 505.26 21 (18.1) 20.6 (17.9) 20.2 (17.2) 19.5 (16.8) 19.1 (16.4) 18.4 (15.7) 17.8 (15.2) 17 (14.3)

1 1010.53 20 (17.1) 19.7 (16.9) 19.3 (16.6) 18.8 (16.1) 18.4 (15.9) 18.1 (15.4) 17.3 (14.7) 16.5 (13.7)

Fast Settling Filter (Sinc3 + Sinc1)

Table 16. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Full Power Mode (Average by 16)

Filter Word

(Dec.)

Output Data Rate

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

384 2.78 0.22 (1.4) 0.13 (0.75) 0.081 (0.44) 0.048 (0.3) 0.039 (0.24) 0.026 (0.18) 0.025 (0.13) 0.019 (0.11)

120 8.89 0.31 (2.1) 0.21 (1.3) 0.13 (0.89) 0.1 (0.63) 0.068 (0.47) 0.047 (0.28) 0.036 (0.25) 0.033 (0.17)

24 44.44 0.7 (4.8) 0.46 (3.1) 0.29 (2.1) 0.22 (1.5) 0.14 (0.95) 0.098 (0.67) 0.079 (0.56) 0.071 (0.44)

20 53.33 0.77 (5.2) 0.5 (3.4) 0.31 (2.3) 0.24 (1.6) 0.17 (1) 0.11 (0.73) 0.09 (0.66) 0.077 (0.48)

2 533.33 6.1 (46) 3.2 (23) 1.8 (12) 1.1 (7.5) 0.65 (4.3) 0.4 (2.7) 0.31 (2.2) 0.27 (2)

1 1066.67 44 (320) 22 (160) 11 (80) 5.7 (40) 2.9 (22) 1.5 (11) 0.83 (6.2) 0.54 (4)

Table 17. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Full Power Mode (Average by 16)

Filter Word

(Dec.)

Output Data Rate

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

384 2.78 24 (21.8) 24 (21.7) 23.9 (21.4) 23.6 (21) 22.9 (20.3) 22.5 (19.8) 21.6 (19.2) 21 (18.4)

120 8.89 24 (21.2) 23.5 (20.9) 23.2 (20.4) 22.6 (19.9) 22.1 (19.4) 21.7 (19.1) 21 (18.3) 20.2 (17.8)

24 44.44 22.8 (20) 22.4 (19.6) 22.1 (19.2) 21.4 (18.7) 21.1 (18.3) 20.6 (17.8) 19.9 (17.1) 19.1 (16.5)

20 53.33 22.6 (19.9) 22.3 (19.5) 22 (19.1) 21.3 (18.6) 20.8 (18.2) 20.4 (17.7) 19.7 (16.9) 19 (16.3)

2 533.33 19.7 (16.8) 19.6 (16.8) 19.4 (16.6) 19.1 (16.3) 18.9 (16.1) 18.6 (15.8) 17.9 (15.1) 17.2 (14.3)

1 1066.67 16.8 (13.9) 16.8 (13.9) 16.8 (13.9) 16.7 (13.9) 16.7 (13.8) 16.6 (13.8) 16.5 (13.6) 16.1 (13.3)

Data Sheet AD7124-4

Rev. D | Page 31 of 93

MID POWER MODE

Sinc4

Table 18. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Mid Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output Data

Rate (Zero

Latency

Mode) (SPS)

f3dB

(Hz) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 2.34 0.586 0.52 0.22 (1.4) 0.14 (0.88) 0.095 (0.6) 0.062 (0.38) 0.048 (0.24) 0.036 (0.17) 0.024 (0.14) 0.02 (0.1)

1920 2.5 0.625 0.575 0.25 (1.4) 0.17 (0.88) 0.11 (0.6) 0.073 (0.38) 0.048 (0.24) 0.037 (0.19) 0.024 (0.14) 0.021 (0.1)

960 5 1.25 1.15 0.34 (2) 0.21 (1.2) 0.13 (0.77) 0.085 (0.52) 0.064 (0.36) 0.052(0.25) 0.04 (0.21) 0.035 (0.2)

480 10 2.5 2.3 0.44 (2.8) 0.28 (1.8) 0.19 (1.1) 0.1 (0.82) 0.1 (0.55) 0.072 (0.41) 0.057 (0.34) 0.048 (0.28)

240 20 5 4.6 0.67 (3.8) 0.4 (2.4) 0.27 (1.6) 0.2 (1.1) 0.14 (0.85) 0.098 (0.64) 0.081 (0.47) 0.07 (0.43)

120 40 10 9.2 0.98 (6) 0.58 (3.6) 0.37 (2.3) 0.27 (1.7) 0.2 (1.1) 0.14 (0.87) 0.11 (0.74) 0.09 (0.57)

96 50 12.5 11.5 1 (7.4) 0.67 (4.2) 0.41 (2.5) 0.28 (1.9) 0.23 (1.3) 0.15 (0.95) 0.13 (0.78) 0.11 (0.7)

80 60 15 13.8 1.1 (7.2) 0.7 (4.3) 0.44 (3) 0.33 (2.1) 0.24 (1.4) 0.17 (1.1) 0.14 (0.89) 0.12 (0.75)

60 80 20 18.4 1.3 (8.4) 0.8 (5.1) 0.53 (3.4) 0.37 (2.4) 0.27 (1.6) 0.2 (1.3) 0.18 (1.1) 0.13 (0.82)

30 160 40 36.8 1.8 (11) 1.2 (7.6) 0.73 (4.6) 0.54 (3.4) 0.39 (2.4) 0.28 (1.9) 0.23 (1.4) 0.19 (1.2)

15 320 80 73.6 2.6 (17) 1.7 (11) 1 (6.6) 0.79 (4.7) 0.58 (3.4) 0.4 (2.5) 0.33 (2) 0.26 (1.5)

8 600 150 138 3.7 (23) 2.3 (15) 1.5 (9.6) 1.2 (7.2) 0.84 (5) 0.56 (4) 0.46 (2.8) 0.4 (2.6)

4 1200 300 276 5.3 (36) 3.6 (24) 2.4 (16) 1.9 (13) 1.3 (8.2) 0.85 (6) 0.68 (4.3) 0.6 (4.5)

2 2400 600 552 9.3 (72) 6.8 (53) 4.8 (35) 4.1 (34) 2.5 (19) 1.7 (13) 1.3 (10) 1.2 (9.7)

1 4800 1200 1104 71 (500) 37 (270) 21 (160) 13 (98) 7.2 (55) 4.3 (33) 3.1 (24) 2.6 (21)

Table 19. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Mid Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output Data

Rate (Zero

Latency Mode)

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 2.34 0.586 24 (21.8) 24 (21.4) 23.6 (21) 23.3 (20.6) 22.6 (20.3) 22.1 (19.7) 21.6 (19.1) 20.9 (18.5)

1920 2.5 0.625 24 (21.8) 23.8 (21.4) 23.5 (21) 23 (20.6) 22.6 (20.3) 22 (19.7) 21.6 (19.1) 20.8 (18.5)

960 5 1.25 23.8 (21.2) 23.5 (21) 23.2 (20.6) 22.8 (20.2) 22.2 (19.7) 21.5 (19.2) 20.9 (18.5) 20.1 (17.6)

480 10 2.5 23.4 (20.8) 23.1 (20.4) 22.7 (20.1) 22.2 (19.6) 21.5 (19.1) 21 (18.5) 20.4 (17.8) 19.6 (17.1)

240 20 5 22.8 (20.3) 22.5 (20) 22.1 (19.6) 21.6 (19.1) 21.1 (18.5) 20.6 (17.9) 19.9 (17.3) 19.1 (16.5)

120 40 10 22.3 (19.7) 22 (19.4) 21.7 (19) 21.1 (18.5) 20.6 (18.1) 20.1 (17.5) 19.4 (16.8) 18.7 (16)

96 50 12.5 22.2 (19.5) 21.8 (19.2) 21.5 (18.9) 21 (18.3) 20.4 (17.9) 19.9 (17.3) 19.2 (16.6) 18.5 (15.8)

80 60 15 22.1 (19.4) 21.7 (19.1) 21.4 (18.7) 20.9 (18.2) 20.3 (17.8) 19.8 (17.2) 19.1 (16.4) 18.4 (15.7)

60 80 20 21.9 (19.2) 21.5 (18.9) 21.1 (18.5) 20.7 (18) 20.1 (17.6) 19.6 (16.9) 18.9 (16.2) 18.2 (15.5)

30 160 40 21.4 (18.8) 21 (18.9) 20.7 (18.5) 20.2 (17.5) 19.6 (17) 19.1 (16.3) 18.4 (15.8) 17.7 (15)

15 320 80 20.9 (18.2) 20.5 (17.8) 20.2 (17.5) 19.6 (17) 19 (16.5) 18.6 (15.9) 17.9 (15.3) 17.2 (14.6)

8 600 150 20.4 (17.7) 20 (17.3) 19.7 (17) 19 (16.4) 18.5 (15.9) 18.1 (15.3) 17.4 (14.8) 16.6 (13.9)

4 1200 300 19.8 (17.1) 19.4 (16.7) 19 (16.3) 18.3 (15.6) 17.9 (15.2) 17.5 (14.7) 16.8 (14) 16 (13.1)

2 2400 600 19 (16.1) 18.5 (15.5) 18 (15.1) 17.2 (14.2) 16.9 (14) 16.5 (13.6) 15.8 (12.9) 15 (12)

1 4800 1200 16.1 (13.3) 16 (13.2) 15.9 (12.9) 15.5 (12.6) 15.4 (12.5) 15.1 (12.2) 14.6 (11.7) 13.9 (10.9)

AD7124-4 Data Sheet

Rev. D | Page 32 of 93

Sinc3

Table 20. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Mid Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output

Data Rate

(Zero

Latency

Mode) (SPS)

f3dB

(Hz) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 2.34 0.78 0.64 0.25 (1.5) 0.17 (1) 0.087 (0.58) 0.065 (0.4) 0.049 (0.27) 0.034 (0.19) 0.03 (0.16) 0.022 (0.11)

960 5 1.67 1.36 0.35 (2.2) 0.23 (1.3) 0.14 (0.82) 0.1 (0.58) 0.074 (0.43) 0.053 (0.31) 0.041 (0.22) 0.034 (0.17)

480 10 3.33 2.72 0.5 (3.1) 0.31 (1.9) 0.19 (1.3) 0.14 (0.89) 0.1 (0.63) 0.075 (0.44) 0.6 (0.35) 0.049 (0.28)

320 15 5 4.08 0.6 (3.8) 0.38 (2.4) 0.24 (1.6) 0.17 (1.1) 0.13 (0.8) 0.089 (0.54) 0.076 (0.46) 0.062 (0.35)

160 30 10 8.16 0.83 (5.6) 0.54 (3.3) 0.34 (2.2) 0.24 (1.6) 0.18 (1.1) 0.13 (0.77) 0.1 (0.65) 0.088 (0.53)

96 50 16.67 13.6 1.1 (7.5) 0.72 (4.4) 0.44 (2.9) 0.31 (2) 0.24 (1.5) 0.17 (1) 0.14 (0.82) 0.11 (0.7)

80 60 20 16.32 1.2 (7.7) 0.8 (4.8) 0.48 (3.1) 0.35 (2.2) 0.25 (1.6) 0.18 (1.1) 0.15 (0.94) 0.12 (0.77)

40 120 40 32.64 1.7 (11) 1.1 (7) 0.7 (4.6) 0.47 (3.2) 0.36 (2.2) 0.26 (1.7) 0.21 (1.5) 0.18 (1.1)

20 240 80 65.28 2.5 (16) 1.6 (9.7) 0.94 (6.2) 0.7 (5) 0.53 (3.2) 0.37 (2.3) 0.31 (2.1) 0.26 (1.8)

10 480 160 130.6 3.5 (24) 2.2 (15) 1.4 (9.3) 1 (7) 0.78 (5.3) 0.56 (3.9) 0.46 (3.1) 0.38 (2.5)

5 960 320 261.1 6.7 (53) 4.1 (34) 2.5 (19) 1.8 (14) 1.2 (8.7) 0.84 (6.4) 0.67 (5) 0.57 (3.9)

3 1600 533.33 435.2 25 (170) 13 (90) 7.1 (53) 4.2 (30) 2.4 (18) 1.5 (11) 1.1 (7.8) 0.89 (6.8)

2 2400 800 652.8 110 (740) 54 (360) 27 (200) 14 (110) 7.4 (51) 3.9 (29) 2.3 (16) 1.6 (12)

4800

1600

1306

880 (5800)

430 (3100)

220 (1500)

110 (760)

55 (400)

27 (180)

14 (110)

7.5 (56)

Table 21. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Mid Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output Data

Rate (Zero

Latency

Mode) (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 2.34 0.78 24 (21.7) 23.8 (21.2) 23.6 (21) 23.2 (20.6) 22.6 (20.1) 22.1 (19.6) 21.3 (18.9) 20.7 (18.4)

960 5 1.67 23.8 (21.1) 23.4 (20.8) 23.1 (20.5) 22.6 (20) 22 (19.5) 21.5 19) 20.8 (18.4) 20.1 (17.8)

480 10 3.33 23.3 (20.6) 22.9 (20.3) 22.6 (19.9) 22.1 (19.4) 21.5 (18.9) 21 (18.4) 20.3 (17.8) 19.6 (17.1)

320 15 5 23 (20.3) 22.6 (20) 22.3 (19.6) 21.8 (19.1) 21.2 (18.6) 20.7 (18.1) 20 (17.4) 19.3 (16.8)

160 30 10 22.5 (19.8) 22.1 (19.5) 21.8 (19.1) 21.3 (18.6) 20.7 (18.1) 20.2 (17.6) 19.5 (16.9) 18.8 (16.2)

96 50 16.67 22.1 (19.4) 21.7 (19.1) 21.4 (18.7) 20.9 (18.2) 20.3 (17.7) 19.8 (17.2) 19.1 (16.5) 18.4 (15.8)

80 60 20 22 (19.3) 21.6 (19) 21.3 (18.6) 20.8 (18.1) 20.2 (17.6) 19.7 (17.1) 19.1 (16.3) 18.3 (15.6)

40 120 40 21.5 (18.8) 21.1 (18.5) 20.8 (18.1) 20.3 (17.6) 19.7 (17.1) 19.2 (16.5) 18.5 (15.7) 17.7 (15.1)

20 240 80 21 (18.3) 20.6 (18) 20.3 (17.6) 19.8 (17) 19.2 (16.6) 18.7 (16) 18 (15.2) 17.2 (14.4)

10 480 160 20.4 (17.7) 20.1 (17.3) 19.8 (17) 19.2 (16.4) 18.6 (15.9) 18.1 (15.3) 17.4 (14.6) 16.7 (13.9)

5 960 320 19.5 (16.5) 19.2 (16.2) 19 (16) 18.4 (15.4) 18 (15.1) 17.5 (14.6) 16.8 (13.9) 16.1 (13.3)

3 1600 533.33 17.6 (14.8) 17.5 (14.8) 17.4 (14.5) 17.2 (14.3) 17 (14.1) 16.7 (13.8) 16.1 (13.3) 15.4 (12.6)

2 2400 800 15.5 (12.7) 15.5 (12.7) 15.5 (12.6) 15.4 (12.6) 15.4 (12.6) 15.3 (12.4) 15 (12.3) 14.6 (11.7)

1 4800 1600 12.5 (9.7) 12.5 (9.7) 12.5 (9.7) 12.5 (9.7) 12.5 (9.6) 12.5 (9.6) 12.4 (9.5) 12.4 (9.4)

Post Filters

Table 22. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Mid Power Mode

Output Data Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

16.67 1.1 (6.3) 0.69 (4) 0.41 (2.5) 0.31 (2) 0.23 (1.4) 0.17 (0.96) 0.13 (0.79) 0.11 (0.61)

20 1.1 (6.9) 0.7 (4) 0.41 (2.5) 0.33 (2.1) 0.23 (1.5) 0.18 (0.96) 0.14 (0.81) 0.12 (0.67)

25 1.2 (8) 0.8 (4.6) 0.46 (2.8) 0.36 (2.3) 0.25 (1.5) 0.17 (1) 0.15 (0.9) 0.12 (0.74)

27.27 1.3 (9.2) 0.82 (4.8) 0.48 (2.8) 0.36 (2.3) 0.28 (1.6) 0.19 (1.1) 0.16 (1) 0.13 (0.79)

Table 23. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Mid Power Mode

Output Data Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

16.67 22.1 (19.6) 21.8 (19.2) 21.5 (18.9) 20.9 (18.3) 20.4 (17.8) 19.8 (17.3) 19.2 (16.6) 18.4 (16)

20 22.1 (19.5) 21.8 (19.2) 21.5 (18.9) 20.9 (18.2) 20.4 (17.7) 19.8 (17.3) 19 (16.6) 18.3 (15.8)

25 22 (19.2) 21.6 (19.1) 21.4 (18.8) 20.7 (18.1) 20.3 (17.6) 19.7 (17.2) 18.9 (16.4) 18.2 (15.7)

27.27 21.9 (19) 21.5 (19) 21.3 (18.8) 20.7 (18.1) 21.1 (17.6) 19.7 (17.1) 18.9 (16.3) 18.2 (15.6)

Data Sheet AD7124-4

Rev. D | Page 33 of 93

Fast Settling Filter (Sinc4 + Sinc1)

Table 24. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Mid Power Mode (Average by 16)

Filter Word

(Dec.)

Output Data Rate

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

96 2.63 0.36 (2.4) 0.23 (1.5) 0.15 (0.82) 0.1 (0.71) 0.078 (0.44) 0.056 (0.35) 0.045 (0.26) 0.038 (0.21)

30 8.42 0.67 (4.2) 0.44 (2.7) 0.26 (1.6) 0.18 (1.1) 0.14 (0.8) 0.1 (0.54) 0.08 (0.48) 0.067 (0.41)

42.11

1.5 (9)

0.96 (6.1)

0.57 (3.7)

0.42 (2.6)

0.32 (1.9)

0.22 (1.5)

0.18 (1.1)

0.15 (0.95)

5 50.53 1.6 (9.3) 1 (7.7) 0.62 (4) 0.46 (3) 0.33 (2) 0.24 (1.6) 0.2 (1.3) 0.17 (1.2)

126.32

2.5 (15)

1.6 (11)

1 (7.2)

0.76 (4.9)

0.57 (3.7)

0.41 (2.7)

0.32 (2.4)

0.29 (1.9)

1 252.63 5.2 (21) 3.1 (19) 1.8 (11) 1.4 (9.8) 0.92 (6.2) 0.62 (4.2) 0.49 (3) 0.41 (3)

Table 25. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Mid Power Mode (Average by 16)

Filter Word

(Dec.)

Output Data Rate

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

96 2.63 23.7 (21) 23.4 (20.7) 23 (20.5) 22.5 (19.8) 21.9 (19.4) 21.4 (18.8) 20.7 (18.2) 20 (17.5)

30 8.42 22.8 (20.2) 22.4 (19.8) 22.2 (19.5) 21.7 (19.1) 21 (18.6) 20.6 (18.1) 19.9 (17.3) 19.1 (16.5)

6 42.11 21.7 (19.1) 21.3 (18.6) 21.1 (18.4) 20.5 (17.9) 19.9 (17.3) 19.4 (16.7) 18.7 (16) 18 (15.2)

5 50.53 21.5 (19) 21.2 (18.4) 20.9 (18.2) 20.4 (17.8) 19.8 (17.2) 19.3 (16.6) 18.5 (15.9) 17.8 (15)

2 126.32 20.9 (18.3) 20.5 (17.8) 20.2 (17.4) 19.6 (17) 19.1 (16.4) 18.6 (15.8) 17.9 (15.2) 17.1 (14.3)

1 252.63 19.9 (17.3) 19.6 (17) 19.4 (16.8) 18.8 (16) 18.4 (15.6) 17.9 (15.2) 17.3 (14.7) 16.5 (13.7)

Fast Settling Filter (Sinc3 + Sinc1)

Table 26. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Mid Power Mode (Average by 16)

Filter Word

(Dec.)

Output Data Rate

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

96 2.78 0.39 (2.4) 0.25 (1.5) 0.16 (1) 0.11 (0.67) 0.08 (0.48) 0.058 (0.31) 0.047 (0.27) 0.039 (0.23)

30 8.89 0.71 (4.2) 0.43 (2.5) 0.27 (1.6) 0.19 (1.1) 0.15 (1) 0.098 (0.64) 0.083 (0.47) 0.068 (0.4)

44.44

1.5 (9.5)

0.93 (6)

0.59 (3.8)

0.43 (2.6)

0.32 (2.1)

0.22 (1.5)

0.18 (1.1)

0.15 (0.98)

53.33

1.6 (11)

1 (6.9)

0.66 (4.2)

0.46 (2.8)

0.35 (2.3)

0.24 (1.6)

0.2 (1.2)

0.17 (1.1)

2 133.33 6 (37) 3.2 (20) 1.8 (11) 1 (7.2) 0.63 (4.5) 0.43 (3) 0.33 (2.2) 0.27 (1.8)

1 266.67 44 (320) 23 (160) 12 (83) 5.7 (41) 3 (20) 1.6 (9.9) 0.84 (6.4) 0.56 (3.5)

Table 27. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Mid Power Mode (Average by 16)

Filter

Word

(Dec.)

Output Data

Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

96 2.78 23.6 (21) 23.3 (20.7) 22.9 (20.3) 22.5 (19.8) 21.9 (19.3) 21.4 (18.9) 20.7 (18.1) 19.9 (17.4)

30 8.89 22.7 (20.2) 22.5 (19.9) 22.2 (19.6) 21.7 (19.1) 21 (18.3) 20.6 (17.9) 19.8 (17.3) 19.1 (16.6)

6 44.44 21.7 (19) 21.4 (18.7) 21 (18.3) 20.5 (17.9) 19.9 (17.2) 19.4 (16.7) 18.7 (16.1) 18 (15.3)

5 53.33 21.5 (18.8) 21.2 (18.5) 20.9 (18.2) 20.4 (17.8) 19.8 (17.1) 19.3 (16.6) 18.6 (16) 17.8 (15.1)

2 133.33 19.7 (17) 19.6 (16.9) 19.4 (16.8) 19.2 (16.4) 18.9 (16.1) 18.5 (15.7) 17.8 (15.1) 17.1 (14.4)

1 266.67 16.8 (13.9) 16.7 (13.9) 16.7 (13.9) 16.7 (13.9) 16.7 (13.9) 16.6 (13.9) 16.5 (13.6) 16.1 (13.4)

AD7124-4 Data Sheet

Rev. D | Page 34 of 93

LOW POWER MODE

Sinc4

Table 28. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Low Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output

Data

Rate

(Zero

Latency

Mode)

(SPS)

f3dB

(Hz) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 1.17 0.293 0.269 0.22 (1.2) 0.15 (0.89) 0.095 (0.67) 0.071 (0.41) 0.053 (0.26) 0.043 (0.2) 0.035 (0.16) 0.024 (0.12)

1920 1.25 0.3125 0.288 0.24 (1.5) 0.15 (0.89) 0.095 (0.67) 0.071 (0.41) 0.053 (0.26) 0.043 (0.2) 0.035 (0.16) 0.024 (0.12)

960 2.5 0.625 0.575 0.37 (2.1) 0.23 (1.2) 0.13 (0.82) 0.1 (0.61) 0.068 (0.37) 0.055 (0.26) 0.041 (0.23) 0.035 (0.17)

480 5 1.25 1.15 0.5 (3) 0.3 (1.7) 0.18 (1.2) 0.13 (0.77) 0.099 (0.56) 0.078 (0.39) 0.06 (0.31) 0.052 (0.26)

240 10 2.5 2.3 0.65 (4.1) 0.42 (2.5) 0.26 (1.9) 0.2 (1.1) 0.14 (0.8) 0.1 (0.6) 0.085 (0.5) 0.072 (0.43)

120 20 5 4.6 0.9 (5.8) 0.61 (3.5) 0.38 (2.5) 0.28 (1.7) 0.2 1.2) 0.15 (0.85) 0.12 (0.68) 0.096 (0.6)

60 40 10 9.2 1.3 (8) 0.82 (5) 0.53 (3.7) 0.38 (2.4) 0.29 (1.8) 0.21 (1) 0.17 (0.95) 0.14 (0.9)

48 50 12.5 11.5 1.4 (9.3) 0.95 (6) 0.6 (4.2) 0.46 (2.8) 0.32 (2.1) 0.24 (1.5) 0.2 (1.1) 0.16 (1)

40 60 15 13.8 1.6 (10) 0.99 (6.6) 0.64 (4.5) 0.47 (3.2) 0.35 (2.2) 0.26 (1.7) 0.21 (1.3) 0.17 (1.1)

30 80 20 18.4 1.8 (12) 1.2 (7.5) 0.77 (5.1) 0.55 (3.7) 0.4 (2.7) 0.3 (2) 0.25 (1.6) 0.19 (1.3)

15 160 40 36.8 2.6 (17) 1.8 (11) 1.1 (7.2) 0.85 (5.7) 0.56 (3.9) 0.41 (2.5) 0.33 (2.1) 0.28 (1.6)

8 300 75 69 3.7 (24) 2.5 (17) 1.6 (11) 1.2 (7.5) 0.87 (5.6) 0.58 (3.9) 0.48 (2.9) 0.39 (2.6)

4 600 150 138 5.2 (35) 4 (24) 2.6 (17) 2.1 (13) 1.4 (8.5) 1 (6) 0.76 (5.2) 0.6 (3.9)

2 1200 300 276 9.4 (57) 7.6 (47) 5.8 (36) 4.9 (32) 3 (19) 1.9 (11) 1.4 (9) 1.3 (7.8)

2400

600

552

72 (470)

39 (240)

22 (130)

16 (110)

8 (49)

4.8 (29)

3.3 (21)

2.6 (18)

Table 29. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate, Low Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output Data

Rate (Zero

Latency

Mode) (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 1.17 0.29311 24 (22) 23.8 (21.4) 23.7 (20.9) 23.2 (20.5) 22.7 (20.2) 21.8 (19.7) 21.3 (18.9) 20.6 (18.3)

1920 1.25 0.3125 24 (21.7) 23.8 (21.3) 23.6 (20.8) 23.1 (20.5) 22.6 (20.1) 21.8 (19.6) 21.2 (18.9) 20.6 (18.3)

960 2.5 0.625 23.7 (21.2) 23.4 (21) 23.2 (20.5) 22.6 (20) 22.1 (19.7) 21.4 (19.2) 20.8 (18.4) 20.1 (17.8)

480 5 1.25 23.3 (20.7) 23 (20.5) 22.7 (20) 22.1 (19.6) 21.6 (19.1) 20.9 (18.6) 20.3 (17.9) 19.5 (17.2

240 10 2.5 22.9 (20.2) 22.5 (19.9) 22.2 (19.4) 21.6 (19.1) 21.1 (18.6) 20.5 (18) 19.8 (17.2) 19.1 (16.5)

120 20 5 22.4 (19.7) 22 (19.4) 21.7 (18.9) 21.1 (18.5) 20.6 (18) 20 (17.5) 19.3 (16.8) 18.6 (16)

60 40 10 21.9 (19.2) 21.5 (18.9) 21.2 (18.4) 20.6 (18) 20.1 (17.4) 19.5 (17.3) 18.8 (16.3) 18.1 (15.4)

48 50 12.5 21.7 (19) 21.3 (18.7) 21 (18.2) 20.4 (17.8) 19.9 (17.2) 19.3 (16.7) 18.6 (16.1) 17.9 (15.2)

40 60 15 21.6 (18.9) 21.2 (18.5) 20.9 (18.1) 20.3 (17.6) 19.8 (17.1) 19.2 (16.5) 18.5 (15.9) 17.8 (15.1)

30 80 20 21.4 (18.7) 21 (18.3) 20.6 (17.9) 20.1 (17.4) 19.6 (16.8) 19 (16.2) 18.3 (15.6) 17.6 (14.9)

15 160 40 20.9 (18.2) 20.4 (17.8) 20.1 (17.4) 19.5 (16.8) 19.1 (16.3) 18.5 (15.7) 17.8 (15.2) 17.1 (14.5)

300

20.4 (17.7)

19.9 (17.2)

19.6 (16.8)

19 (16.3)

18.5 (15.8)

18 (15.3)

17.3 (14.7)

16.6 (13.9)

4 600 150 19.9 (17.1) 19.3 (16.7) 18.9 (16.2) 18.2 (15.6) 17.8 (15.2) 17.3 (14.7) 16.7 (13.9) 16 (13.3)

1200

300

19 (16.4)

18.3 (15.7)

17.7 (15.1)

17 (14.3)

16.7 (14)

16.3 (13.8)

15.7 (13.1)

14.9 (12.3)

1 2400 600 16.1 (13.4) 16 (13.4) 15.8 (13.3) 15.3 (12.5) 15.2 (12.5) 15 (12.4) 14.5 (11.9) 13.9 (11)

Data Sheet AD7124-4

Rev. D | Page 35 of 93

Sinc3

Table 30. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Low Power Mode

Filter

Word

(Dec.)

Output

Data

Rate

(SPS)

Output

Data

Rate

(Zero

Latency

Mode)

(SPS)

f3dB

(Hz) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 1.17 0.39 0.32 0.26 (1.5) 0.17 (0.9) 0.099 (0.6) 0.072 (0.36) 0.055 (0.27) 0.039 (0.21) 0.032 (0.16) 0.026 (0.13)

480 5 1.67 1.36 0.51 (3.1) 0.31 (1.9) 0.2 (1.3) 0.15 (0.86) 0.11 (0.65) 0.078 (0.45) 0.063 (0.37) 0.05 (0.28)

240 10 3.33 2.72 0.75 (4.5) 0.45 (2.8) 0.29 (2) 0.21 (1.3) 0.16 (0.9) 0.11 (0.65) 0.085 (0.51) 0.071 (0.39)

160 15 5 4.08 0.88 (5.5) 0.55 (3.3) 0.3 (2.4) 0.26 (1.6) 0.19 (1.2) 0.14 (0.79) 0.1 (0.62) 0.089 (0.53)

80 30 10 8.16 1.3 (7.8) 0.77 (4.9) 0.47 (3.3) 0.36 (2.2) 0.27 (1.7) 0.19 (1.2) 0.15 (0.94) 0.12 (0.72)

48 50 16.67 13.6 1.7 (9.9) 1 (6.4) 0.63 (4.6) 0.47 (3.1) 0.36 (2.2) 0.26 (1.7) 0.2 ( 1.3) 0.16 (1)

16.32

1.8 (12)

1.1 (7)

0.71 (5)

0.52 (3.4)

0.39 (2.5)

0.27 (1.8)

0.21 (1.4)

0.18 (1.3)

20 120 40 32.64 2.5 (17) 1.6 (10) 0.9 (6.1)7 0.73 (5) 0.55 (3.7) 0.41 (2.5) 0.3 (1.9) 0.26 (1.6)

240

65.28

3.5 (25)

2.4 (16)

1.5 (9.9)

1.1 (7.6)

0.8 (5.3)

0.56 (3.5)

0.45 (2.8)

0.37 (2.3)

5 480 160 130.6 6.8 (48) 4.3 (32) 2.6 (19) 2 (15) 1.3 (9) 0.9 (6.5) 0.7 (4.5) 0.55 (3.3)

3 800 266.67 217.6 25 (180) 13 (98) 7.4 (53) 4.5 (34) 2.7 (18) 1.6 (11) 1.1 (7.7) 0.91 (6)

2 1200 400 326.4 110 (740) 55 (390) 28 (180) 15 (100) 7.6 (57) 4 (32) 2.4 (16) 1.6 (12)

1 2400 800 652.8 870 (5600) 430 (2900) 220 (1400) 110 (670) 56 (370) 28 (180) 14 (100) 7.6 (52)

Table 31. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate, Low Power Mode

Filter

Word

(Dec.)

Output

Data Rate

(SPS)

Output

Data Rate

(Zero

Latency

Mode)

(SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

2047 1.17 0.39 24 (21.7) 23.8 (21.4) 23.6 (21) 23 (20.7) 22.4 (20.1) 21.9 (19.5) 21.2 (18.9) 20.5 (18.2)

480 5 1.67 23.2 (20.6) 22.9 (20.3) 22.6 (19.9) 22 (19.5) 21.4 (18.9) 20.9 (18.4) 20.2 (17.7) 19.6 (17.1)

240 10 3.33 22.7 (20.1) 22.4 (19.8) 22.1 (19.3) 21.5 (18.9) 20.9 (18.4) 20.4 (17.9) 19.8 (17.2) 19.1 (16.6)

160 15 5 22.4 (19.8) 22.1 (19.5) 21.8 (19) 21.2 (18.6) 20.6 (18) 20.1 (17.6) 19.5 (16.9) 18.8 (16.2)

80 30 10 21.9 (19.3) 21.6 (19) 21.3 (18.5) 20.7 (18.1) 20.1 (17.5) 19.6 (17) 19 (16.3) 18.3 (15.7)

48 50 16.67 21.5 (18.9) 21.2 (18.6) 20.9 (18.1) 20.3 (17.6) 19.7 (17.1) 19.2 (16.5) 18.6 (15.9) 17.9 (15.2)

40 60 20 21.4 (18.7) 21.1 (18.4) 20.8 (17.9) 20.2 (17.5) 19.6 (16.9) 19.1 (16.4) 18.5 (15.8) 17.7 (15.1)

20 120 40 20.9 (18.2) 20.6 (17.9) 20.3 (17.4) 19.7 (16.9) 19.1 (16.4) 18.6 (15.9) 18 (15.3) 17.2 (14.6)

10 120 80 20.4 (17.6) 20 (17.2) 19.7 (16.9) 19.1 (16.3) 18.6 (15.9) 18.1 (15.4) 17.4 (14.8) 16.7 (14.1)

5 480 160 19.5 (16.7) 19.2 (16.3) 18.8 (16) 18.2 (15.4) 17.9 (15.1) 17.4 (14.6) 16.8 (14.1) 16.1 (13.5)

3 800 266.67 17.6 (14.8) 17.5 (14.6) 17.4 (14.5) 17.1 (14.2) 16.8 (14.1) 16.6 (13.8) 16.1 (13.3) 15.4 (12.7)

2 1200 400 15.5 (12.7) 15.5 (12.7) 15.4 (12.7) 15.4 (12.6) 15.3 (12.4) 15.2 (12.3) 15 (12.2) 14.5 (11.6)

1 2400 800 12.5 (9.8) 12.5 (9.8) 12.5 (9.8) 12.5 (9.8 12.5 (9.7) 12.5 (9.7) 12.5 (9.6) 12.3 (9.6)

Post Filters

Table 32. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Low Power Mode

Output Data Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

16.67 1.7 (12) 0.96 (5.8) 0.65 (4) 0.45 (2.6) 0.34 (1.9) 0.25 (1.5) 0.2 (1.2) 0.16 (0.92)

20 1.7 (11) 1.1 (6.4) 0.65 (4.2) 0.46 (2.6) 0.36 (1.9) 0.26 (1.5) 0.21 (1.2) 0.17 (0.93)

25 1.8 (11) 1.1 (6.7) 0.68 (4.2) 0.52 (2.7) 0.37 (2) 0.26 (1.6) 0.22 (1.2) 0.17 (1.1)

27.27 1.9 (11) 1.1 (7.3) 0.69 (4.4) 0.54 (2.9) 0.4 (2.1) 0.27 (1.8) 0.23 (1.4) 0.18 (1.3)

Table 33. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Low Power Mode

Output Data Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

16.67

21.5 (18.8)

21.3 (18.7)

20.9 (18.2)

21.4 (17.9)

19.8 (17.3)

19.3 (16.7)

18.6 (16.1)

17.9 (15.4)

20 21.5 (18.8) 21.2 (18.6) 20.9 (18.2) 20.4 (17.9) 19.7 (17.3) 19.2 (16.7) 18.6 (16.1) 17.8 (15.4)

21.4 (18.8)

21.2 (18.5)

20.8 (18.2)

20.2 (17.8)

19.7 (17.3)

19.2 (16.6)

18.5 (15.9)

17.8 (15.1)

27.27 21.3 (18.7) 21.1 (18.4) 20.8 (18.1) 20.2 (17.7) 19.6 (17.2) 19.1 (16.4) 18.4 (15.8) 17.7 (14.9)

AD7124-4 Data Sheet

Rev. D | Page 36 of 93

Fast Settling Filter (Sinc4 + Sinc1)

Table 34. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Low Power Mode (Average by 8)

Filter Word

(Dec.)

Output Data

Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

96 2.27 0.53 (3.4) 0.34 (2.2) 0.19 (1.2) 0.16 (0.97) 0.1 (0.61) 0.082 (0.48) 0.065 (0.38) 0.058 (0.37)

30 7.27 0.89 (5.4) 0.6 (3.6) 0.36 (2.2) 0.27 (1.8) 0.21 (1.2) 0.15 (0.93) 0.12 (0.65) 0.093 (0.59)

36.36

2.1 (12)

1.4 (8.3)

0.82 (5.6)

0.64 (3.9)

0.43 (2.7)

0.33 (2.1)

0.25 (1.6)

0.21 (1.4)

5 43.64 2.2 (13) 1.4 (9.7) 0.93 (6.5) 0.71 (4.2) 0.5 (3.1) 0.35 (2.4) 0.28 (1.7) 0.23 (1.5)

109.1

3.7 (25)

2.5 (18)

1.5 (10)

1.3 (7.5)

0.86 (5.6)

0.59 (3.5)

0.47 (3.2)

0.39 (2.4)

1 218.18 8.4 (52) 5.4 (34) 3.3 (21) 2.6 (16) 1.6 (9.8) 0.97 (6.1) 0.75 (5.4) 0.63 (4.7)

Table 35. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Low Power Mode (Average by 8)

Filter Word

(Dec.)

Output Data

Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

96 2.27 23.2 (20.5) 22.8 (20.1) 22.7 (20) 21.9 (19.3) 21.5 (19) 20.9 (18.3) 20.2 (17.6) 19.4 (16.7)

30 7.27 22.4 (19.8) 22 (19.4) 21.7 (19.1) 21.1 (18.4) 20.5 (18) 20 (17.4) 19.4 (16.9) 18.7 (16)

6 36.36 21.2 (18.6) 20.8 (18.1) 20.5 (17.8) 19.9 (17.3) 19.5 (16.8) 18.9 (16.2) 18.3 (15.6) 17.5 (14.8)

5 43.64 21.1 (18.5) 20.7 (18) 20.4 (17.6) 19.8 (17.2) 19.3 (16.6) 18.8 (16) 18.1 (15.5) 17.4 (14.7)

2 109.1 20.4 (17.6) 19.9 (17.1) 19.6 (16.9) 18.9 (16.3) 18.5 (15.8) 18 (15.4) 17.3 (14.6) 16.6 (14)

1 218.18 19.2 (16.6) 18.8 (16.2) 18.5 (15.9) 17.9 (15.2) 17.6 (15) 17.3 (14.7) 16.7 (13.8) 15.9 (13)

Fast Settling Filter (Sinc3 + Sinc1)

Table 36. RMS Noise (Peak-to-Peak Noise) vs. Gain and Output Data Rate (µV), Low Power Mode (Average by 8)

Filter Word

(Dec.)

Output Data

Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

96 2.5 0.53 (3.6) 0.33 (2.1) 0.21 (1.4) 0.15 (0.93) 0.11 (0.6) 0.073 (0.44) 0.064 (0.39) 0.051 (0.29)

30 8 0.92 (5.4) 0.58 (3.4) 0.4 (2.3) 0.28 (1.6) 0.2 (1.1) 0.14 (0.79) 0.11 (0.62) 0.094 (0.51)

2.1 (13)

1.3 (8.3)

0.83 (6)

0.61 (4.1)

0.44 (3)

0.33 (2.1)

0.26 (1.6)

0.21 (1.3)

2.3 (14)

1.5 (8.6)

0.87 (6.6)

0.7 (4.4)

0.5 (3.3)

0.36 (2.3)

0.3 (1.7)

0.23 (1.4)

2 120 11 (72) 5.9 (39) 3.2 (23) 1.9 (15) 1.1 (8.5) 0.7 (4.7) 0.5 (3.3) 0.4 (2.4)

1 240 88 (530) 45 (250) 22 (140) 11 (82) 5.8 (40) 3 (22) 01.6 (11) 0.94 (6.3)

Table 37. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate (Bits), Low Power Mode (Average by 8)

Filter Word

(Dec.)

Output Data

Rate (SPS) Gain = 1 Gain = 2 Gain = 4 Gain = 8 Gain = 16 Gain = 32 Gain = 64 Gain = 128

96 2.5 23.2 (20.4) 22.8 (20.2) 22.5 (19.8) 22 (19.4) 21.4 (19) 21 (18.4) 20.2 (17.6) 19.6 (17)

30 8 22.4 (19.8) 22 (19.5) 21.6 (19) 21.1 (18.6) 20.6 (18.1) 20.1 (17.6) 19.4 (16.9) 18.7 (16.2)

6 40 21.2 (18.6) 20.9 (18.2) 20.5 (17.7) 20 (17.2) 19.4 (16.7) 18.9 (16.2) 18.2 (15.6) 17.5 (14.9)

5 48 21 (18.4) 20.7 (18.1) 20.4 (17.5) 19.8 (17) 19.3 (16.5) 18.7 (16.1) 18 (15.5) 17.4 (14.8)

2 120 18.7 (16.1) 18.7 (16) 18.6 (15.8) 18.3 (15.3) 18.1 (15.2) 17.8 (15) 17.3 (14.6) 16.6 (14)

1 240 15.8 (13.2) 15.8 (13.2) 15.8 (13.2) 15.7 (12.9) 15.7 (12.9) 15.7 (12.8) 15.6 (12.8) 15.3 (12.6)

Data Sheet AD7124-4

Rev. D | Page 37 of 93

GETTING STARTED

BIAS

SERIAL

INTERFACE

AND

CONTROL

LOGIC

INTERNAL

CLOCK

DIAGNOSTICS

CHANNEL

SEQUENCER

DIGITAL

FILTER

CLK

AIN0

X-MUX

REFERENCE

DETECT

DOUT/RDY

SCLK

IOV

VDD

TEMP

SENSOR

DIN

SYNC

NOTES

1. SIMP LI FIE D BLO CK DIAG RAM S HOWN.

PSW

OUT+OUT–

IN+

IN–

REFIN1(–)

REFIN1(+)

REF

OUT+OUT–

IN+

IN–

AIN1

AIN2

AIN3

AIN4

AIN5

REFIN2(+)

REFIN2(–)

PGA Σ-Δ

ADC

AD7124-4

REGCAPA REGCAPD AV

DGND

13197-068

Figure 65. Basic Connection Diagram

OVERVIEW

The AD7124-4 is a low power ADC that incorporates a Σ-Δ

modulator, buffer, reference, gain stage, and on-chip digital

filtering, which is intended for the measurement of wide

dynamic ranges, low frequency signals (such as those in pressure

transducers), weigh scales, and temperature measurement

applications.

Power Modes

The AD7124-4 offers three power modes: high power mode,

mid power mode, and low power mode. This allows the user

total flexibility in terms of speed, rms noise, and current

consumption.

Analog Inputs

The device can have four differential or seven pseudo differential

analog inputs. The analog inputs can be buffered or unbuffered.

The AD7124-4 uses flexible multiplexing; thus, any analog

input pin can be selected as a positive input (AINP) and any

analog input pin can be selected as a negative input (AINM).

Multiplexer

The on-chip multiplexer increases the channel count of the device.

Because the multiplexer is included on chip, any channel

changes are synchronized with the conversion process.

Reference

The device contains a 2.5 V reference, which has a drift of

10 ppm/°C maximum for the AD7124-4 B grade and for the

AD7124-4 in the TSSOP package and 15 ppm/°C maximum for

the AD7124-4 in the LFCSP package.

Reference buffers are also included on chip, which can be used

with the internal reference and externally applied references.

Programmable Gain Array (PGA)

The analog input signal can be amplified using the PGA. The

PGA allows gains of 1, 2, 4, 8, 16, 32, 64, and 128.

Burnout Currents

Two burnout currents, which can be programmed to 500 nA,

2 µA, or 4 µA, are included on chip to detect the presence of the

external sensor.

Σ-Δ ADC and Filter

The AD7124-4 contains a fourth-order Σ-Δ modulator followed

by a digital filter. The device has the following filter options:

• Sinc4

• Sinc3

• Fast filter

• Post filter

• Zero latency

Channel Sequencer

The AD7124-4 allows up to 16 configurations, or channels.

These channels can consist of analog inputs, reference inputs, or

power supplies such that diagnostic functions, such as power

supply monitoring, can be interleaved with conversions. The

sequencer automatically converts all enabled channels. When

each enabled channel is selected, the time required to generate

the conversion is equal to the settling time for the selected channel.

AD7124-4 Data Sheet

Rev. D | Page 38 of 93

Per Channel Configuration

The AD7124-4 allows up to eight different setups, each setup

consisting of a gain, output data rate, filter type, and a reference

source. Each channel is then linked to a setup.

Serial Interface

The AD7124-4 has a 3-wire or 4-wire SPI. The on-chip registers

are accessed via the serial interface.

Clock

The device has an internal 614.4 kHz clock. Use either this

clock or an external clock as the clock source for the device. The

internal clock can also be made available on a pin if a clock

source is required for external circuitry.

Temperature Sensor

The on-chip temperature sensor monitors the die temperature.

Digital Outputs

The AD7124-4 has two general-purpose digital outputs. These

can be used for driving external circuitry. For example, an

external multiplexer can be controlled by these outputs.

Calibration

Both internal calibration and system calibration are included on

chip; therefore, the user has the option of removing offset or

gain errors internal to the device only, or removing the offset or

gain errors of the complete end system.

Excitation Currents

The device contains two excitation currents which can be set

independently to 50 µA, 100 µA, 250 µA, 500 µA, 750 µA, or 1 mA.

Bias Voltage

A bias voltage generator is included on chip so that signals from

thermocouples can be biased suitably. The bias voltage is set to

AVDD/2 and can be made available on any input. It can supply

multiple channels.

Bridge Power Switch (PSW)

A low-side power switch allows the user to power down bridges

that are interfaced to the ADC.

Diagnostics

The AD7124-4 includes numerous diagnostics features such as

• Reference detection

• Overvoltage/undervoltage detection

• CRC on SPI communications

• CRC on the memory map

• SPI read/write checks

These diagnostics allow a high level of fault coverage in an

application.

POWER SUPPLIES

The AD7124-4 operates with an analog power supply voltage

from 2.7 V to 3.6 V in low or mid power mode and from 2.9 V

to 3.6 V in full power mode. The device accepts a digital power

supply from 1.65 V to 3.6 V.

The device has two independent power supply pins: AVDD and

IOVDD.

• AVDD is referred to AVSS. AVDD powers the internal analog

regulator that supplies the ADC.

• IOVDD is referred to DGND. This supply sets the interface

logic levels on the SPI interface and powers an internal

regulator for operation of the digital processing.

Single Supply Operation (AVSS = DGND)

When the AD7124-4 is powered from a single supply that is

connected to AV DD, AVSS and DGND can be shorted together

on one single ground plane. With this setup, an external level

shifting circuit is required when using truly bipolar inputs to shift

the common-mode voltage. Recommended regulators include

the ADP162, which has a low quiescent current.

Split Supply Operation (AVSS ≠ DGND)

The AD7124-4 can operate with AVSS set to a negative voltage,

allowing true bipolar inputs to be applied. This allows a truly

fully differential input signal centered around 0 V to be applied

to the AD7124-4 without the need for an external level shifting

circuit. For example, with a 3.6 V split supply, AVDD = +1.8 V

and AV SS = −1.8 V. In this use case, the AD7124-4-internally

level shifts the signals, allowing the digital output to function

between DGND (nominally 0 V) and IOVDD.

When using a split supply for AVDD and AVSS, the absolute

maximum ratings must be considered (see the Absolute

Maximum Ratings section). Ensure that IOVDD is set below

3.6 V to stay within the absolute maximum ratings for the device.

DIGITAL COMMUNICATION

The AD7124-4 has a 3-wire or 4-wire SPI interface that is

compatible with QSPI™, MICROWIRE™, and DSPs. The interface

operates in SPI Mode 3 and can be operated with CS tied low. In

SPI Mode 3, SCLK idles high, the falling edge of SCLK is the

drive edge, and the rising edge of SCLK is the sample edge. This

means that data is clocked out on the falling/drive edge and data

is clocked in on the rising/sample edge.

DRIVE E DGE SAMPLE EDGE

13197-069

Figure 66. SPI Mode 3, SCLK Edges

Data Sheet AD7124-4

Rev. D | Page 39 of 93

Accessing the ADC Register Map

The communications register controls access to the full register

map of the ADC. This register is an 8-bit, write only register.

On power-up or after a reset, the digital interface defaults to a

state where it expects a write to the communications register;

therefore, all communication begins by writing to the

communications register.

The data written to the communications register determines

which register is accessed and if the next operation is a read or

write. The register address bits (Bit 5 to Bit 0) determine the

specific register to which the read or write operation applies.

When the read or write operation to the selected register is

complete, the interface returns to its default state, where it

expects a write operation to the communications register.

In situations where interface synchronization is lost, a write

operation of at least 64 serial clock cycles with DIN high returns

the ADC to its default state by resetting the entire device, including

the register contents. Alternatively, if CS is used with the digital

interface, returning CS high resets the digital interface to its

default state and aborts any current operation.

Figure 67 and Figure 68 illustrate writing to and reading from a

Reading the ID register is the recommended method for verifying

correct communication with the device. The ID register is a read

only register and contains the value of 0x04 for the AD7124-4

and 0x06 for the AD7124-4 B grade. The communication register

and ID register details are described in Table 38 and Table 39.

DIN

SCLK

8-BI T COM M AND 8 BIT S , 16 BITS,

OR 24 BI TS OF DATA

CMD DATA

13197-070

Figure 67. Writing to a Register (8-Bit Command with Register Address

Followed by Data of 8 Bits, 16 Bits, or 24 Bits; Data Length Is Dependent on

the Register Selected)

DIN

SCLK

8-BI T CO M M AND

8 BITS, 16 BITS,

24 BITS, OR

32 BITS OUTP UT

CMD

DATA

DOUT/RDY

13197-071

Figure 68. Reading from a Register (8-Bit Command with Register Address

Followed by Data of 8 Bits, 16 Bits, 24 Bits, or 32 Bits; Data Length on DOUT Is

Dependent on the Register Selected, CRC Enabled)

Table 38. Communications Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x00 COMMS [7:0] WEN R/W RS[5:0] 0x00 W

Table 39. ID Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x05 ID [7:0] DEVICE_ID SILICON_REVISION 0x04/

0x06

AD7124-4 Data Sheet

Rev. D | Page 40 of 93

CONFIGURATION OVERVIEW

After power-on or reset, the AD7124-4 default configuration is

as follows:

• Channel: Channel 0 is enabled, AIN0 is selected as the

positive input, and AIN1 is selected as the negative input.

Setup 0 is selected.

• Setup: the input and reference buffers are disabled, the gain

is set to 1, and the external reference is selected.

• ADC control: the AD7124-4 is in low power mode,

continuous conversion mode and the internal oscillator is

enabled and selected as the master clock source.

• Diagnostics: the only diagnostic enabled is the

SPI_IGNORE_ERR function.

Note that only a few of the register setting options are shown;

this list is just an example. For full register information, see the

On-Chip Registers section.

Figure 69 shows an overview of the suggested flow for changing

the ADC configuration, divided into the following three blocks:

• Channel configuration (see Box A in Figure 69)

• Setup (see Box B in Figure 69)

• Diagnostics (see Box C in Figure 69)

• ADC control (see Box D in Figure 69)

Channel Configuration

The AD7124-4 has 16 independent analog input channels and

eight independent setups. The user can select any of the analog

input pairs on any channel, as well as any of the eight setups for

any channel, giving the user full flexibility in the channel configura-

tion. This also allows per channel configuration when using all

differential inputs because each channel can have its own

dedicated setup.

Along with the analog inputs, signals such as the power supply

or reference can also be used as inputs; they are routed to the

multiplexer internally when selected. The AD7124-4 allows the

user to define 16 configurations, or channels, to the ADC. This

allows diagnostics to be interleaved with conversions.

Channel Registers

Use the channel registers to select which input pins are either the

positive analog input or the negative analog input for that

channel. This register also contains a channel enable/disable bit

and the setup selection bits, which are used to select which of

the eight available setups to use for this channel.

When the AD7124-4 is operating with more than one channel

enabled, the channel sequencer cycles through the enabled

channels in sequential order, from Channel 0 to Channel 15. If a

channel is disabled, it is skipped by the sequencer. Details of the

channel register for Channel 0 are shown in Table 40.

DIAGNOSTICS

ENABL E CRC, SP I READ AND WRI TE CHECKS

ENABL E LDO CHE CKS , AND MO RE

SETUP

8 POSSIBLE ADC SETUPS

SELECT FILTER, OUTPUT DATA RATE, GAINAND M ORE

CHANNEL CONFIGURATION

SELECT POSI T IVEAND NEG ATIVE INPUT FOR EACHADC CHANNEL

SELECT ONE OF 8 SETUPS FO RADC CHANNEL

ADC CONTROL

SELECT ADC OP ERATI NG MODE, CLO CK S OURCE,

SELECT POW ER MODE, DATA + STATUS, AND MO RE

13197-072

Figure 69. Suggested ADC Configuration Flow

Table 40. Channel 0 Register

Reg.

Name

Bits

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Reset

0x09

CHANNEL_0 [15:8]

Enable Setup 0 AINP[4:3] 0x8001 RW

[7:0] AINP[2:0] AINM[4:0]

Data Sheet AD7124-4

Rev. D | Page 41 of 93

ADC Setups

The AD7124-4 has eight independent setups. Each setup

consists of the following four registers:

• Configuration register

• Filter register

• Offset register

• Gain register

For example, Setup 0 consists of Configuration Register 0, Filter

shows the grouping of these registers. The setup is selectable

from the channel registers detailed in the Channel Configuration

section. This allows each channel to be assigned to one of eight

separate setups. Table 41 through Table 44 show the four

registers that are associated with Setup 0. This structure is

repeated for Setup 1 to Setup 7.

Configuration Registers

The configuration registers allow the user to select the output

coding of the ADC by selecting between bipolar and unipolar. In

bipolar mode, the ADC accepts negative differential input voltages,

and the output coding is offset binary. In unipolar mode, the ADC

accepts only positive differential voltages, and the coding is straight

binary. In either case, the input voltage must be within the AVDD

and AVSS supply voltages. The user can also select the reference

source using these registers. Four options are available: an

internal 2.5 V reference, an external reference connected

between REFIN1(+) and REFIN1(−), an external reference

connected between REFIN2(+) and REFIN2(−), or AVDD to AVSS.

The PGA gain is also set; gains of 1, 2, 4, 8, 16, 32, 64, and 128

are provided. The analog input buffers and reference input

buffers for the setup can also be enabled using this register.

Filter Registers

The filter registers select which digital filter is used at the output

of the ADC modulator. The filter type and the output data rate

are selected by setting the bits in this register. For more information,

see the Digital Filter section.

CONFIGURATION

REGISTERS

FILTER

REGISTERS

OFFSET

REGISTERS

GAIN

REGISTERS

SELECT PERIPHERAL

FUNCTIONS FOR

ADC CHANNEL

SELECT DIGITAL

FILTER TYPE

AND OUTPUT DATA RAT E

ANALOG INPUT BUFFERS

REF ERE NCE BUFF E RS

BURNOUT

REF ERE NCE S OURCE

GAIN

SINC4

SINC3

SINC4 + SINC1

SINC3 + SINC1

ENHANCED 50Hz/60Hz RE JE CTI ON

GAI N CORRECTI ON

OPTIONALLY

PROGRAMMED

PER SETUP AS REQUIRED

OFFSET CORRECTION

OPTIONALLY PROGRAMMED

PER SETUP AS REQUIRED

0x19

0x1A

0x1B

0x1C

0x1D

0x1E

0x1F

0x20

0x21

0x22

0x23

0x24

0x25

0x26

0x27

0x28

0x31

0x32

0x33

0x34

0x35

0x36

0x37

0x38

0x29

0x2A

0x2B

0x2C

0x2D

0x2E

0x2F

0x30

CONFIG_3

CONFIG_5

CONFIG_6

CONFIG_7

CONFIG_4

CONFIG_0

CONFIG_2

CONFIG_1

FILTER_3

FILTER_5

FILTER_6

FILTER_7

FILTER_4

FILTER_0

FILTER_2

FILTER_1

GAIN_3

GAIN_5

GAIN_6

GAIN_7

GAIN_4

GAIN_0

GAIN_2

GAIN_1

OFFSET_3

OFFSET_5

OFFSET_6

OFFSET_7

OFFSET_4

OFFSET_0

OFFSET_2

OFFSET_1

13197-073

Figure 70. ADC Setup Register Grouping

Table 41. Configuration 0 Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x19 CONFIG_0 [15:8] 0 Bipolar Burnout REF_BUFP 0x0860 RW

[7:0] REF_BUFM AIN_BUFP AIN_BUFM

REF_SEL PGA

Table 42. Filter 0 Register

Reg.

Name

Bits

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Reset

0x28 FILTER_0 [23:9] Filter REJ60 POST_FILTER SINGLE_CYCLE 0x060180 RW

[15:8] 0 FS[10:8]

[7:0] FS[7:0]

Table 43. Offset 0 Register

Reg. Name Bits Bits[23:0] Reset RW

0x29 OFFSET_0 [23:0] Offset[23:0] 0x800000

Table 44. Gain 0 Register

Reg. Name Bits Bits[23:0] Reset RW

0x31 GAIN_0 [23:0] Gain[23:0] 0x5XXXXX

AD7124-4 Data Sheet

Rev. D | Page 42 of 93

Offset Registers

The offset registers hold the offset calibration coefficient for the

ADC. The power-on reset value of an offset register is 0x800000.

The offset registers are 24-bit read/write registers. The power-

on reset value is automatically overwritten if an internal or

system zero-scale calibration is initiated by the user or if the offset

registers are written to by the user.

Gain Registers

The gain registers are 24-bit registers that hold the gain

calibration coefficient for the ADC. The gain registers are

read/write registers. The gain is factory calibrated at a gain of 1;

thus, the default value varies from device to device. The default

value is automatically overwritten if an internal or system full-

scale calibration is initiated by the user. For more information

on calibration, see the Calibration section.

Diagnostics

The ERROR_EN register enables and disables the numerous

diagnostics on the AD7124-4. By default, the SPI_IGNORE

function is enabled, which indicates inappropriate times to

write to the ADC (for example, during power-up and during a

reset). Other diagnostics include

• SPI read and write checks, which ensure that only valid

registers are accessed

• SCLK counter, which ensures that the correct number of

SCLK pulses are used

• SPI CRC

• Memory map CRC

• LDO checks

When a diagnostic is enabled, the corresponding flag is contained

in the error register. All enabled flags are OR’ed to control the

ERR flag in the status register. Thus, if an error occurs (for example,

the SPI CRC check detects an error), the relevant flag (for example,

the SPI_CRC_ERR flag) in the error register is set. The ERR flag

in the status register is also set. This is useful when the status bits

are appended to conversions. The ERR bit indicates if an error has

occurred. The user can then read the error register for more

details on the error source.

The frequency of the on-chip oscillator can also be monitored

on the AD7124-4. The MCLK_COUNT register monitors the

master clock pulses. Table 45 to Table 47 give more detail on the

diagnostic registers. See the Diagnostics section for more detail

on the diagnostics available.

ADC Control Register

The ADC control register configures the core peripherals for use

by the AD7124-4 and the mode for the digital interface. The

power mode (full power, mid power, or low power) is selected

via this register. Also, the mode of operation is selected, for example,

continuous conversion or single conversion. The user can also

select the standby and power-down modes, as well as any of the

calibration modes. In addition, this register contains the clock

source select bits and the internal reference enable bits. The

reference select bits are contained in the setup configuration

registers (see the ADC Setups section for more information).

The digital interface operation is also selected via the ADC

control register. This register allows the user to enable the data

plus status read and continuous read mode. For more details, see

the Digital Interface section. The details of this register are

shown in Table 48.

Table 45. Error Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x06 Error [23:16] 0 LDO_CAP_ERR ADC_CAL_ERR ADC_CONV_

ERR

ADC_SAT_

ERR

0x000000 R

[15:8] AINP_OV_

ERR

AINP_UV_

ERR

AINM_OV_

ERR

AINM_UV_

ERR

REF_DET_ERR 0 DLDO_PSM_

ERR

[7:0] ALDO_PSM_

ERR

SPI_IGNORE_

ERR

SPI_SCLK_

CNT_ERR

SPI_READ_

ERR

SPI_WRITE_

ERR

SPI_CRC_ERR MM_CRC_

ERR

ROM_CRC_

ERR

Table 46. Error Enable Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x07 ERROR_EN [23:16] 0 MCLK_CNT_

LDO_CAP_

CHK_TEST_EN

LDO_CAP_CHK ADC_CAL_

ERR_EN

ADC_CONV_

ERR_EN

ADC_SAT_

ERR_EN

0x000040 RW

[15:8] AINP_OV_

ERR_EN

AINP_UV_

ERR_EN

AINM_OV_

ERR_EN

AINM_UV_

ERR_EN

REF_DET_

ERR_EN

DLDO_PSM_

TRIP_TEST_EN

DLDO_PSM_

ERR_EN

ALDO_PSM_

TRIP_TEST_EN

[7:0] ALDO_PSM_

ERR_EN

SPI_IGNORE_

ERR_EN

SPI_SCLK_

CNT_ERR_EN

SPI_READ_

ERR_EN

SPI_WRITE_

ERR_EN

SPI_CRC_

ERR_EN

MM_CRC_

ERR_EN

ROM_CRC_

ERR_EN

Table 47. MCLK Count Register

Reg.

Name

Bits

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Reset

0x08 MCLK_COUNT [7:0] MCLK_COUNT 0x00 R

Table 48. ADC Control Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x01 ADC_CONTROL [15:8] 0 DOUT_RDY_DEL CONT_ READ DATA_STATUS CS_EN REF_EN 0x0000 RW

[7:0] POWER_MORE Mode CLK_SEL

Data Sheet AD7124-4

Rev. D | Page 43 of 93

Understanding Configuration Flexibility

In Figure 71, Figure 72, and Figure 73, the registers shown in

black font are programmed for this configuration. The registers

shown in gray font are redundant.

The most straightforward implementation of the AD7124-4 is

to use differential inputs with adjacent analog inputs and run all

of them with the same setup, gain correction, and offset correction

In this case, the user selects the following differential inputs: AIN0/

AIN1, AIN2/AIN3, AIN4/AIN5, AIN6/AIN7.

Programming the gain and offset registers is optional for any

use case, as indicated by the dashed lines between the register

blocks. If an internal or system offset or full-scale calibration is

performed, the gain and offset registers for the selected channel

are automatically updated.

An alternative way to implement these four fully differential inputs

is by taking advantage of the eight available setups. Motivation for

this includes having a different speed, noise, or gain requirement on

some of the four differential inputs vs. other inputs, or there may be

a specific offset or gain correction for particular channels. Figure 72

shows how each of the differential inputs can use a separate setup,

allowing full flexibility in the configuration of each channel.

CONFIGURATION

REGISTERS

CHANNEL

REGISTERS

FILTER

REGISTERS OFFSET

REGISTERS

GAIN

REGISTERS

SELECT PERIPHERAL

FUNCTIONS FOR

ADC CHANNEL

SEL E CT ANAL OG INPUT P ARTS

ENABL E THE CHANNE L

SELECT SETUP 0

SELECT DIGITAL

FILTER TYPE

AND OUTPUT DATA RAT E

ANALOG INPUT BUFFERS

REF ERE NCE BUFF E RS

BURNOUT

REF ERE NCE S OURCE

GAIN

SINC

+ SI NC

SINC

+ SI NC

ENHANCED 50Hz/60Hz RE JE CTI ON

GAI N CORRECTI ON

OPTIONALLY

PROGRAMMED

PER SETUP AS REQUIRED

OFFSET CORRECTION

OPTIONALLY PROGRAMMED

PER SETUP AS REQUIRED

0x19

0x1A

0x1B

0x1C

0x1D

0x1E

0x1F

0x20

0x21

0x22

0x23

0x24

0x25

0x26

0x27

0x28

0x31

0x32

0x33

0x34

0x35

0x36

0x37

0x38

0x29

0x2A

0x2B

0x2C

0x2D

0x2E

0x2F

0x30

CONFIG_3

CONFIG_5

CONFIG_6

CONFIG_7

CONFIG_4

CONFIG_0

CONFIG_2

CONFIG_1

FILTER_3

FILTER_5

FILTER_6

FILTER_7

FILTER_4

FILTER_0

FILTER_2

FILTER_1

GAIN_3

GAIN_5

GAIN_6

GAIN_7

GAIN_4

GAIN_0

GAIN_2

GAIN_1

OFFSET_3

OFFSET_5

OFFSET_6

OFFSET_7

OFFSET_4

OFFSET_0

OFFSET_2

OFFSET_1

0x09

CH0

0x0A

CH1

0x0B

CH2

0x0C

CH3

0x0D

CH4

0x0E

CH5

0x0F

CH6

0x10

CH7

0x11

CH8

0x12

CH9

0x13

CH10

0x14

CH11

0x15

CH12

0x16

CH13

0x17

CH14

0x18

CH15

AIN0

AIN1

AIN2

AIN3

AIN4

AIN5

AIN6

AIN7

13197-074

Figure 71. Four Fully Differential Inputs, All Using a Single Setup (CONFIG_0, FILTER_0, GAIN_0, OFFSET_0)

CONFIGURATION

REGISTERS

FILTER

REGISTERS

OFFSET

REGISTERS

GAIN

REGISTERS

SELECT PERIPHERAL

FUNCTIONS FOR

ADC CHANNEL

SEL E CT ANAL OG INPUT P ARTS

ENABL E THE CHANNE L

SELECT SETUP

SELECT DIGITAL

FILTER TYPE

AND OUTPUT DATA RAT E

ANALOG INPUT BUFFERS

REF ERE NCE BUFF E RS

BURNOUT

REF ERE NCE S OURCE

GAIN

SINC

+ SI NC

SINC

+ SI NC

ENHANCED 50Hz/60Hz RE JE CTI ON

GAI N CORRECTI ON

OPTIONALLY

PROGRAMMED

PER SETUP AS REQUIRED

OFFSET CORRECTION

OPTIONALLY PROGRAMMED

PER SETUP AS REQUIRED

0x19

0x1A

0x1B

0x1C

0x1D

0x1E

0x1F

0x20

0x21

0x22

0x23

0x24

0x25

0x26

0x27

0x28

0x31

0x32

0x33

0x34

0x35

0x36

0x37

0x38

0x29

0x2A

0x2B

0x2C

0x2D

0x2E

0x2F

0x30

CONFIG_

CONFIG_5

CONFIG_6

CONFIG_7

CONFIG_4

CONFIG_0

CONFIG_

FILTER_3

FILTER_5

FILTER_6

FILTER_7

FILTER_4

FILTER_0

FILTER_2

FILTER_1

GAIN_3

GAIN_5

GAIN_6

GAIN_7

GAIN_4

GAIN_0

GAIN_2

GAIN_1

OFFSET_3

OFFSET_5

OFFSET_6

OFFSET_7

OFFSET_4

OFFSET_0

OFFSET_2

OFFSET_1

0x09

CH0

0x0A

CH1

0x0B

CH2

0x0C

CH3

0x0D

CH4

0x0E

CH5

0x0F

CH6

0x10

CH7

CH8

CH9

CH10

CH11

CH12

CH13

CH14

CH15

AIN0

AIN1

AIN2

AIN3

AIN4

AIN5

AIN6

AIN7

CHANNEL

REGISTERS

0x11

0x12

0x13

0x14

0x15

0x16

0x17

0x18

13197-075

Figure 72. Four Fully Differential Inputs with a Separate Setup per Channel

AD7124-4 Data Sheet

Rev. D | Page 44 of 93

Figure 73 shows an example of how the channel registers span

between the analog input pins and the setup configurations

downstream. In this random example, two differential inputs and

two single-ended inputs are required. The single-ended inputs are

the AIN0/AIN7 and AIN6/AIN7 combinations. The first differen-

tial input pair (AIN0/AIN1) uses Setup 0. The two single-ended

input pairs (AIN0/AIN7 and AIN6/AIN7) are set up as diagnostics;

therefore, they use a separate setup (Setup 1). The final differential

input (AIN2/AIN3) also uses a separate setup: Setup 2.

Given that three setups are selected for use, the CONFIG_0,

CONFIG_1, and CONFIG_2 registers are programmed as

required, and the FILTER_0, FILTER_1, and FILTER_2 registers

are also programmed as required. Optional gain and offset

correction can be employed on a per setup basis by

programming the GAIN_0, GAIN_1, and GAIN_2 registers

and the OFFSET_0, OFFSET_1, and OFFSET_2 registers.

In the example shown in Figure 73, the CHANNEL_0 to

CHANNEL_3 registers are used. Setting the MSB (the enable

bit) in each of these registers enables the four combinations via

the crosspoint multiplexer. When the AD7124-4 converts, the

sequencer transitions in ascending sequential order from

CHANNEL_0 to CHANNEL_1 to CHANNEL_2, and then on

to CHANNEL_3 before looping back to CHANNEL_0 to repeat

the sequence.

CONFIGURATION

REGISTERS FILTER

REGISTERS OFFSET

REGISTERS

GAIN

REGISTERS

SELECT PERIPHERAL

FUNCTIONS FOR

ADC CHANNEL

SEL E CT ANAL OG INPUT P ARTS

ENABL E THE CHANNE L

SELECT SETUP

SELECT DIGITAL

FILTER TYPE

AND OUTPUT DATA RAT E

ANALOG INPUT BUFFERS

REF ERE NCE BUFF E RS

BURNOUT

REF ERE NCE S OURCE

GAIN

SINC

+ SI NC

SINC

+ SI NC

ENHANCED 50Hz/60Hz RE JE CTI ON

GAI N CORRECTI ON

OPTIONALLY

PROGRAMMED

PER SETUP AS REQUIRED

OFFSET CORRECTION

OPTIONALLY PROGRAMMED

PER SETUP AS REQUIRED

0x19

0x1A

0x1B

0x1C

0x1D

0x1E

0x1F

0x20

0x21

0x22

0x23

0x24

0x25

0x26

0x27

0x28

0x31

0x32

0x33

0x34

0x35

0x36

0x37

0x38

0x29

0x2A

0x2B

0x2C

0x2D

0x2E

0x2F

0x30

CONFIG_3

CONFIG_5

CONFIG_6

CONFIG_7

CONFIG_4

CONFIG_0

CONFIG_2

CONFIG_1

FILTER_3

FILTER_5

FILTER_6

FILTER_7

FILTER_4

FILTER_0

FILTER_2

FILTER_1

GAIN_3

GAIN_5

GAIN_6

GAIN_7

GAIN_4

GAIN_0

GAIN_2

GAIN_1

OFFSET_3

OFFSET_5

OFFSET_6

OFFSET_7

OFFSET_4

OFFSET_0

OFFSET_2

OFFSET_1

0x09

CHANNEL_0

0x0A

CHANNEL_1

0x0B

CHANNEL_2

0x0C

CHANNEL_3

0x0D

CHANNEL_4

0x0E

CHANNEL_5

0x0F

CHANNEL_6

0x10

CHANNEL_7

CHANNEL_8

CHANNEL_9

CHANNEL_10

CHANNEL_11

CHANNEL_12

CHANNEL_13

CHANNEL_14

CHANNEL_15

AIN0

AIN1

AIN2

AIN3

AIN4

AIN5

AIN6

AIN7

CHANNEL

REGISTERS

0x11

0x12

0x13

0x14

0x15

0x16

0x17

0x18

13197-076

Figure 73. Mixed Differential and Single-Ended Configuration Using Multiple Shared Setups

Data Sheet AD7124-4

Rev. D | Page 45 of 93

ADC CIRCUIT INFORMATION

ANALOG INPUT CHANNEL

The AD7124-4 uses flexible multiplexing; thus, any of the analog

input pins, AIN0 to AIN7, can be selected as a positive input or

a negative input. This feature allows the user to perform diagnostics

such as checking that pins are connected. It also simplifies printed

circuit board (PCB) design. For example, the same PCB can

accommodate 2-wire, 3-wire, and 4-wire resistance temperature

detectors (RTDs).

AIN0

AIN1

AVDD

AVSS

AVDD

AVSS

AIN6

AVDD

AIN7

AVDD

AVSS

PGA T O ADC

BURNOUT

CURRENTS

13197-077

Figure 74. Analog Input Multiplexer Circuit

The channels are configured using the AINP[4:0] bits and the

AINM[4:0] bits in the channel registers (see Table 49). The device

can be configured to have four differential inputs, seven pseudo

differential inputs, or a combination of both. When using

differential inputs, use adjacent analog input pins to form the input

pair. Using adjacent pins minimizes any mismatch between the

channels.

The inputs can be buffered or unbuffered at a gain of 1 but are

automatically buffered when the gain exceeds 1. The AINP and

AINM buffers are enabled/disabled separately using the AIN_BUFP

and AIN_BUFM bits in the configuration register (see Table 50). In

buffered mode, the input channel feeds into a high impedance

input stage of the buffer amplifier. Therefore, the input can tolerate

significant source impedances and is tailored for direct connection

to external resistive type sensors such as strain gages or RTDs.

When the device is operated in unbuffered mode, the device has

a higher analog input current. Note that this unbuffered input

path provides a dynamic load to the driving source. Therefore,

resistor/capacitor (RC) combinations on the input pins can

cause gain errors, depending on the output impedance of the

source that is driving the ADC input.

The absolute input voltage in unbuffered mode (gain = 1)

includes the range between AVSS − 50 mV and AVDD + 50 mV.

The absolute input voltage range in buffered mode at a gain of 1 is

restricted to a range between AVSS + 100 mV and AVDD − 100 m V.

The common-mode voltage must not exceed these limits;

otherwise, linearity and noise performance degrade.

When the gain is greater than 1, the analog input buffers are

automatically enabled. The PGA placed in front of the input

buffers is rail-to-rail; thus, in this case, the absolute input voltage

includes the range from AVSS − 50 mV to AVDD + 5 0 m V.

Table 49. Channel Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x09 to

0x18

CHANNEL_0 to

CHANNEL_15

[15:8] Enable Setup 0 AINP[4:3] 0x8001 RW

[7:0] AINP[2:0] AINM[4:0]

Table 50. Configuration Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x19 to

0x20

CONFIG_0 to

CONFIG_7

[15:8] 0 Bipolar Burnout REF_BUFP 0x0860 RW

[7:0] REF_BUFM AIN_BUFP AIN_BUFM REF_SEL PGA

AD7124-4 Data Sheet

Rev. D | Page 46 of 93

EXTERNAL IMPEDANCE WHEN USING A GAIN OF 1

When a gain of 1 is used, the PGA is powered down, reducing

the current consumption. A capacitive network is included at

the PGA output for electromagnetic compatibility (EMC)

purposes. For a gain of 1, this capacitive network is connected

directly to the analog input pins because the PGA is bypassed

(see Figure 77). A precharge buffer is included on the AD7124-4

B grade to charge this capacitive network quickly when switching

channels. The precharge buffer ensures that the analog input is

settled when sampled by the ADC.

When using the AD7124-4, which does not include the

precharge buffer, using large external loads at a gain of 1 in

multiplexed applications affects the settling time. Large external

loads affect the initial error on the gain of 1 channel. The

external RC antialiasing filter determines the recovery time of

the channel. When the gain of 1 channel is selected, the

maximum possible error (initial error) is

VERROR = CPAR × (VIN_PREV_CH × GAIN_PREV_CH − VIN) ÷

(CPAR + CFILT) (1)

where:

CPAR is the internal capacitance (63 pF due to 10 pF/25 pF

network plus 3 pF of parasitic capacitance).

CFILT is the external filter capacitance on the gain of 1 channel.

VIN_PREV_CH is the input voltage of the previous selected channel.

GAIN_PREV_CH is the gain of the previous selected channel.

If a fast output data rate is selected, the error in the conversion

has a magnitude comparable with Equation 1. For slower output

data rates, the error is reduced as the ADC takes more time to

process the analog input, which allows the front end to settle.

The settling time is dependent on the time constant of the

external antialiasing filter.

Figure 75 and Figure 76 show the error for different RC filter

combinations on the gain of 1 channel when a resistor

attenuator is connected to the analog input and the ADC is

multiplexed.

6000

ERROR (µV )

5000

4000

3000

2000

1000

–1000

110 100 1000 10000

SETTLED OUTPUT DATA RATE ( sps)

RC: 100Ω RESISTOR

1µ F CAPICI T OR

0. 0 1µF CAP ACITOR TO G ND

RC: 100Ω RESISTOR

0.1µF CAPICITOR

0.01µF CAPICITOR TO GND

RC: 100Ω RESISTOR

0.01µF CAPICITOR

0.01µF CAPICITOR TO GND

13048-175

Figure 75. Error vs. Settled Output Data Rate

(100 kΩ Resistors in Attenuator Circuit)

RC: 1kΩ RESISTOR

0.01µF CAPICITOR

0. 0 1µF CAP ACITOR TO G ND

RC: 1kΩ RESISTOR

0.01µF CAPICITOR

NO CAPICITOR TO G ND

7000

6000

ERROR (µV )

5000

4000

3000

2000

1000

–1000

110 100 1000 10000

SETTLED OUTPUT DATA RATE ( sps)

13048-176

Figure 76. Error vs. Settled Output Data Rate (47 kΩ Resistors in Attenuator Circuit)

Figure 75 and Figure 76 show that, at low output data rates, the

ADC allows sufficient time for the gain of 1 channel to settle for

any external load resistance and RC filter values. At intermediate

output data rates, reducing the values of the external RC compo-

nents reduces the time constant of the external filter so that the

analog input can settle within the allowed time. For high output

data rates, the settling time allowed by the ADC is short; therefore,

a large capacitor from AINP to AINM minimizes the error.

For gains > 1, the PGA is used, which isolates the internal

capacitive network from the analog input pins. Therefore, for

gains > 1, there are no restrictions on the external circuitry.

BUFFER

PGA2

MUX

ADC

13048-078

10pF

AVSS BUFFER

AD7124-8

AVSS

25pF

AINP

AINM

AVSS

RC ANTI-ALIASING

FILTER

AVSS

ATTENUATOR

CIRCUIT

Figure 77. Input Schematic

Data Sheet AD7124-4

Rev. D | Page 47 of 93

PROGRAMMABLE GAIN ARRAY (PGA)

When the gain stage is enabled, the output from the multiplexer

is applied to the input of the PGA. The presence of the PGA means

that signals of small amplitude can be gained within the

AD7124-4 and still maintain excellent noise performance.

BUF

ANALOG

BUFFERS

PGA2PGA1

X-MUX

24-BIT

Σ-∆ADC

13197-080

Figure 78. PGA

The AD7124-4 can be programmed to have a gain of 1, 2, 4, 8,

16, 32, 64, or 128 by using the PGA bits in the configuration

gain of 1, both stages are bypassed. For gains of 2 to 8, a single

stage is used, whereas for gains greater than 8, both stages are used.

The analog input range is ±VREF/gain. Therefore, with an external

2.5 V reference, the unipolar ranges are from 0 mV to 19.53 mV

to 0 V to 2.5 V, and the bipolar ranges are from ±19.53 mV to

±2.5 V. For high reference values, for example, VREF = AVDD, the

analog input range must be limited. Consult the Specifications

section for more details on these limits.

REFERENCE

The AD7124-4 has an embedded 2.5 V reference. The embedded

reference is a low noise, low drift reference with 15 ppm/°C drift

maximum for the AD7124-4 in the LFCSP package and

10 ppm/°C drift maximum for the TSSOP package and the

AD7124-4 B grade. Including the reference on the AD7124-4

reduces the number of external components needed in appli-

cations such as thermocouples, leading to a reduced PCB size.

BAND GAP

REF

24-BIT

Σ-∆ADC

REFIN1(+)

REFOUT

REFIN1(–)

REFIN2(+)

REFIN2(–)

REFERENCE

BUFFERS

13197-081

Figure 79. Reference Connections

This reference can be used to supply the ADC (by setting the

REF_EN bit in the ADC_CONTROL register to 1) or an

external reference can be applied. For external references, the

ADC has a fully differential input capability for the channel. In

addition, the user can select one of two external reference options

(REFIN1 or REFIN2). The reference source for the AD7124-4 is

selected using the REF_SEL bits in the configuration register

(see Table 50). When the internal reference is selected, it is

internally connected to the modulator. It can also be made

available on the REFOUT pin. A 0.1 μF decoupling capacitor is

required on REFOUT when the internal reference is active.

The common-mode range for the differential reference inputs is

from AVSS − 50 mV to AVDD + 50 mV when the reference

buffers are disabled. The reference inputs can also be buffered

on-chip. The buffers require 100 mV of headroom. The reference

voltage of REFIN (REFINx(+) − REFINx(−)) is 2.5 V nominal,

but the AD7124-4 is functional with reference voltages from

0.5 V to AVDD.

In applications where the excitation (voltage or current) for the

transducer on the analog input also drives the reference voltage

for the devices, the effect of the low frequency noise in the excita-

tion source is removed, because the application is ratiometric. If

the AD7124-4 is used in nonratiometric applications, use a low

noise reference.

The recommended 2.5 V reference voltage sources for the

AD7124-4 include the ADR4525, which is a low noise, low power

reference. Note that the reference input provides a high impedance,

dynamic load when unbuffered. Because the input impedance of

each reference input is dynamic, resistor/capacitor combinations

on these inputs can cause dc gain errors if the reference inputs

are unbuffered, depending on the output impedance of the

source driving the reference inputs.

Reference voltage sources typically have low output impedances

and are, therefore, tolerant to having decoupling capacitors on

REFINx(+) without introducing gain errors in the system. Deriving

the reference input voltage across an external resistor means that

the reference input sees a significant external source impedance.

In this situation, using the reference buffers is required.

REFINx(+)

1µF 4.7µF

ADR4525

2.5V REF

REFINx(–)

0.1µF4.7µF

13197-082

Figure 80. ADR4525 to AD7124-4 Connections

BIPOLAR/UNIPOLAR CONFIGURATION

The analog input to the AD7124-4 can accept either unipolar or

bipolar input voltage ranges, which allows the user to tune the

ADC input range to the sensor output range. When a split

power supply is used, the device accepts truly bipolar inputs.

When a single power supply is used, a bipolar input range does

not imply that the device can tolerate negative voltages with

respect to system AVSS. Unipolar and bipolar signals on the

AINP input are referenced to the voltage on the AINM input.

For example, if AINM is 1.5 V and the ADC is configured for

unipolar mode with a gain of 1, the input voltage range on the

AINP input is 1.5 V to 3 V when VREF = AVDD = 3 V. If the ADC

is configured for bipolar mode, the analog input range on the

AINP input is 0 V to AVDD. The bipolar/unipolar option is chosen

by programming the bipolar bit in the configuration register.

AD7124-4 Data Sheet

Rev. D | Page 48 of 93

DATA OUTPUT CODING

When the ADC is configured for unipolar operation, the output

code is natural (straight) binary with a zero differential input

voltage resulting in a code of 00 … 00, a midscale voltage resulting

in a code of 100 … 000, and a full-scale input voltage resulting

in a code of 111 … 111. The output code for any analog input

voltage can be represented as

Code = (2N × AIN × Gain)/VREF

When the ADC is configured for bipolar operation, the output

code is offset binary with a negative full-scale voltage resulting

in a code of 000 … 000, a zero differential input voltage resulting

in a code of 100 … 000, and a positive full-scale input voltage

resulting in a code of 111 … 111. The output code for any

analog input voltage can be represented as

Code = 2N − 1 × ((AIN × Gain/VREF) + 1)

where:

N = 24.

AIN is the analog input voltage.

Gain is the gain setting (1 to 128).

EXCITATION CURRENTS

The AD7124-4 also contains two matched, software configurable,

constant current sources that can be programmed to equal 50 µA,

100 µA, 250 µA, 500 µA, 750 µA, or 1 mA. These current sources

can be used to excite external resistive bridges or RTD sensors.

Both current sources source currents from AVDD and can be

directed to any of the analog input pins (see Figure 81).

The pins on which the currents are made available are programmed

using the IOUT1_CH and IOUT0_CH bits in the IO_CONTROL_1

individually programmable using the IOUT1 and IOUT0 bits in

the IO_CONTROL_1 register. In addition, both currents can be

output to the same analog input pin.

Note that the on-chip reference does not need to be enabled

when using the excitation currents.

AIN0

AIN1

VBIAS

IOUT1IOUT0

AIN7

VBIAS

PGA T O ADC

BURNOUT

CURRENTS

13197-083

Figure 81. Excitation Current and Bias Voltage Connections

Table 51. Input/Output Control 1 Register

Reg. Name Bits Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x03 IO_

CONTROL_

[23:16] GPIO_DAT2 GPIO_DAT1 0 0 GPIO_CTRL2 GPIO_CTRL1 0 0 0x000000 RW

[15:8] PDSW 0 IOUT1 IOUT0

[7:0] IOUT1_CH IOUT0_CH

Data Sheet AD7124-4

Rev. D | Page 49 of 93

BRIDGE POWER-DOWN SWITCH

In bridge applications such as strain gages and load cells, the

bridge itself consumes the majority of the current in the system.

For example, a 350 Ω load cell requires 8.6 mA of current when

excited with a 3 V supply. To minimize the current consumption of

the system, the bridge can be disconnected (when it is not being

used) using the bridge power-down switch. The switch can with-

stand 30 mA of continuous current, and it has an on resistance

of 10 Ω maximum. The PDSW bit in the IO_CONTROL_1

LOGIC OUTPUTS

The AD7124-4 has two general-purpose digital outputs: P1 and

P2. These are enabled using the GPIO_CTRL bits in the IO_

CONTROL_1 register (see Table 51). The pins can be pulled high

or low using the GPIO_DATx bits in the register; that is, the

value at the pin is determined by the setting of the GPIO_DATx

bits. The logic levels for these pins are determined by AVDD

rather than by IOVDD. When the IO_CONTROL_1 register is

read, the GPIO_DATx bits reflect the actual value at the pins;

this is useful for short-circuit detection.

These pins can be used to drive external circuitry, for example,

an external multiplexer. If an external multiplexer is used to

increase the channel count, the multiplexer logic pins can be

controlled via the AD7124-4 general-purpose output pins. The

general-purpose output pins can be used to select the active

multiplexer pin. Because the operation of the multiplexer is

independent of the AD7124-4, reset the modulator and filter

using the SYNC pin or by writing to the mode or configuration

BIAS VOLTAGE GENERATOR

A bias voltage generator is included on the AD7124-4 (see

Figure 81). It biases the negative terminal of the selected input

channel to (AVDD − AVSS)/2. This function is useful in thermocou-

ple applications, as the voltage generated by the thermocouple

must be biased around some dc voltage if the ADC operates from a

single power supply. The bias voltage generator is controlled using

the VBIASx bits in the IO_CONTROL_2 register (see Table 53).

The power-up time of the bias voltage generator is dependent

on the load capacitance. Consult the Specifications section for

more details.

CLOCK

The AD7124-4 includes an internal 614.4 kHz clock on chip. This

internal clock has a tolerance of ±5%. Use either the internal

clock or an external clock as the clock source to the AD7124-4.

The clock source is selected using the CLK_SEL bits in the

ADC_CONTROL register (see Table 54).

The internal clock can also be made available at the CLK pin.

This is useful when several ADCs are used in an application and

the devices must be synchronized. The internal clock from one

device can be used as the clock source for all ADCs in the system.

Using a common clock, the devices can be synchronized by

applying a common reset to all devices, or the SYNC pin can be

pulsed.

POWER MODES

The AD7124-4 has three power modes: full power mode, mid

power mode, and low power mode. The mode is selected using

the POWER_MODE bits in the ADC_CONTROL register. The

power mode affects the power consumption of the device as

well as changing the master clock frequency. A 614.4 kHz clock

is used by the device. However, this clock is internally divided,

the division factor being dependent on the power mode. Thus,

the range of output data rates and performance is affected by

the power mode.

Table 52. Power Modes

Power

Mode

Master Clock

(kHz)

Output Data

Rate1 (SPS) Current

Full Power 614.4 9.37 to 19,200 See the

Specifications

section

Mid Power 153.6 2.34 to 4800

Low Power 76.8 1.17 to 2400

1 Unsettled, using a sinc3/sinc4 filter.

STANDBY AND POWER-DOWN MODES

In standby mode, most blocks are powered down. The LDOs

remain active so that registers maintain their contents. If

enabled, the reference, the internal oscillator, the P1 and P2

digital outputs, the bias voltage generator, and the low-side

power switch remain active. On the AD7124-4 B grade, the

excitation currents, if enabled, also remain active in standby

mode. The excitation currents are disabled on the AD7124-4.

These blocks can be disabled, if required, by setting the

corresponding bits appropriately. The reference detection and

LDO capacitor detection functions are disabled in standby mode.

Table 53. Input/Output Control 2 Register

Reg. Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x04 IO_CONTROL_2 VBIAS7 VBIAS6 0 0 VBIAS5 VBIAS4 0 0 0x0000 RW

0 0 VBIAS3 VBIAS2 VBIAS1 VBIAS0

Table 54. ADC Control Register

Reg. Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x01 ADC_CONTROL 0 DOUT_RDY_DEL CONT_READ DATA_STATUS CS_EN REF_EN 0x0000 RW

POWER_MODE Mode CLK_SEL

AD7124-4 Data Sheet

Rev. D | Page 50 of 93

Other diagnostics remain active if enabled when the ADC is in

standby mode. Diagnostics can be enabled or disabled while in

standby mode. However, any diagnostics that require the master

clock (reference detect, undervoltage/overvoltage detection,

LDO trip tests, memory map CRC, and MCLK counter) must

be enabled when the ADC is in continuous conversion mode or

idle mode; these diagnostics do not function if enabled in

standby mode.

The standby current is typically 15 µA when the LDOs only are

enabled. If functions such as the bias voltage generator remain

active in standby mode, the current increases by 36 µA typically.

If the internal oscillator remains active in standby mode, the

current increases by 22 µA typically. When exiting standby

mode, the AD7124-4 requires 130 MCLK cycles to power up

and settle. The internal oscillator, if disabled in standby mode,

requires an additional 40 µs to power up and settle. If an external

master clock is being used, ensure that it is active before issuing

the command to exit standby mode. Do not write to the ADC_

CONTROL register again until the ADC has powered up and

settled.

In power-down mode, all blocks are powered down, including

the LDOs. All registers lose their contents, and the digital outputs

P1 and P2 are placed in tristate. To prevent accidental entry to

power-down mode, the ADC must first be placed into standby

mode. If an external master clock is being used, keep it active

until the device is placed in power-down mode. Exiting power-

down mode requires 64 SCLK cycles with CS = 0 and DIN = 1,

that is, a serial interface reset. The AD7124-4 requires 2 ms

typically to power up and settle. The POR_FLAG in the status

up/settling period. After this time, the user can access the on-chip

registers. The power-down current is 2 µA typically.

DIGITAL INTERFACE

The programmable functions of the AD7124-4 are controlled

using a set of on-chip registers. Data is written to these registers

via the serial interface. Read access to the on-chip registers is

also provided by this interface. All communications with the

device must start with a write to the communications register.

After power-on or reset, the device expects a write to its

communications register. The data written to this register

determines whether the next operation is a read operation or a

write operation, and determines to which register this read or

write operation occurs. Therefore, write access to any of the

other registers on the devices begins with a write operation to

the communications register, followed by a write to the selected

continuous read mode is selected) starts with a write to the

communications register, followed by a read operation from the

selected register.

The serial interface of the AD7124-4 consists of four signals: CS,

DIN, SCLK, and DOUT/RDY. The DIN line transfers data into

the on-chip registers, whereas DOUT/RDY accesses data from

the on-chip registers. SCLK is the serial clock input for the

device, and all data transfers (either on DIN or DOUT/RDY)

occur with respect to the SCLK signal. The DOUT/RDY pin

also operates as a data ready signal; the line goes low when a

new data-word is available in the output register. It is reset high

when a read operation from the data register is complete. It also

goes high before the data register updates to indicate when not

to read from the device, to ensure that a data read is not attempted

while the register is being updated. CS is used to select a device.

It can decode the AD7124-4 in systems where several components

are connected to the serial bus.

Figure 3 and Figure 4 show timing diagrams for interfacing to the

AD7124-4 with CS decoding the devices. Figure 3 shows the

timing for a read operation from the output shift register of the

AD7124-4. Figure 4 shows the timing for a write operation to

the input shift register. A delay is required between consecutive

SPI communications. Figure 5 shows the delay required between

SPI read/write operations. It is possible to read the same word

from the data register several times, even though the DOUT/RDY

line returns high after the first read operation. However, care

must be taken to ensure that the read operations are complete

before the next output update occurs. In continuous read mode,

the data register can be read only once.

The serial interface can operate in 3-wire mode by tying CS low.

In this case, the SCLK, DIN, and DOUT/RDY lines communicate

with the AD7124-4. The end of the conversion can be monitored

using the RDY bit in the status register. This scheme is suitable

for interfacing to microcontrollers. If CS is required as a decoding

signal, it can be generated from a port pin. For microcontroller

interfaces, it is recommended that SCLK idle high between data

transfers.

The AD7124-4 can be operated with CS being used as a frame

synchronization signal. This scheme is useful for DSP interfaces.

In this case, the first bit (MSB) is effectively clocked out by CS,

because CS normally occurs after the falling edge of SCLK in

DSPs. SCLK can continue to run between data transfers,

provided the timing numbers are obeyed.

CS must be used to frame read and write operations and the

CS_EN bit in the ADC_CONTROL register must be set when

the diagnostics SPI_READ_ERR, SPI_WRITE_ERR, or

SPI_SCLK_CNT_ERR are enabled.

The serial interface can be reset by writing a series of 1s on the

DIN input. See the Reset section for more details. Reset returns

the interface to the state in which it is expecting a write to the

communications register

The AD7124-4 can be configured to continuously convert or

perform a single conversion (see Figure 82 through Figure 84).

Single Conversion Mode

In single conversion mode, the AD7124-4 performs a single

conversion and is placed in standby mode after the conversion

is complete. If a master clock is present (external master clock

or the internal oscillator is enabled), DOUT/RDY goes low to

Data Sheet AD7124-4

Rev. D | Page 51 of 93

indicate the completion of a conversion. When the data-word is

read from the data register, DOUT/RDY goes high. The data

DOUT/RDY is high. Do not read the ADC_CONTROL register

close to the completion of a conversion because the mode bits are

being updated by the ADC to indicate that the ADC is in standby

mode.

If several channels are enabled, the ADC automatically sequences

through the enabled channels and performs a conversion on

each channel. When a conversion is started, DOUT/RDY goes

high and remains high until a valid conversion is available and CS

is low. As soon as the conversion is available, DOUT/RDY goes low.

The ADC then selects the next channel and begins a conversion.

The user can read the present conversion while the next conversion

is being performed. As soon as the next conversion is complete,

the data register is updated; therefore, the user has a limited

period in which to read the conversion. When the ADC has

performed a single conversion on each of the selected channels,

it returns to standby mode.

If the DATA_STATUS bit in the ADC_CONTROL register is set

to 1, the contents of the status register are output along with the

conversion each time that the data read is performed. The four

LSBs of the status register indicate the channel to which the

conversion corresponds.

Continuous Conversion Mode

Continuous conversion is the default power-up mode. The

AD7124-4 converts continuously, and the RDY bit in the status

the DOUT/RDY line also goes low when a conversion is complete.

To read a conversion, write to the communications register,

indicating that the next operation is a read of the data register.

When the data-word is read from the data register, DOUT/RDY

goes high. The user can read this register additional times, if

required. However, the user must ensure that the data register is

not being accessed at the completion of the next conversion;

otherwise the new conversion word is lost.

When several channels are enabled, the ADC automatically

sequences through the enabled channels, performing one

conversion on each channel. When all channels are converted,

the sequence starts again with the first channel. The channels

are converted in order from lowest enabled channel to highest

enabled channel. The data register is updated as soon as each

conversion is available. The DOUT/RDY pin pulses low each

time a conversion is available. The user can then read the

conversion while the ADC converts the next enabled channel.

If the DATA_STATUS bit in the ADC_CONTROL register is set

to 1, the contents of the status register, along with the conversion

data, are output each time the data register is read. The status

DIN

SCLK

DOUT/RDY

0x01 0x0004 0x42

DATA

13197-087

Figure 82. Single Conversion Configuration

DIN

SCLK

DOUT/RDY

0x42 0x42

DATADATA

13197-088

Figure 83. Continuous Conversion Configuration

AD7124-4 Data Sheet

Rev. D | Page 52 of 93

DIN

SCLK

DOUT/RDY

DATADATA

0x01 0x0800

13197-089

Figure 84. Continuous Read Configuration

Continuous Read Mode

In continuous read mode, it is not required to write to the

communications register before reading ADC data; apply the

required number of SCLKs after DOUT/RDY goes low to

indicate the end of a conversion. When the conversion is read,

DOUT/RDY returns high until the next conversion is available.

In this mode, the data can be read only once. Ensure that the data-

word is read before the next conversion is complete. If the user

has not read the conversion before the completion of the next

conversion, or if insufficient serial clocks are applied to the

AD7124-4 to read the word, the serial output register is reset

when the next conversion is complete, and the new conversion

is placed in the output serial register. The ADC must be configured

for continuous conversion mode to use continuous read mode.

To enable continuous read mode, set the CONT_READ bit in

the ADC_CONTROL register. When this bit is set, the only serial

interface operations possible are reads from the data register. To

exit continuous read mode, write a read data command (0x42)

while the DOUT/RDY pin is low. Alternatively, apply a software

reset, that is, 64 SCLKs with CS = 0 and DIN = 1. This resets the

ADC and all register contents. These are the only commands

that the interface recognizes after it is placed in continuous read

mode. DIN must be held low in continuous read mode until an

instruction is to be written to the device.

If multiple ADC channels are enabled, each channel is output in

turn, with the status bits being appended to the data if DATA_

STATUS is set in the ADC_CONTROL register. The status

DATA_STATUS

The contents of the status register can be appended to each

conversion on the AD7124-4. This is a useful function if several

channels are enabled. Each time a conversion is output, the

contents of the status register are appended. The four LSBs of

the status register indicate to which channel the conversion

corresponds. In addition, the user can determine if any errors

are being flagged via the ERROR_FLAG bit. To append the status

the ADC_CONTROL register is set to 1.

SERIAL INTERFACE RESET (DOUT_RDY_DEL AND

CS_EN BITS)

The instant at which the DOUT/RDY pin changes from being a

DOUT pin to a RDY pin is programmable on the AD7124-4. By

default, the D OUT/RDY pin changes functionality after a period

of time following the last SCLK rising edge, the SCLK edge on

which the LSB is read by the processor. This time is 10 ns

minimum by default and, by setting the DOUT_RDY_DEL bit

in the ADC_ CONTROL register to 1, can be extended to 110

ns minimum.

By setting the CS_EN bit in the ADC_CONTROL register to 1, the

DOUT/RDY pin continues to output the LSB of the register being

read until CS is taken high. This configuration is useful if the

CS signal is used to frame all read operations. If CS is not used

to frame all read operations, set CS_EN to 0 so that DOUT/RDY

changes functionality following the last SCLK edge in the read

operation.

CS_EN must be set to 1 and the CS signal must be used to frame all

read and write operations when the SPI_READ_ERR,

SPI_WRITE_ERR, and SPI_SCLK_CNT_ERR diagnostic

functions are enabled.

The serial interface is always reset on the CS rising edge, that is,

the interface is reset to a known state whereby it awaits a write

to the communications register. Therefore, if a read or write

operation is performed by performing multiple 8- bit data

transfers, CS must be held low until the all bits are transferred.

RESET

The circuitry and serial interface of the AD7124-4 can be reset

by writing 64 consecutive 1s to the device. This resets the logic,

the digital filter, and the analog modulator, and all on-chip

registers are reset to their default values. A reset is automatically

performed on power-up. A reset requires a time of 90 MCLK

cycles. The POR_FLAG bit in the status register is set to 1 when

the reset is initiated and then is set to 0 when the reset is

complete. A reset is useful if the serial interface becomes

asynchronous due to noise on the SCLK line.

Data Sheet AD7124-4

Rev. D | Page 53 of 93

CALIBRATION

The AD7124-4 provides four calibration modes that can be

used to eliminate the offset and gain errors on a per setup basis:

• Internal zero-scale calibration mode

• Internal full-scale calibration mode

• System zero-scale calibration mode

• System full-scale calibration mode

Only one channel can be active during calibration. After each

conversion, the ADC conversion result is scaled using the ADC

calibration registers before being written to the data register.

The default value of the offset register is 0x800000, and the nominal

value of the gain register is 0x5XXXXX. The calibration range

of the ADC gain is from 0.4 × VREF/gain to 1.05 × VREF/gain.

The following equations show the calculations that are used in

each calibration mode. In unipolar mode, the ideal

relationship—that is, not taking into account the ADC gain

error and offset error—is as follows:

0x400000

)0x800000(2

75.0











−−×

Gain

Offset

Data

REF

In bipolar mode, the ideal relationship—that is, not taking into

account the ADC gain error and offset error—is as follows:

0x800000

0x400000

0x800000)(2

0.75











−−×

Gain

Offset

Data

REF

To start a calibration, write the relevant value to the mode bits

in the ADC_CONTROL register. The DOUT/RDY pin and the

RDY bit in the status register go high when the calibration

initiates. When the calibration is complete, the contents of the

corresponding offset or gain register are updated, the RDY bit

in the status register is reset, the DOUT/RDY pin returns low (if

CS is low), and the AD7124-4 reverts to idle mode.

During an internal offset calibration, the selected positive

analog input pin is disconnected, and it is connected internally

to the selected negative analog input pin. For this reason, it is

necessary to ensure that the voltage on the selected negative

analog input pin does not exceed the allowed limits and is free

from excessive noise and interference.

To perform an internal full-scale calibration, a full-scale input

voltage is automatically connected to the selected analog input

for this calibration. A full-scale calibration is recommended

each time the gain of a channel is changed to minimize the full-

scale error. When performing internal calibrations, the internal

full-scale calibration must be performed before the internal

zero-scale calibration. Therefore, write the value 0x800000 to

the offset register before performing the internal full-scale

calibration, which ensures that the offset register is at its default

value. The AD7124-4 is factory calibrated at a gain of 1, and the

resulting gain coefficient is the default gain coefficient on the

device. The device does not support further internal full-scale

calibrations at a gain of 1.

System calibrations expect the system zero-scale (offset) and

system full-scale (gain) voltages to be applied to the ADC pins

before initiating the calibration modes. As a result, errors

external to the ADC are removed. The system zero-scale

calibration must be performed before the system full-scale

calibration.

From an operational point of view, treat a calibration like

another ADC conversion. Set the system software to monitor

the RDY bit in the status register or the DOUT/RDY pin to

determine the end of a calibration via a polling sequence or an

interrupt-driven routine.

An internal/system offset calibration and system full-scale

calibration requires a time equal to the settling time of the

selected filter to be completed. The internal full-scale

calibration requires a time of four settling periods (gain > 1).

A calibration can be performed at any output data rate. Using

lower output data rates results in better calibration accuracy and

is accurate for all output data rates. A new calibration is required

for a given channel if the reference source or the gain for that

channel is changed.

Offset and system full-scale calibrations can be performed in

any power mode. Internal full-scale calibrations can be performed

in the low power or mid power modes only. Thus, when using

full power mode, the user must select mid or low power mode

to perform the internal full-scale calibration. However, an internal

full-scale calibration performed in low or mid power mode is

valid in full power mode, if the same gain is used.

The offset error is typically ±15 µV for gains of 1 to 8 and

±200/gain µV for higher output data rates. An internal or system

offset calibration reduces the offset error to the order of the

noise. The gain error is factory calibrated at ambient temperature

and at a gain of 1. Following this calibration, the gain error is

±0.0025% maximum. Therefore, internal full-scale calibrations

at a gain of 1 are not supported on the AD7124-4. For other

gains, the gain error is −0.3%. An internal full-scale calibration at

ambient temperature reduces the gain error to ±0.016%

maximum for gains of 2 to 8 and ±0.025% typically for higher

gains. A system full-scale calibration reduces the gain error to the

order of the noise.

The AD7124-4 provides the user with access to the on-chip

calibration registers, allowing the microprocessor to read the

calibration coefficients of the device and to write its own

calibration coefficients from prestored values in the EEPROM.

A read or write of the offset and gain registers can be performed

at any time except during an internal or self-calibration. The

values in the calibration registers are 24 bits wide. The span and

offset of the device can also be manipulated using the registers.

AD7124-4 Data Sheet

Rev. D | Page 54 of 93

SPAN AND OFFSET LIMITS

Whenever a system calibration mode is used, the amount of

offset and span which can be accommodated is limited. The

overriding requirement in determining the amount of offset

and gain which can be accommodated by the device is the

requirement that the positive full-scale calibration limit is

≤1.05 × VREF/gain. This allows the input range to go 5% above

the nominal range. The built-in headroom in the AD7124-4

analog modulator ensures that the device still operates correctly

with a positive full-scale voltage which is 5% beyond the nominal.

The range of input span in both the unipolar and bipolar modes

has a minimum value of 0.8 × VREF/gain and a maximum value

of 2.1 × VREF/gain. However, the span, which is the difference

between the bottom of the AD7124-4 input range and the top of

its input range, must account for the limitation on the positive

full-scale voltage. The amount of offset that can be accommodated

depends on whether the unipolar or bipolar mode is being used.

The offset must account for the limitation on the positive full-

scale voltage. In unipolar mode, there is considerable flexibility in

handling negative (with respect to AINM) offsets. In both

unipolar and bipolar modes, the range of positive offsets that

can be handled by the device depends on the selected span.

Therefore, in determining the limits for system zero-scale and

full-scale calibrations, the user must ensure that the offset range

plus the span range does exceed 1.05 × VREF/gain. This is best

illustrated by looking at a few examples.

If the device is used in unipolar mode with a required span of

0.8 × VREF/gain, the offset range that the system calibration can

handle is from −1.05 × VREF/gain to +0.25 × VREF/gain. If the

device is used in unipolar mode with a required span of

VREF/gain, the offset range that the system calibration can

handle is from −1.05 × VREF/gain to +0.05 × VREF/gain. Similarly,

if the device is used in unipolar mode and required to remove

an offset of 0.2× VREF/gain, the span range that the system

calibration can handle is 0.85 × VREF/gain.

If the device is used in bipolar mode with a required span of

±0.4 × VREF/gain, then the offset range which the system

calibration can handle is from −0.65 × VREF/gain to +0.65 ×

VREF/gain. If the device is used in bipolar mode with a required

span of ±VREF/gain, the offset range the system calibration can

handle is from −0.05 × VREF/gain to +0.05 × VREF/gain. Similarly,

if the device is used in bipolar mode and required to remove an

offset of ±0.2 × VREF/gain, the span range that the system

calibration can handle is ±0.85 × VREF/gain.

SYSTEM SYNCHRONIZATION

The SYNC input allows the user to reset the modulator and the

digital filter without affecting any of the setup conditions on the

device. This allows the user to start gathering samples of the

analog input from a known point in time, that is, the rising edge

of SYNC. Take SYNC low for at least four master clock cycles to

implement the synchronization function.

If multiple AD7124-4 devices are operated from a common

master clock, they can be synchronized so that their data

registers are updated simultaneously. A falling edge on the

SYNC pin resets the digital filter and the analog modulator and

places the AD7124-4 into a consistent, known state. While the

SYNC pin is low, the AD7124-4 is maintained in this state. On

the SYNC rising edge, the modulator and filter exit this reset

state and, on the next clock edge, the device starts to gather

input samples again. In a system using multiple AD7124-4

devices, a common signal to their SYNC pins synchronizes their

operation. This is normally performed after each AD7124-4 has

performed its own calibration or has calibration coefficients

loaded into its calibration registers. The conversions from the

AD7124-4 devices are then synchronized.

The device exits reset on the master clock falling edge following

the SYNC low to high transition. Therefore, when multiple

devices are being synchronized, pull the SYNC pin high on the

master clock rising edge to ensure that all devices begin

sampling on the master clock falling edge. If the SYNC pin is

not taken high in sufficient time, it is possible to have a

difference of one master clock cycle between the devices; that is,

the instant at which conversions are available differs from

device to device by a maximum of one master clock cycle.

The SYNC pin can also be used as a start conversion command.

In this mode, the rising edge of SYNC starts conversion and the

falling edge of RDY indicates when the conversion is complete.

The settling time of the filter must be allowed for each data

the sinc4 filter and zero latency is disabled, the settling time

equals 4/fADC where fADC is the output data rate when

continuously converting on a single channel.

Data Sheet AD7124-4

Rev. D | Page 55 of 93

DIGITAL FILTER

Table 55. Filter Registers

Reg. Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x21 to

0x28

FILTER_0 to

FILTER_7

Filter REJ60 POST_FILTER SINGLE_CYCLE 0x060180 RW

0 FS[10:8]

FS[7:0]

The AD7124-4 offers a great deal of flexibility in the digital

filter. The device has several filter options. The option selected

affects the output data rate, settling time, and 50 Hz and 60 Hz

rejection. The following sections describe each filter type,

indicating the available output data rates for each filter option.

The filter response along with the settling time and 50 Hz and

60 Hz rejection is also discussed.

The filter bits in the filter register select between the sinc type filter.

SINC4 FILTER

When the AD7124-4 is powered up, the sinc4 filter is selected by

default. This filter gives excellent noise performance over the

complete range of output data rates. It also gives the best 50 Hz/

60 Hz rejection, but it has a long settling time. In Figure 85, the

blocks shown in gray are unused.

SINC

/SINC

FILTER

MODULATOR

AVERAGING

BLOCK

POST

FILTER

13197-091

Figure 85. Sinc4 Filter

Sinc4 Output Data Rate/Settling Time

The output data rate (the rate at which conversions are available

on a single channel when the ADC is continuously converting)

is equal to

fADC = fCLK/(32 × FS[10:0])

where:

fADC is the output data rate.

fCLK is the master clock frequency (614.4 kHz in full power mode,

153.6 kHz in mid power mode, and 76.8 kHz in low power mode).

FS[10:0] is the decimal equivalent of the FS[10:0] bits in the

filter register. FS[10:0] can have a value from 1 to 2047.

The output data rate can be programmed from

• 9.38 SPS to 19,200 SPS for full power mode

• 2.35 SPS to 4800 SPS for mid power mode

• 1.17 SPS to 2400 SPS for low power mode

The settling time for the sinc4 filter is equal to

tSETTLE = (4 × 32 × FS[10:0] + Dead time)/fCLK

where Dead time = 61 when FS[10:0] = 1 and 95 when FS[10:0] > 1.

When a channel change occurs, the modulator and filter are

reset. The settling time is allowed to generate the first

conversion after the channel change. Subsequent conversions on

this channel occur at 1/fADC.

CONVERSIONS

CHANNEL A

CHANNELCHANNEL B

CH A CH A

CH A CH B CH B

CH B

fADC

DT/

fCLK

NOTES

1. DT = DE AD TIM E

13197-092

Figure 86. Sinc4 Channel Change

When conversions are performed on a single channel and a

step change occurs, the ADC does not detect the change in the

analog input. Therefore, it continues to output conversions

at the programmed output data rate. However, it is at least four

conversions later before the output data accurately reflects the

analog input. If the step change occurs while the ADC is

processing a conversion, then the ADC takes five conversions

after the step change to generate a fully settled result.

ANALOG

INPUT

ADC

OUTPUT

FULLY

SETTLED

fADC

13197-093

Figure 87. Asynchronous Step Change in the Analog Input

The 3 dB frequency for the sinc4 filter is equal to

f3dB = 0.23 × fADC

Table 56 gives some examples of the relationship between the

values in the FS[10:0] bits and the corresponding output data

rate and settling time.

Table 56. Examples of Output Data Rates and the

Corresponding Settling Times for the Sinc4 Filter

Power Mode FS[10:0]

Output Data

Rate (SPS)

Settling

Time (ms)

Full Power (fCLK =

614.4 kHz)

1920 10 400.15

384 50 80.15

320 60 66.82

Mid Power (fCLK =

153.6 kHz)

480 10 400.61

96 50 80.61

80 60 67.28

Low Power (fCLK =

76.8 kHz)

240 10 401.22

48 50 81.22

40 60 67.89

AD7124-4 Data Sheet

Rev. D | Page 56 of 93

Sinc4 Zero Latency

Zero latency is enabled by setting the SINGLE_CYCLE bit in

the filter register to 1. With zero latency, the conversion time

when continuously converting on a single channel approximately

equals the settling time. The benefit of this mode is that a similar

period of time elapses between all conversions irrespective of

whether the conversions occur on one channel or whether several

channels are used. When the analog input is continuously sampled

on a single channel, the output data rate equals

fADC = fCLK/(4 × 32 × FS[10:0])

where:

fADC is the output data rate.

fCLK is the master clock frequency.

FS[10:0] is the decimal equivalent of the FS[10:0] bits in the

setup filter register.

When the user selects another channel, there is an extra delay in

the first conversion of

Dead time/fCLK

where Dead time = 61 when FS[10:0] = 1 and 95 when FS[10:0] > 1.

At low output data rates, this extra delay has little impact on the

value of the settling time. However, at high output data rates, the

delay must be considered. Table 57 summarizes the output data

rate when continuously converting on a single channel and the

settling time when switching between channels for a sample of

FS[10:0] values.

When switching between channels, the AD7124-4 allows the

complete settling time to generate the first conversion after the

channel change. Therefore, the ADC automatically operates in

zero latency mode when several channels are enabled—setting

the SINGLE_CYCLE bit has no benefits.

Table 57. Examples of Output Data Rates and the

Corresponding Settling Times for the Sinc4 Filter (Zero Latency)

Power Mode FS[10:0]

Output Data

Rate (SPS)

Settling

Time (ms)

Full Power (fCLK =

614.4 kHz)

1920 2.5 400.15

384 12.5 80.15

320 15 66.82

Mid Power (fCLK =

153.6 kHz)

480 2.5 400.61

96 12.5 80.61

80 15 67.28

Low Power (fCLK =

76.8 kHz)

240 2.5 401.22

48 12.5 81.22

40 15 67.89

When the analog input is constant or a channel change occurs,

valid conversions are available at a near constant output data

rate. When conversions are being performed on a single

channel and a step change occurs on the analog input, the ADC

continues to output fully settled conversions if the step change is

synchronized with the conversion process. If the step change is

asynchronous, one conversion is output from the ADC, which is

not completely settled (see Figure 88).

ANALOG

INPUT

ADC

OUTPUT

FULLY

SETTLED

ADC

13197-094

Figure 88. Sinc4 Zero Latency Operation

Sequencer

The description in the Sinc4 Filter section is valid when

manually switching channels, for example, writing to the device

to change channels. When multiple channels are enabled, the

on-chip sequencer is automatically used; the device

automatically sequences between all enabled channels. In this

case, the first conversion takes the complete settling time as

listed in Table 56. For all subsequent conversions, the time

needed for each conversion is the settling time also, but the

dead time is reduced to 30.

Sinc4 50 Hz and 60 Hz Rejection

Figure 89 shows the frequency response of the sinc4 filter when

the output data rate is programmed to 50 SPS and zero latency

is disabled. For the same configuration but with zero latency

enabled, the filter response remains the same but the output data

rate is 12.5 SPS. The sinc4 filter provides 50 Hz (±1 Hz) rejection in

excess of 120 dB minimum, assuming a stable master clock.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

025 50 75 100 125 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-095

Figure 89. Sinc4 Filter Response (50 SPS Output Data Rate, Zero Latency

Disabled or 12.5 SPS Output Data Rate, Zero Latency Enabled)

Data Sheet AD7124-4

Rev. D | Page 57 of 93

Figure 90 shows the frequency response of the sinc4 filter when

the output data rate is programmed to 60 SPS and zero latency

is disabled. For the same configuration but with zero latency

enabled, the filter response remains the same but the output

data rate is 15 SPS. The sinc4 filter provides 60 Hz (±1 Hz)

rejection of 120 dB minimum, assuming a stable master clock.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

030 60 90 120 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-096

Figure 90. Sinc4 Filter Response (60 SPS Output Data Rate, Zero Latency

Disabled or 15 SPS Output Data Rate, Zero Latency Enabled)

When the output data rate is 10 SPS with zero latency disabled

or 2.5 SPS with zero latency enabled, simultaneous 50 Hz and

60 Hz rejection is obtained. The sinc4 filter provides 50 Hz

(±1 Hz) and 60 Hz (±1 Hz) rejection of 120 dB minimum,

assuming a stable master clock.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

030 60 90 120 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-097

Figure 91. Sinc4 Filter Response (10 SPS Output Data Rate, Zero Latency

Disabled or 2.5 SPS Output Data Rate, Zero Latency Enabled)

Simultaneous 50 Hz/60 Hz rejection can also be achieved using

the REJ60 bit in the filter register. When the sinc filter places a

notch a 50 Hz, the REJ60 bit places a first order notch at 60 Hz.

The output data rate is 50 SPS when zero latency is disabled and

12.5 SPS when zero latency is enabled. Figure 92 shows the

frequency response of the sinc4 filter. The filter provides 50 Hz ±

1 Hz and 60 Hz ± 1 Hz rejection of 82 dB minimum, assuming

a stable master clock.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

025 50 75 100 125 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-098

Figure 92. Sinc4 Filter Response (50 SPS Output Data Rate, Zero Latency

Disabled or 12.5 SPS Output Data Rate, Zero Latency Enabled, REJ60 = 1)

SINC3 FILTER

A sinc3 filter can be used instead of the sinc4 filter. The filter is

selected using the filter bits in the filter register. This filter has

good noise performance, moderate settling time, and moderate

50 Hz and 60 Hz (±1 Hz) rejection. In Figure 93, the blocks

shown in gray are unused.

SINC

/SINC

FILTER

MODULATOR

AVERAGING

BLOCK

POST

FILTER

13197-099

Figure 93. Sinc3 Filter

Sinc3 Output Data Rate and Settling Time

The output data rate (the rate at which conversions are available on

a single channel when the ADC is continuously converting) equals

fADC = fCLK/(32 × FS[10:0])

where:

fADC is the output data rate.

fCLK is the master clock frequency (614.4 kHz in full power mode,

153.6 kHz in mid power mode and 76.8 kHz in low power mode).

FS[10:0] is the decimal equivalent of the FS[10:0] bits in the

filter register. FS[10:0] can have a value from 1 to 2047.

The output data rate can be programmed from

• 9.38 SPS to 19,200 SPS for full power mode

• 2.35 SPS to 4800 SPS for mid power mode

• 1.17 SPS to 2400 SPS for low power mode

The settling time for the sinc3 filter is equal to

tSETTLE = (3 × 32 × FS[10:0] + Dead time)/fCLK

where Dead time = 61 when FS[10:0] = 1 and 95 FS[10:0] >1.

The 3 dB frequency is equal to

f3dB = 0.262 × fADC

AD7124-4 Data Sheet

Rev. D | Page 58 of 93

Table 58 gives some examples of FS[10:0] settings and the

corresponding output data rates and settling times.

Table 58. Examples of Output Data Rates and the

Corresponding Settling Times for the Sinc3 Filter

Power Mode FS[10:0]

Output Data

Rate (SPS)

Settling

Time (ms)

Full Power (fCLK =

614.4 kHz)

1920 10 300.15

384 50 60.15

320 60 50.15

Mid Power (fCLK =

153.6 kHz)

480 10 300.61

96 50 60.61

80 60 50.61

Low Power (fCLK =

76.8 kHz)

240 10 301.22

48 50 61.22

40 60 51.22

When a channel change occurs, the modulator and filter are

reset. The complete settling time is allowed to generate the first

conversion after the channel change (see Figure 94). Subsequent

conversions on this channel are available at 1/fADC.

CONVERSIONS

CHANNEL A

CHANNELCHANNEL B

CH ACH A CH BCH B

1/f

ADC

13197-100

DT/f

CLK

NOTES

1. DT = DEAD TI M E

Figure 94. Sinc3 Channel Change

When conversions are performed on a single channel and a step

change occurs, the ADC does not detect the change in the

analog input. Therefore, it continues to output conversions at

the programmed output data rate. However, it is at least three

conversions later before the output data accurately reflects the

analog input. If the step change occurs while the ADC is processing

a conversion, the ADC takes four conversions after the step

change to generate a fully settled result.

fADC

ANALOG

INPUT

ADC

OUTPUT

FULLY

SETTLED

13197-101

Figure 95. Asynchronous Step Change in the Analog Input

Sinc3 Zero Latency

Zero latency is enabled by setting the SINGLE_CYCLE bit in

the filter register to 1. With zero latency, the conversion time

when continuously converting on a single channel approximately

equals the settling time. The benefit of this mode is that a similar

period of time elapses between all conversions irrespective of

whether the conversions occur on one channel or whether

several channels are used.

When the analog input is continuously sampled on a single

channel, the output data rate equals

fADC = fCLK/(3 × 32 × FS[10:0])

where:

fADC is the output data rate.

fCLK is the master clock frequency.

FS[10:0] is the decimal equivalent of the FS[10:0] bits in the

filter register.

When switching channels, there is an extra delay in the first

conversion of

Dead time/fCLK

where Dead time = 61 when FS[10:0] = 1 or 95 when FS > 1.

At low output data rates, this extra delay has little impact on the

value of the settling time. However, at high output data rates, the

delay must be considered. Table 59 summarizes the output data rate

when continuously converting on a single channel and the settling

time when switching between channels for a sample of FS[10:0].

When the user selects another channel, the AD7124-4 allows

the complete settling time to generate the first conversion after

the channel change. Therefore, the ADC automatically operates

in zero latency mode when several channels are enabled—setting

the SINGLE_CYCLE bit has no benefits.

When the analog input is constant or a channel change occurs,

valid conversions are available at a near constant output data

rate. When conversions are being performed on a single channel

and a step change occurs on the analog input, the ADC continues

to output fully settled conversions if the step change is synchronized

with the conversion process. If the step change is asynchronous,

one conversion is output from the ADC that is not completely

settled (see Figure 96).

ANALOG

INPUT

ADC

OUTPUT

FULLY

SETTLED

ADC

13197-102

Figure 96. Sinc3 Zero Latency Operation

Table 59. Examples of Output Data Rates and the

Corresponding Settling Times for the Sinc3 Filter (Zero Latency)

Power Mode FS[10:0]

Output Data

Rate (SPS)

Settling

Time (ms)

Full Power (fCLK =

614.4 kHz)

1920 3.33 300.15

384 16.67 60.15

320 20 50.15

Mid Power (fCLK =

153.6 kHz)

480 3.33 300.61

96 16.67 60.61

80 20 50.61

Low Power (fCLK =

76.8 kHz)

240 3.33 301.22

48 16.67 61.22

40 20 51.22

Data Sheet AD7124-4

Rev. D | Page 59 of 93

Sequencer

The description in the Sinc3 Filter section is valid when manually

switching channels, for example, writing to the device to change

channels. When multiple channels are enabled, the on-chip

sequencer is automatically used; the device automatically

sequences between all enabled channels. In this case, the first

conversion takes the complete settling time as listed in Table 58.

For all subsequent conversions, the time needed for each conversion

is also the settling time, but the dead time is reduced to 30.

Sinc3 50 Hz and 60 Hz Rejection

Figure 97 shows the frequency response of the sinc3 filter when

the output data rate is programmed to 50 SPS and zero latency

is disabled. For the same configuration but with zero latency

enabled, the filter response remains the same but the output

data rate is 16.67 SPS. The sinc3 filter gives 50 Hz ± 1 Hz

rejection of 95 dB minimum for a stable master clock.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

025 50 75 100 125 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-103

Figure 97. Sinc3 Filter Response (50 SPS Output Data Rate, Zero Latency

Disabled or 16.67 SPS Output Data Rate, Zero Latency Enabled)

Figure 98 shows the frequency response of the sinc3 filter when

the output data rate is programmed to 60 SPS and zero latency

is disabled. For the same configuration but with zero latency

enabled, the filter response remains the same but the output

data rate is 20 SPS. The sinc3 filter has rejection of 95 dB

minimum at 60 Hz ± 1 Hz, assuming a stable master clock.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

030 60 90 120 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-104

Figure 98. Sinc3 Filter Response (60 SPS Output Data Rate, Zero Latency

Disabled or 20 SPS Output Data Rate, Zero Latency Enabled)

When the output data rate is 10 SPS with zero latency disabled

or 3.33 SPS with zero latency enabled, simultaneous 50 Hz and

60 Hz rejection is obtained. The sinc3 filter has rejection of 100 dB

minimum at 50 Hz ± 1 Hz and 60 Hz ± 1 Hz (see Figure 99).

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

030 60 90 120 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-105

Figure 99. Sinc3 Filter Response (10 SPS Output Data Rate, Zero Latency

Disabled or 3.33 SPS Output Data Rate, Zero Latency Enabled)

Simultaneous 50 Hz and 60 Hz rejection can also be achieved

using the REJ60 bit in the filter register. When the sinc filter

places a notch a 50 Hz, the REJ60 bit places a first order notch

at 60 Hz. The output data rate is 50 SPS when zero latency is

disabled and 16.67 SPS when zero latency is enabled. Figure 100

shows the frequency response of the sinc3 filter with this configura-

tion. Assuming a stable clock, the rejection at 50 Hz and 60 Hz

(±1 Hz) is in excess of 67 dB minimum.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

025 50 75 100 125 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-106

Figure 100. Sinc3 Filter Response (50 SPS Output Data Rate, Zero Latency

Disabled or 16.67 SPS Output Data Rate, Zero Latency Enabled, REJ60 = 1)

FAST SETTLING MODE (SINC4 + SINC1 FILTER)

In fast settling mode, the settling time is close to the inverse of

the first filter notch; therefore, the user can achieve 50 Hz and/or

60 Hz rejection at an output data rate close to 1/50 Hz or 1/60 Hz.

The settling time is approximately equal to 1/output data rate.

Therefore, the conversion time is near constant when converting

on a single channel or when converting on several channels.

AD7124-4 Data Sheet

Rev. D | Page 60 of 93

Enable the fast settling mode using the filter bits in the filter

sinc4 filter. The sinc1 filter averages by 16 in the full power and

mid power modes and averages by 8 in the low power mode. In

Figure 101, the blocks shown in gray are unused.

SINC

/SINC

FILTER

MODULATOR

AVERAGING

BLOCK

POST

FILTER

13197-107

Figure 101. Fast Settling Mode, Sinc4 + Sinc1 Filter

Output Data Rate and Settling Time, Sinc4 + Sinc1 Filter

When continuously converting on a single channel, the output

data rate is

fADC = fCLK/((4 + Avg − 1) × 32 × FS[10:0])

where:

fADC is the output data rate.

fCLK is the master clock frequency (614.4 kHz in full power mode,

153.6 kHz in mid power mode, and 76.8 kHz in low power mode).

Avg is 16 for the full or mid power mode and 8 for low power

mode.

FS[10:0] is the decimal equivalent of the FS[10:0] bits in the

filter register. FS[10:0] can have a value from 1 to 2047.

When another channel is selected by the user, there is an extra

delay in the first conversion. The settling time is equal to

tSETTLE = ((4 + Avg − 1) × 32 × FS[10:0] + Dead time)/fCLK

where Dead time = 95.

The 3 dB frequency is equal to

f3dB = 0.44 × fADC

Table 60 lists sample FS[10:0] settings and the corresponding

output data rates and settling times.

Table 60. Examples of Output Data Rates and the

Corresponding Settling Times (Fast Settling Mode, Sinc4 + Sinc1)

Power Mode FS[10:0]

First

Notch

(Hz)

Output

Data Rate

(SPS)

Settling

Time

(ms)

Full Power (fCLK =

614.4 kHz,

Average by 16)

120 10 8.42 118.9

24 50 42.11 23.9

20 60 50.53 19.94

Mid Power (fCLK =

153.6 kHz,

Average by 16)

30 10 8.42 119.36

6 50 42.11 24.36

5 60 50.53 20.4

Low Power (fCLK =

76.8 kHz,

Average by 8)

30 10 7.27 138.72

6 50 36.36 28.72

5 60 43.64 24.14

When the analog input is constant or a channel change occurs,

valid conversions are available at a near constant output data rate.

CONVERSIONS

CHANNEL A

CHANNELCHANNEL B

CH A CH A CH A CH ACH A CH B CH BCH B CH B

ADC

13197-108

DT/

CLK

NOTES

1. DT = DE AD TIM E

Figure 102. Fast Settling, Sinc4 + Sinc1 Filter

When the device is converting on a single channel and a step

change occurs on the analog input, the ADC does not detect the

change and continues to output conversions. If the step change

is synchronized with the conversion, only fully settled results

are output from the ADC. However, if the step change is

asynchronous to the conversion process, there is one intermediate

result, which is not completely settled (see Figure 103).

ANALOG

INPUT

ADC

OUTPUT

VALID

fADC

13197-109

Figure 103. Step Change on the Analog Input, Sinc4 + Sinc1 Filter

Sequencer

The description in the Fast Settling Mode (Sinc4 + Sinc1 Filter)

section is valid when manually switching channels, for example,

writing to the device to change channels. When multiple

channels are enabled, the on-chip sequencer is automatically

used; the device automatically sequences between all enabled

channels. In this case, the first conversion takes the complete

settling time as listed in Table 60. For all subsequent

conversions, the time needed for each conversion is also the

settling time, but the dead time is reduced to 30.

50 Hz and 60 Hz Rejection, Sinc4 + Sinc1 Filter

Figure 104 shows the frequency response when FS[10:0] is set to

24 in the full power mode or 6 in the mid power mode or low

power mode. Table 60 lists the corresponding output data rate.

The sinc filter places the first notch at

fNOTCH = fCLK/(32 × FS[10:0])

The sinc1 filter places notches at fNOTCH/Avg (Avg equaling 16 for

the full power mode and mid power mode and equaling 8 for

the low power mode). Notches are also placed at multiples of

this frequency; therefore, when FS[10:0] is set to 6 in the full

power mode or mid power mode, a notch is placed at 800 Hz

due to the sinc filter and notches are placed at 50 Hz and

multiples of 50 Hz due to the averaging. In low power mode, a

notch is placed at 400 Hz due to the sinc filter and notches are

placed at 50 Hz and multiples of 50 Hz due to the averaging.

The notch at 50 Hz is a first-order notch; therefore, the notch is

not wide. This means that the rejection at 50 Hz exactly is good,

assuming a stable master clock. However, in a band of 50 Hz ± 1 Hz,

the rejection degrades significantly. The rejection at 50 Hz ± 0.5 Hz

is 40 dB minimum, assuming a stable clock; therefore, a good

master clock source is recommended when using fast settling mode.

Data Sheet AD7124-4

Rev. D | Page 61 of 93

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

0 306090120150

FRE QUE NCY ( Hz)

FILTER GAIN (dB)

13197-110

Figure 104. 50 Hz Rejection

Figure 105 shows the filter response when FS[10:0] is set to 20

in full power mode or 5 in the mid power and low power modes. In

this case, a notch is placed at 60 Hz and multiples of 60 Hz. The

rejection at 60 Hz ± 0.5 Hz is equal to 40 dB minimum.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

0 306090120150

FRE QUENCY (H z)

FILTER GAIN (dB)

13197-111

Figure 105. 60 Hz Rejection

Simultaneous 50 Hz/60 Hz rejection is achieved when FS[10:0]

is set to 384 in full power mode or 30 in the mid power and low

power modes. Notches are placed at 10 Hz and multiples of 10 Hz,

thereby giving simultaneous 50 Hz and 60 Hz rejection. The

rejection at 50 Hz ± 0.5 Hz and 60 Hz ± 0.5 Hz is 44 dB typically.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

FREQUENCY (Hz)

FILTER GAIN (dB)

0306090120150

13197-112

Figure 106. Simultaneous 50 Hz and 60 Hz Rejection

FAST SETTLING MODE (SINC3 + SINC1 FILTER)

In fast settling mode, the settling time is close to the inverse of

the first filter notch; therefore, the user can achieve 50 Hz and/or

60 Hz rejection at an output data rate close to 1/50 Hz or 1/60 Hz.

The settling time is approximately equal to 1/output data rate.

Therefore, the conversion time is near constant when converting

on a single channel or when converting on several channels.

Enable the fast settling mode using the filter bits in the filter

sinc3 filter. The sinc1 filter averages by 16 in the full power and

mid power modes and averages by 8 in low power mode. In

Figure 107, the blocks shown in gray are unused.

SINC

/SINC

FILTER

MODULATOR

AVERAGING

BLOCK

POST

FILTER

13197-113

Figure 107. Fast Settling Mode, Sinc3 + Sinc1 Filter

Output Data Rate and Settling Time, Sinc3 + Sinc1 Filter

When continuously converting on a single channel, the output

data rate is

fADC = fCLK/((3 + Avg − 1) × 32 × FS[10:0])

where:

fADC is the output data rate.

fCLK is the master clock frequency (614.4 kHz in full power mode,

153.6 kHz in mid power mode, and 76.8 kHz in low power mode).

Avg is 16 in full or mid power mode and 8 in low power mode.

FS[10:0] is the decimal equivalent of the FS[10:0] bits in the

filter register. FS[10:0] can have a value from 1 to 2047.

When another channel is selected by the user, there is an extra

delay in the first conversion. The settling time is equal to

tSETTLE = ((3 + Avg − 1) × 32 × FS[10:0] + Dead time)/ fCLK

where Dead time = 95.

The 3 dB frequency is equal to

f3dB = 0.44 × fNOTCH

Table 61 lists some sample FS[10:0] settings and the

corresponding output data rates and settling times.

Table 61. Examples of Output Data Rates and the

Corresponding Settling Times (Fast Settling Mode, Sinc3 + Sinc1)

Power Mode FS[10:0]

First Notch

(Hz)

Output Data

Rate (SPS)

Settling

Time (ms)

Full Power (fCLK =

614.4 kHz,

Average by 16)

120 10 8.89 112.65

24 50 44.44 22.65

20 60 53.33 18.9

Mid Power (fCLK =

153.6 kHz,

Average by 16)

30 10 8.89 113.11

6 50 44.44 23.11

5 60 53.33 19.36

Low Power (fCLK =

76.8 kHz,

Average by 8)

30 10 8 126.22

6 50 40 26.22

5 60 48 22.06

AD7124-4 Data Sheet

Rev. D | Page 62 of 93

When the analog input is constant or a channel change occurs,

valid conversions are available at a near constant output data rate.

CONVERSIONS

CHANNEL A

CHANNEL CHANNEL B

CH A CH A CH A CH A

CH A CH B CH BCH B CH B

fADC

13197-114

DT/

fCLK

NOTES

1. DT = DE AD TIM E

Figure 108. Fast Settling, Sinc3 + Sinc1 Filter

When the device is converting on a single channel and a step

change occurs on the analog input, the ADC does not detect

the change and continues to output conversions. When the step

change is synchronized with the conversion, only fully settled

results are output from the ADC. However, if the step change is

asynchronous to the conversion process, one intermediate result

is not completely settled (see Figure 109).

ANALOG

INPUT

ADC

OUTPUT

VALID

ADC

13197-115

Figure 109. Step Change on the Analog Input, Sinc3 + Sinc1 Filter

Sequencer

The description in the Fast Settling Mode (Sinc3 + Sinc1 Filter)

section is valid when manually switching channels, for example,

writing to the device to change channels. When multiple

channels are enabled, the on-chip sequencer is automatically

used; the device automatically sequences between all enabled

channels. In this case, the first conversion takes the complete

settling time as listed in Table 61. For all subsequent conversions,

the time needed for each conversion is also the settling time,

but the dead time is reduced to 30.

50 Hz and 60 Hz Rejection, Sinc3 + Sinc1 Filter

Figure 110 shows the frequency response when FS[10:0] is set to

24 in the full power mode or 6 in the mid power mode or low

power mode. Table 61 lists the corresponding output data rate.

The sinc filter places the first notch at

fNOTCH = fCLK/(32 × FS[10:0])

The averaging block places notches at fNOTCH/Avg (Avg equaling

16 for the full power mode and mid power mode and equaling 8

for the low power mode). Notches are also placed at multiples of

this frequency; therefore, when FS[10:0] is set to 6 in full power

mode or mid power mode, a notch is placed at 800 Hz due to

the sinc filter and notches are placed at 50 Hz and multiples of

50 Hz due to the averaging. In low power mode, a notch is

placed at 400 Hz due to the sinc filter and notches are placed at

50 Hz and multiples of 50 Hz due to the averaging.

The notch at 50 Hz is a first-order notch; therefore, the notch is not

wide. This means that the rejection at 50 Hz exactly is good, assum-

ing a stable master clock. However, in a band of 50 Hz ± 1 Hz, the

rejection degrades significantly. The rejection at 50 Hz ± 0.5 Hz is

40 dB minimum, assuming a stable clock; therefore, a good master

clock source is recommended when using fast settling mode.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

030 60 90 120 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-116

Figure 110. 50 Hz Rejection

Figure 111 shows the filter response when FS[10:0] is set to 20

in full power mode or 5 in the mid power and low power modes. In

this case, a notch is placed at 60 Hz and multiples of 60 Hz. The

rejection at 60 Hz ± 0.5 Hz is equal to 40 dB minimum.

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

030 60 90 120 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-117

Figure 111. 60 Hz Rejection

Simultaneous 50 Hz/60 Hz rejection is achieved when FS[10:0]

is set to 384 in full power mode or 30 in the mid power and low

power modes. Notches are placed at 10 Hz and multiples of 10 Hz,

thereby giving simultaneous 50 Hz and 60 Hz rejection. The

rejection at 50 Hz ± 0.5 Hz and 60 Hz ± 0.5 Hz is 42 dB typically.

Data Sheet AD7124-4

Rev. D | Page 63 of 93

–120

–110

–100

–90

–80

–70

–60

–50

–40

–30

–20

–10

030 60 90 120 150

FREQUENCY (Hz)

FILTE R GAIN ( dB)

13197-118

Figure 112. Simultaneous 50 Hz and 60 Hz Rejection

POST FILTERS

The post filters provide rejection of 50 Hz and 60 Hz

simultaneously and allow the user to trade off settling time and

rejection. These filters can operate up to 27.27 SPS or can reject

up to 90 dB of 50 Hz ± 1 Hz and 60 Hz ± 1 Hz interference. These

filters are realized by post filtering the output of the sinc3 filter.

The filter bits must be set to all 1s to enable the post filter. The post

filter option to use is selected using the POST_FILTER bits in the

filter register. In Figure 113, the blocks shown in gray are unused.

SINC

/SINC

FILTER

MODULATOR

AVERAGING

BLOCK

POST

FILTER

13197-119

Figure 113. Post Filters

Table 62 shows the output data rates with the accompanying

settling times and the rejection.

When continuously converting on a single channel, the first

conversion requires a time of tSETTLE. Subsequent conversions

occur at 1/fADC. When multiple channels are enabled (either

manually or using the sequencer), the settling time is required

to generate a valid conversion on each enabled channel.

Table 62. AD7124-4 Post Filters: Output Data Rate, Settling Time (tSETTLE), and Rejection

Output Data

Rate (SPS)

f3dB

(Hz)

tSETTLE, Full Power

Mode (ms)

tSETTLE, Mid Power

Mode (ms)

tSETTLE, Low Power

Mode (ms)

Simultaneous Rejection of 50 Hz ± 1 Hz

and 60 Hz ± 1 Hz (dB)1

27.27 17.28 38.498 38.998 39.662 47

25 15.12 41.831 42.331 42.995 62

13.38

51.831

52.331

52.995

16.67 12.66 61.831 62.331 62.995 92

1 Stable master clock used.

AD7124-4 Data Sheet

Rev. D | Page 64 of 93

–100 0600

FILTER GAIN (dB)

FRE Q UE NCY ( Hz )

–90

–80

–70

–60

–50

–40

–30

–20

–10

100 200 300 400 500

13197-120

Figure 114. DC to 600 Hz, 27.27 SPS Output Data Rate, 36.67 ms Settling Time

–10040 70

FILTER GAIN (dB)

FRE Q UE NCY ( Hz )

–90

–80

–70

–60

–50

–40

–30

–20

–10

45 50 55 60 65

13197-121

Figure 115. Zoom in 40 Hz to 70 Hz, 27.27 SPS Output Data Rate, 36.67 ms

Settling Time

–10040

FILTER GAIN (dB)

FRE Q UE NCY ( Hz )

–90

–80

–70

–60

–50

–40

–30

–20

–10

600

100 200 300 400 500

13197-122

Figure 116. DC to 600 Hz, 25 SPS Output Data Rate, 40 ms Settling Time

–10040 70

FILTER GAIN (dB)

FRE Q UE NCY ( Hz )

–90

–80

–70

–60

–50

–40

–30

–20

–10

45 50 55 60 65

13197-123

Figure 117. Zoom in 40 Hz to 70 Hz, 25 SPS Output Data Rate, 40 ms Settling Time

–100 0600

FILTER GAIN (dB)

FRE Q UE NCY ( Hz )

–90

–80

–70

–60

–50

–40

–30

–20

–10

100 200 300 400 500

13197-124

Figure 118. DC to 600 Hz, 20 SPS Output Data Rate, 50 ms Settling Time

–10040 70

FILTER GAIN (dB)

FRE Q UE NCY ( Hz )

–90

–80

–70

–60

–50

–40

–30

–20

–10

45 50 55 60 65

13197-125

Figure 119. Zoom in 40 Hz to 70 Hz, 20 SPS Output Data Rate, 50 ms Settling Time

Data Sheet AD7124-4

Rev. D | Page 65 of 93

–100 0600

FILTER GAIN (dB)

FRE Q UE NCY ( Hz )

–90

–80

–70

–60

–50

–40

–30

–20

–10

100 200 300 400 500

13197-126

Figure 120. DC to 600 Hz, 16.667 SPS Output Data Rate, 60 ms Settling Time

–10040 70

FILTER GAIN (dB)

FRE Q UE NCY ( Hz )

–90

–80

–70

–60

–50

–40

–30

–20

–10

45 50 55 60 65

13197-127

Figure 121. Zoom in 40 Hz to 70 Hz, 16.667 SPS Output Data Rate, 60 ms

Settling Time

AD7124-4 Data Sheet

Rev. D | Page 66 of 93

SUMMARY OF FILTER OPTIONS

The AD7124-4 has several filter options. The filter that is

chosen affects the output data rate, settling time, the rms noise,

the stop band attenuation, and the 50 Hz and 60 Hz rejection.

Table 63 shows some sample configurations and the

corresponding performance in terms of throughput and 50 Hz

and 60 Hz rejection.

Table 63. Filter Summary1

Filter Power Mode Output Data Rate (SPS) REJ60 50 Hz Rejection (dB)2

Sinc4 All 10 0 120 dB (50 Hz and 60 Hz)

All 50 0 120 dB (50 Hz only)

All 50 1 82 dB (50 Hz and 60 Hz)

All 60 0 120 dB (60 Hz only)

Sinc4, Zero Latency All 12.5 0 120 dB (50 Hz only)

All 12.5 1 82 dB (50 Hz and 60 Hz)

All

120 dB (60 Hz only)

Sinc3 All 10 0 100 dB (50 Hz and 60 Hz)

All 50 0 95 dB (50 Hz only)

All

67 dB (50 Hz and 60 Hz)

All 60 0 95 dB (60 Hz only)

Fast Settling (Sinc4 + Sinc1) Full/mid 50.53 0 40 dB (60 Hz only)

Low 43.64 0 40 dB (60 Hz only)

Full/mid 42.11 0 40 dB (50 Hz only)

Low 36.36 0 40 dB (50 Hz only)

Full/mid 8.4 0 40 dB (50 Hz and 60 Hz)

Low 7.27 0 40 dB (50 Hz and 60 Hz)

Fast Settling (Sinc3 + Sinc1) Full/mid 53.33 0 40 dB (60 Hz only)

Low 48 0 40 dB (60 Hz only)

Full/mid 44.44 0 40 dB (50 Hz only)

Low

40 dB (50 Hz only)

Full/mid 8.89 0 40 dB (50 Hz and 60 Hz)

Low 8 0 40 dB (50 Hz and 60 Hz)

Post Filter All 27.27 0 47 dB (50 Hz and 60 Hz)

All 25 0 62 dB (50 Hz and 60 Hz)

All 20 0 85 dB (50 Hz and 60 Hz)

All 16.67 0 90 dB (50 Hz and 60 Hz)

1 These calculations assume a stable master clock.

2 For fast settling mode, the 50 Hz/60 Hz rejection is measured in a band of ±0.5 Hz around 50 Hz and/or 60 Hz. For all other modes, a region of ±1 Hz around 50 Hz

and/or 60 Hz is used.

Data Sheet AD7124-4

Rev. D | Page 67 of 93

DIAGNOSTICS

The AD7124-4 has numerous diagnostic functions on chip. Use

these features to ensure

• Read/write operations are to valid registers only

• Only valid data is written to the on-chip registers

• Appropriate decoupling is used on the LDOs

• The external reference, if used, is present

• The ADC modulator and filter are working within

specification

SIGNAL CHAIN CHECK

Functions such as the reference and power supply voltages can

be selected as inputs to the ADC. The AD7124-4 can therefore

check the voltages connected to the device. The AD7124-4 also

generates an internal 20 mV signal that can be applied internally to

a channel by selecting the V_20MV_P to V_20MV_M channel

in the channel register. The PGA can be checked using this

function. As the PGA setting is increased, for example, the

signal as a percent of the analog input range is reduced by a

factor of two. This allows the user to check that the PGA is

functioning correctly.

REFERENCE DETECT

The AD7124-4 includes on-chip circuitry to detect if there is a

valid reference for conversions or calibrations when the user

selects an external reference as the reference source. This is a

valuable feature in applications such as RTDs or strain gages

where the reference is derived externally.

0.7V

COMPARATOR

REF I N (REF INx(+ ) – RE FINx( –) ) OUTPUT: 0 WHEN RE FI N ≤0.7V

1 WHE N RE FIN < 0.7V

13197-128

Figure 122. Reference Detect Circuitry

This feature is enabled when the REF_DET_ERR_EN bit in the

ERROR_EN register is set to 1. If the voltage between the

selected REFINx(+) and REFINx(−) pins goes below 0.7 V, or

either the REFINx(+) or REFINx(−) inputs are open circuit, the

AD7124-4 detects that it no longer has a valid reference. In this

case, the REF_DET_ERR bit in the error register is set to 1. The

ERR bit in the status register is also set.

If the AD7124-4 is performing normal conversions and the

REF_DET_ERR bit becomes active, the conversion results

revert to all 1s. Therefore, it is not necessary to continuously

monitor the status of the REF_DET_ERR bit when performing

conversions. It is only necessary to verify its status if the

conversion result read from the ADC data register is all 1s.

If the AD7124-4 is performing either offset or full-scale

calibrations and the REF_DET_ERR bit becomes active, the

updating of the respective calibration register is inhibited to

avoid loading incorrect coefficients to the register, and the

REF_DET_ERR bit is set. If the user is concerned about

verifying that a valid reference is in place every time a calibration

is performed, check the status of the REF_DET_ERR bit at the

end of the calibration cycle.

The reference detect flag may be set when the device exits

standby mode. Therefore, read the error register after exiting

standby mode to reset the flag to 0.

CALIBRATION, CONVERSION, AND SATURATION

ERRORS

The conversion process and calibration process can also be

monitored by the AD7124-4. These diagnostics check the

analog input used as well as the modulator and digital filter

during conversions or calibration. The functions can be enabled

using the ADC_CAL_ERR_EN, ADC_CONV_ERR_EN, and

ADC_SAT_ERR_EN bits in the ERROR_EN register. With these

functions enabled, the ADC_ CAL_ERR, ADC_CONV_ERR, and

ADC_SAT_ERR bits are set if an error occurs.

The ADC_CONV_ERR flag is set if there is an overflow or

underflow in the digital filter. The ADC conversion clamps to

all 0s or all 1s also. This flag is updated in conjunction with the

update of the data register and can be cleared only by a read of

the error register.

The ADC_SAT_ERR flag is set if the modulator outputs 20

consecutive 1s or 0s. This indicates that the modulator has

saturated.

When an offset calibration is performed, the resulting offset

coefficient must be between 0x7FFFF and 0xF80000. If the

coefficient is outside this range, the offset register is not updated

and the ADC_CAL_ERR flag is set. During a full-scale calibration,

overflow of the digital filter is checked. If an overflow occurs,

the error flag is set and the gain register is not updated.

OVERVOLTAGE/UNDERVOLTAGE DETECTION

The overvoltage/undervoltage monitors check the absolute

voltage on the AINx analog input pins. The absolute voltage

must be within specification to meet the datasheet

specifications. If the ADC is operated outside the datasheet

limits, linearity degrades.

AINx

OVERVOLTAGE

COMPARATOR

+ 40mV

AINx_O V _E RR: S E T I F AI Nx IS

40mV ABOVE AVDD

AINx_UV_E RR: S E T I F AINx IS

40mV ABOVE AVSS

UNDERVOLTAGE

COMPARATOR

NOTE: AINx IS AINP OR AINM

AVSS – 40mV

13197-129

Figure 123. Analog Input Overvoltage/Undervoltage Monitors

AD7124-4 Data Sheet

Rev. D | Page 68 of 93

The positive (AINP) and negative (AINM) analog inputs can be

separately checked for overvoltages and undervoltages. The

AINP_OV_ERR_EN and AINP_UV_ERR_EN bits in the

ERROR_EN register enable the overvoltage/undervoltage

diagnostics respectively. An overvoltage is flagged when the

voltage on AINP exceeds AVDD while an undervoltage is flagged

when the voltage on AINP goes below AVSS. Similarly, an

overvoltage/undervoltage check on the negative analog input

pin is enabled using the AINM_OV_ERR_EN and AINM_UV_

ERR_EN bits in the ERROR_EN register. The error flags are

AINP_OV_ERR, AINP_UV_ERR, AINM_OV_ERR, and

AINM_UV_ERR in the error register.

When this function is enabled, the corresponding flags may be

set in the error register. Therefore, the user must read the error

to ensure that the flags are reset to 0.

POWER SUPPLY MONITORS

Along with converting external voltages, the ADC can monitor

the voltage on the AVDD pin and the IOVDD pin. When the

inputs of AVDD to AVSS or IOVDD to DGND are selected, the

voltage (AVDD to AVSS or IOVDD to DGND) is internally

attenuated by 6, and the resulting voltage is applied to the Σ-Δ

modulator. This is useful because variations in the power supply

voltage can be monitored.

LDO MONITORING

There are several LDO checks included on the AD7124-4. Like

the external power supplies, the voltage generated by the analog

and digital LDOs are selectable as inputs to the ADC. In addition,

the AD7124-4 can continuously monitor the LDO voltages.

Power Supply Monitor

The voltage generated by the ALDO and DLDO can be

monitored by enabling the ALDO_PSM_ERR_EN bit and the

DLDO_PSM_ERR_EN bit, respectively, in the ERROR_EN

continuously monitored. If the ALDO voltage drops below

1.6 V, the ALDO_PSM_ERR flag is asserted. If the DLDO

voltage drops below 1.55 V, the DLDO_PSM_ERR flag is

asserted. The bit remains set until the corresponding LDO

voltage recovers. However, the bit is only cleared when the

error register is read.

1.6V

OVERVOLTAGE

COMPARATOR

ALDO SET IF ALDO O UTPUT VOLTAG E I S

LESS T HA N 1.6V

13197-130

Figure 124. Analog LDO Monitor

1.55V

OVERVOLTAGE

COMPARATOR

DLDO SET IF DLDO OUTPUT VOLTAGE IS

LESS THAN 1.55V

13197-131

Figure 125. Digital LDO Monitor

The AD7124-4 can also test the circuitry used for the power

supply monitoring. When the ALDO_PSM_TRIP_TEST_EN or

DLDO_PSM_TRIP_TEST_EN bits are set, the input to the test

circuitry is tied to GND rather than the LDO output. Set the

corresponding ALDO_PSM_ERR or DLDO_PSM_ERR bit.

LDO Capacitor Detect

The analog and digital LDOs require an external decoupling

capacitor of 0.1 μF. The AD7124-4 can check for the presence of

this decoupling capacitor. Using the LDO_CAP_CHK bits in

the ERROR_EN register, the LDO being checked is turned off

and the voltage at the LDO output is monitored. If the voltage

falls, this is considered a fail and the LDO_CAP_ERR bit in the

error register is set.

Only the analog LDO or digital LDO can be tested for the

presence of the decoupling capacitor at any one time. This test

also interferes with the conversion process.

The circuitry used to check for missing decoupling capacitors

can also be tested by the AD7124-4. When the LDO_CAP_

CHK_TEST_EN bit in the ERROR_EN register is set, the

decoupling capacitor is internally disconnected from the LDO,

forcing a fault condition. Therefore, when the LDO capacitor

test is performed, a fault condition is reported, that is, the

LDO_CAP_ERR bit in the error register is set.

MCLK COUNTER

A stable master clock is important as the output data rate, filter

settling time, and the filter notch frequencies are dependent on

the master clock. The AD7124-4 allows the user to monitor the

master clock. When the MCLK_CNT_EN bit in the ERROR_EN

131 master clock cycles. The user can monitor this register over

a fixed period of time. The master clock frequency can be

determined from the result in the MCLK_COUNT register. The

MCLK_COUNT register wraps around after it reaches its

maximum value.

Note that the incrementation of the register is asynchronous to

the register read. If a register read coincides with the register

incrementation, it is possible to read an invalid value. To prevent

this, read the register four times rather than once, then read the

it is possible to identify the correct register value at the start and

at the end of the timing instants.

SPI SCLK COUNTER

The SPI SCLK counter counts the number of SCLK pulses used

in each read and write operation. CS must frame every read and

write operation when this function is used. All read and write

operations are multiples of eight SCLK pulses (8, 16, 32, 40, 48).

If the SCLK counter counts the SCLK pulses and the result is not a

multiple of eight, an error is flagged; the SPI_SCLK_CNT_ERR bit

in the error register is set. If a write operation is being performed

and the SCLK contains an incorrect number of SCLK pulses,

the value is not written to the addressed register and the write

operation is aborted.

Data Sheet AD7124-4

Rev. D | Page 69 of 93

The SCLK counter is enabled by setting the SPI_SCLK_

CNT_ERR_EN bit in the ERROR_EN register.

SPI READ/WRITE ERRORS

Along with the SCLK counter, the AD7124-4 can also check the

read and write operations to ensure that valid registers are being

addressed. When the SPI_READ_ERR_EN bit or the SPI_

WRITE_ERR_EN bit in the ERROR_EN register are set, the

AD7124-4 checks the address of the read/write operations. If

the user attempts to write to or read from any register other

than the user registers described in this data sheet, an error is

flagged; the SPI_READ_ERR bit or the SPI_WRITE_ERR bit in

the error register is set and the read/write operation is aborted.

This function, along with the SCLK counter and the CRC,

makes the serial interface more robust. Invalid registers are not

written to or read from. An incorrect number of SCLK pulses

can cause the serial interface to go asynchronous and incorrect

registers to be accessed. The AD7124-4 protects against these

issues via the diagnostics.

SPI_IGNORE ERROR

At certain times, the on-chip registers are not accessible. For

example, during power-up, the on-chip registers are set to their

default values. The user must wait until this operation is

complete before writing to registers. Also, when offset or gain

calibrations are being performed, registers cannot be accessed.

The SPI_IGNORE_ERR bit in the error register indicates when

the on-chip registers cannot be written to. This diagnostic is

enabled by default. The function can be disabled using the

SPI_IGNORE_ERR_EN bit in the ERROR_EN register.

Any write operations performed when SPI_IGNORE_ERR is

enabled are ignored.

CHECKSUM PROTECTION

The AD7124-4 has a checksum mode that can be used to improve

interface robustness. Using the checksum ensures that only

valid data is written to a register and allows data read from a

write, the CRC_ERR bit is set in the error register. However, to

ensure that the register write was successful, read back the

For CRC checksum calculations, the following polynomial is

always used:

x8 + x2 + x + 1

The CRC_ERR_EN bit in the ERROR_EN register enables and

disables the checksum.

The checksum is appended to the end of each read and write

transaction. The checksum calculation for the write transaction

is calculated using the 8-bit command word and the 8-bit to 24-bit

data. For a read transaction, the checksum is calculated using the

command word and the 8-bit to 32-bit data output. Figure 126 and

Figure 127 show SPI write and read transactions, respectively.

8-BI T COM M AND 8-BIT CRCUP TO 24-BI T I NP UT

CS DATA CRC

DIN

SCLK

13197-132

Figure 126. SPI Write Transaction with CRC

8- BIT COM MAND 8- BIT CRCUP TO 32 -BI T OUTPUT

CMD

DATA CRC

DIN

SCLK

DOUT/

RDY

13197-133

Figure 127. SPI Read Transaction with CRC

If checksum protection is enabled when continuous read mode

is active, there is an implied read data command of 0x42 before

every data transmission that must be accounted for when

calculating the checksum value. This ensures a nonzero checksum

value even if the ADC data equals 0x000000.

MEMORY MAP CHECKSUM PROTECTION

For added robustness, a CRC calculation is performed on the

on-chip registers as well. The status register, data register, error

check because their contents change continuously. The CRC is

performed at a rate of 1/2400 seconds. Each time that the

memory map is accessed, the CRC is recalculated. Events which

cause the CRC to be recalculated are

• A user write

• An offset/full-scale calibration

• When the device is operated in single conversion mode

and the ADC goes into standby mode following the

completion of the conversion

• When exiting continuous read mode (the CONT_READ bit

in the ADC_CONTROL register is set to 0)

The memory map CRC function is enabled by setting the

MM_CRC_ERR_EN bit in the ERROR_EN register to 1. If an

error occurs, the MM_CRC_ERR bit in the error register is set

to 1.

AD7124-4 Data Sheet

Rev. D | Page 70 of 93

ROM CHECKSUM PROTECTION

On power-up, all registers are set to default values. These default

values are held in read only memory (ROM). For added robustness,

a CRC calculation is performed on the ROM contents as well. The

CRC is performed on power-up.

The ROM CRC function is enabled by setting the ROM_CRC_

ERR_EN bit in the ERROR_EN register to 1. If an error occurs,

the ROM_CRC_ERR bit in the error register is set to 1.

When this function is enabled, the internal master clock, if

enabled, remains active in the standby mode.

CRC Calculation

The checksum, which is 8 bits wide, is generated using the

polynomial

x8 + x2 + x + 1

To generate the checksum, the data is left shifted by eight bits to

create a number ending in eight Logic 0s. The polynomial is

aligned so that its MSB is adjacent to the leftmost Logic 1 of the

data. An XOR (exclusive OR) function is applied to the data to

produce a new, shorter number. The polynomial is again aligned

so that its MSB is adjacent to the leftmost Logic 1 of the new result,

and the procedure is repeated. This process is repeated until the

original data is reduced to a value less than the polynomial.

This is the 8-bit checksum.

Example of a Polynomial CRC Calculation—24-Bit Word: 0x654321 (8-Bit Command and 16-Bit Data)

An example of generating the 8-bit checksum using the polynomial based checksum is as follows:

Initial value 011001010100001100100001

01100101010000110010000100000000 left shifted eight bits

x8 + x2 + x + 1 = 100000111 polynomial

100100100000110010000100000000 XOR result

100000111 polynomial

100011000110010000100000000 XOR result

100000111 polynomial

11111110010000100000000 XOR result

100000111 polynomial value

1111101110000100000000 XOR result

100000111 polynomial value

111100000000100000000 XOR result

100000111 polynomial value

11100111000100000000 XOR result

100000111 polynomial value

1100100100100000000 XOR result

100000111 polynomial value

100101010100000000 XOR result

100000111 polynomial value

101101100000000 XOR result

100000111 polynomial value

1101011000000 XOR result

100000111 polynomial value

101010110000 XOR result

100000111 polynomial value

1010001000 XOR result

100000111 polynomial value

10000110 checksum = 0x86

Data Sheet AD7124-4

Rev. D | Page 71 of 93

BURNOUT CURRENTS

The AD7124-4 contains two constant current generators that

can be programmed to 0.5 µA, 2 µA, or 4 µA. One generator

sources current from AVDD to AINP, and one sinks current from

AINM to AVSS. These currents enable open wire detection.

X-MUX

AVDD

AVSS

BURNOUT

DETECT PGA1

13197-134

Figure 128. Burnout Currents

The currents are switched to the selected analog input pair.

Both currents are either on or off. The burnout bits in the

configuration register enable/disable the burnout currents along

with setting the amplitude. Use these currents to verify that an

external transducer is still operational before attempting to take

measurements on that channel. After the burnout currents are

turned on, they flow in the external transducer circuit, and a

measurement of the input voltage on the analog input channel

can be taken. If the resulting voltage measured is near full scale,

the user must verify why this is the case. A near full-scale reading

can mean that the front-end sensor is open circuit. It can also

mean that the front-end sensor is overloaded and is justified in

outputting full scale, or that the reference may be absent and the

REF_DET_ERR bit is set, thus clamping the data to all 1s.

When a conversion is close to full scale, the user must check

these three cases before making a judgment. If the voltage

measured is 0 V, it may indicate that the transducer has short

circuited. For normal operation, these burnout currents are

turned off by setting the burnout bits to zero. The current

sources work over the normal absolute input voltage range

specifications with buffers on.

TEMPERATURE SENSOR

Embedded in the AD7124-4 is a temperature sensor that is

useful to monitor the die temperature. This is selected using the

AINP[4:0] and AINM[4:0] bits in the channel register. The

sensitivity is 13,584 codes/°C, approximately. The equation for

the temperature sensor is

Temperature (°C) = ((Conversion − 0x800000)/13,584) − 272.5

The temperature sensor has an accuracy of ±0.5°C typically.

–0.6

–0.4

–0.2

0.2

0.4

0.6

0.8

1.0

1.2

–40 –30 –20 –10 015 25 40 50 60 70 85 95 125115105

TEMPERATURE SE NS OR ERROR (°C)

TEMPERATURE (°C)

32 UNITS

13197-135

Figure 129. Temperature Sensor Error vs. Temperature

AD7124-4 Data Sheet

Rev. D | Page 72 of 93

GROUNDING AND LAYOUT

The analog inputs and reference inputs are differential and,

therefore, most of the voltages in the analog modulator are

common-mode voltages. The high common-mode rejection of

the device removes common-mode noise on these inputs. The

analog and digital supplies to the AD7124-4 are independent

and separately pinned out to minimize coupling between the

analog and digital sections of the device. The digital filter

provides rejection of broadband noise on the power supplies,

except at integer multiples of the master clock frequency.

The digital filter also removes noise from the analog and

reference inputs, provided that these noise sources do not

saturate the analog modulator. As a result, the AD7124-4 is

more immune to noise interference than a conventional high

resolution converter. However, because the resolution of the

AD7124-4 is high and the noise levels from the converter are so

low, care must be taken with regard to grounding and layout.

The PCB that houses the ADC must be designed so that the

analog and digital sections are separated and confined to

certain areas of the board. A minimum etch technique is

generally best for ground planes because it results in the best

shielding.

In any layout, the user must keep in mind the flow of currents

in the system, ensuring that the paths for all return currents are as

close as possible to the paths the currents took to reach their

destinations.

Avoid running digital lines under the device because this

couples noise onto the die and allows the analog ground plane

to run under the AD7124-4 to prevent noise coupling. The

power supply lines to the AD7124-4 must use as wide a trace as

possible to provide low impedance paths and reduce glitches on

the power supply line. Shield fast switching signals like clocks

with digital ground to prevent radiating noise to other sections

of the board and never run clock signals near the analog inputs.

Avoid crossover of digital and analog signals. Run traces on

opposite sides of the board at right angles to each other. This

reduces the effects of feedthrough on the board. A microstrip

technique is by far the best but is not always possible with a

double-sided board. In this technique, the component side of

the board is dedicated to ground planes, whereas signals are

placed on the solder side.

Good decoupling is important when using high resolution ADCs.

The AD7124-4 has two power supply pins—AVDD and IOVDD.

The AVDD pin is referenced to AVSS, and the IOVDD pin is

referenced to DGND. Decouple AVDD with a 1 µF tantalum

capacitor in parallel with a 0.1 µF capacitor to AVSS on each pin.

Place the 0.1 µF capacitor as close as possible to the device on

each supply, ideally right up against the device. Decouple IOVDD

with a 1 µF tantalum capacitor in parallel with a 0.1 µF

capacitor to DGND. All analog inputs must be decoupled to

AVSS. If an external reference is used, decouple the REFINx(+)

and REFINx(−) pins to AVSS.

The AD7124-4 also has two on-board LDO regulators—one

that regulates the AVDD supply and one that regulates the IOVDD

supply. For the REGCAPA pin, it is recommended that a 0.1 µF

capacitor to AVSS be used. Similarly, for the REGCAPD pin, it is

recommended that a 0.1 µF capacitor to DGND be used.

If using the AD7124-4 with split supply operation, a separate

plane must be used for AVSS.

Data Sheet AD7124-4

Rev. D | Page 73 of 93

APPLICATIONS INFORMATION

The AD7124-4 offers a low cost, high resolution analog-to-

digital function. Because the analog-to-digital function is provided

by a Σ-Δ architecture, the device is more immune to noisy

environments, making it ideal for use in sensor measurement,

and industrial and process control applications.

TEMPERATURE MEASUREMENT USING A

THERMOCOUPLE

Figure 130 outlines a connection from a thermocouple to the

AD7124-4. In a thermocouple application, the voltage generated

by the thermocouple is measured with respect to an absolute

reference; thus, the internal reference is used for this conversion.

The cold junction measurement uses a ratiometric configuration,

so the reference is provided externally.

Because the signal from the thermocouple is small, the AD7124-4

is operated with the PGA enabled to amplify the signal from the

thermocouple. As the input channel is buffered, large decoupling

capacitors can be placed on the front end to eliminate any noise

pickup that may be present in the thermocouple leads. The bias

voltage generator provides a common-mode voltage so that the

voltage generated by the thermocouple is biased up to (AVDD −

AVSS)/2. For thermocouple voltages that are centered about ground,

the AD7124-4 can be operated with a split power supply (±1.8 V).

The cold junction compensation is performed using a thermistor in

Figure 130. The on-chip excitation current supplies the thermistor.

In addition, the reference voltage for the cold junction measurement

is derived from a precision resistor in series with the thermistor.

This allows a ratiometric measurement so that variation of the

excitation current has no effect on the measurement (it is the

ratio of the precision reference resistance to the thermistor

resistance that is measured).

Most conversions are read from the thermocouple, with the

cold junction being read only periodically as the cold junction

temperature is stable or slow moving. If a T-type thermocouple

is used, it can measure a temperature from −200°C to +400°C.

The voltage generated over this temperature range is −8.6 mV

to +17.2 mV. The AD7124-4 internal reference equals 2.5 V.

Therefore, the PGA is set to 128. If the thermocouple uses the

AIN0/AIN1 channel and the thermistor is connected to the

AIN4/AIN5 channel, the conversion process is as follows:

1. Reset the ADC.

2. Select the power mode.

Set the CHANNEL_0 register analog input to AIN0/AIN1.

Assign Setup 0 to this channel. Configure Setup 0 to have a

gain of 128 and select the internal reference. Select the

filter type and set the output data rate.

3. Enable VBIAS on AIN0.

4. Set the CHANNEL_1 register analog input to AIN4/AIN5.

Assign Setup 1 to this channel. Configure Setup 1 to have a

gain of 1 and select the external reference REFIN2(±).

Select the filter type and set the output data rate.

5. Enable the excitation current (IOUTx) and select a suitable

value. Output this current to the AIN4 pin.

6. Enable the AIN0/AIN1 channel. Wait until RDY goes low.

Read the conversion.

7. Continue to read nine further conversions from the

AIN0/AIN1 channel.

8. Disable CHANNEL_0 and enable CHANNEL_1.

9. Wait until RDY goes low. Read one conversion.

10. Repeat Step 5 to Step 8.

Using the linearization equation for the T-type thermocouple,

process the thermocouple voltage along with the thermistor voltage

and compute the actual temperature at the thermocouple head.

SERIAL

INTERFACE

AND

CONTROL

LOGIC

INTERNAL

CLOCK CLK

AIN0

X-MUX

REFERENCE

DETECT

DOUT/RDY

SCLK

IOV

TEMP

SENSOR

DIN

SYNC

PSW

REFIN1(–)

REFIN1(+)

REF

AIN1

AIN4

AIN5

REFIN2(+)

REFIN2(–)

PGA Σ-Δ

ADC

AD7124-4

DGND

BIAS

DIAGNOSTICS

CHANNEL

SEQUENCER

BAND GAP

REFERENCE

NOTES

1. SIMP LI FIE D BLO CK DIAG RAM S HOWN.

REGCAPA REGCAPD

DIGITAL

FILTER

COLD JUNCTIO N

THE RM OCOUP LE JUNCTION

13197-136

Figure 130. Thermocouple Application

AD7124-4 Data Sheet

Rev. D | Page 74 of 93

The external antialias filter is omitted for clarity. However, such

a filter is required to reject any interference at the modulator

frequency and multiples of the modulator frequency. In addition,

some filtering may be needed for EMI purposes. Both the analog

inputs and the reference inputs can be buffered, which allows

the user to connect any RC combination to the reference or

analog input pins.

The required power mode depends on the performance

required from the system along with the current consumption

allowance for the system. In a field transmitter, low current

consumption is essential. In this application, the low power

mode or mid power mode is most suitable. In process control

applications, power consumption is not a priority. Thus, full

power mode may be selected. The full power mode offers

higher throughput and lower noise.

The AD7124-4 on-chip diagnostics allow the user to check the

circuit connections, monitor power supply, reference, and LDO

voltages, check all conversions and calibrations for any errors, as

well as monitor any read/write operations. In thermocouple

applications, the circuit connections are verified using the

reference detect and the burnout currents. The REF_DET_ERR

flag is set if the external reference REFIN2(±) is missing. The

burnout currents (available in the configuration registers) detect an

open wire. For example, if the thermocouple is not connected

and the burnout currents are enabled on the channel, the ADC

outputs a conversion that is equal to or close to full scale. For

best performance, enable the burnout currents periodically to

check the connections but disable them as soon as the connections

are verified for they add an error to the conversions. The

decoupling capacitors on the LDOs can also be checked. The

ADC indicates if the capacitor is not present.

As part of the conversion process, the analog input overvoltage/

undervoltage monitors are useful for detecting any excessive

voltages on AINP and AINM. The power supply voltages and

reference voltages are selectable as inputs to the ADC. Thus, the

user can periodically check these voltages to confirm whether

they are within the system specification. Also, the user can check

that the LDO voltages are within specification. The conversion

process and calibration process can also be checked. This ensures

that any invalid conversions or calibrations are flagged to the user.

Finally, the CRC check, SCLK counter, and the SPI read/write

checks make the interface more robust as any read/write

operation that is not valid is detected. The CRC check

highlights if any bits are corrupted when being transmitted

between the processor and the ADC.

TEMPERATURE MEASUREMENT USING AN RTD

To optimize a 3-wire RTD configuration, two identically

matched current sources are required. The AD7124-4, which

contains two well matched current sources, is ideally suited to

these applications. One possible 3-wire configuration is shown

in Figure 131. In this 3-wire configuration, the lead resistances

result in errors if only one current (output at AIN0) is used, as

the excitation current flows through RL1, developing a voltage

error between AIN1 and AIN2. In the scheme outlined, the

second RTD current source (available at AIN3) compensates for

the error introduced by the excitation current flowing through

RL1. The second RTD current flows through RL2. Assuming

that RL1 and RL2 are equal (the leads are normally of the same

material and of equal length) and that the excitation currents

match, the error voltage across RL2 equals the error voltage

across RL1, and no error voltage is developed between AIN1

and AIN2. Twice the voltage is developed across RL3; however,

because this is a common-mode voltage it does not introduce

errors. The reference voltage for the AD7124-4 is also generated

using one of the matched current sources. It is developed using

a precision resistor and applied to the differential reference pins

of the ADC. This scheme ensures that the analog input voltage

span remains ratiometric to the reference voltage. Any errors in

the analog input voltage due to the temperature drift of the

excitation current are compensated by the variation of the

reference voltage.

As an example, the PT100 measures temperature from −200°C

to +600°C. The resistance is 100 Ω typically at 0°C and 313.71 Ω

at 600°C. If the 500 µA excitation currents are used, the

maximum voltage generated across the RTD when using the full

temperature range of the RTD is

500 µA × 313.71 Ω = 156.86 mV

This is amplified to 2.51 V within the AD7124-4 if the gain is

programmed to 16.

The voltage generated across the reference resistor must be at least

2.51 V. Therefore, the reference resistor value must equal at least

2.51 V/500 µA = 5020 Ω

Therefore, a 5.11 kΩ resistor can be used.

5.11 kΩ × Excitation Current = 5.11 kΩ × 500 µA = 2.555 V

One other consideration is the output compliance. The output

compliance equals AVDD − 0.37 V. If a 3 .3 V analog supply is

used, the voltage at AIN0 must be less than (3.3 V − 0.37 V) =

2.93 V. From the previous calculations, this specification is met

because the maximum voltage at AIN0 equals the voltage across

the reference resistor plus the voltage across the RTD, which equals

2.555 V + 156.86 mV = 2.712 V

Data Sheet AD7124-4

Rev. D | Page 75 of 93

A typical procedure for reading the RTD is as follows:

1. Reset the ADC.

2. Select the power mode.

3. Set the CHANNEL_0 register analog input to AIN1/AIN2.

Assign Setup 0 to this channel. Configure Setup 0 to have a

gain of 16 and select the reference source REFIN2(±).

Select the filter type and set the output data rate.

4. Program the excitation currents to 500 µA and output the

currents on the AIN0 and AIN3 pins.

5. Wait until RDY goes low. Read the conversion value.

6. Repeat Step 4.

In the processor, implement the linearization routine for the PT100.

The external antialias filter is omitted for clarity. However, such

a filter is required to reject any interference at the modulator

frequency and multiples of the modulator frequency. Also, some

filtering may be needed for EMI purposes. Both the analog inputs

and reference inputs can be buffered, which allows the user to

connect any RC combination to the reference or analog input pins.

On the AD7124-4, the excitation currents can be made available

at the input pins, for example, the AIN3 pin can function as an

analog input as well as outputting the current source. This option

allows multiple sensors to be connected to the ADC using a

minimum pin count. However, the resistor of the antialiasing

filter is in series with the RTD. This introduces an error in the

conversions as there is a voltage generated across the antialiasing

resistor. To minimize the error, minimize the resistance of the

antialiasing filter.

The power mode to use depends on the performance required

from the system along with the current consumption allowance

for the system. In a field transmitter, low current consumption

is essential. In this application, the low power mode or mid power

mode is most suitable. In process control applications, power

consumption is not a priority. Thus, full power mode may be

selected. The full power mode offers higher throughput and

lower noise.

The AD7124-4 on-chip diagnostics allow the user to check the

circuit connections, monitor the power supply, reference, and

LDO voltages, check all conversions and calibrations for any

errors, as well as monitor any read/write operations. In RTD

applications, the circuit connections are verified using the

reference detect and the burnout currents. The REF_DET_ERR

flag is set if the external reference REFIN2(±) is missing. The

burnout currents (available in the configuration registers) detect an

open wire. The decoupling capacitors on the LDOs can also be

checked. The ADC indicates if the capacitor is not present.

As part of the conversion process, the analog input overvoltage/

undervoltage monitors are useful to detect any excessive voltages

on AINP and AINM. The power supply voltages and reference

voltages are selectable as inputs to the ADC. Thus, the user can

periodically check these voltages to confirm whether they are

within the system specification. Also, the user can check that

the LDO voltages are within specification. The conversion process

and calibration process can also be checked. This ensures that

any invalid conversions or calibrations are flagged to the user.

Finally, the CRC check, SCLK counter, and the SPI read/write

checks make the interface more robust as any read/write

operation that is not valid is detected. The CRC check highlights if

any bits are corrupted when being transmitted between the

processor and the ADC.

BIAS

SERIAL

INTERFACE

AND

CONTROL

LOGIC

INTERNAL

CLOCK CLK

AIN0

X-MUX

REFERENCE

DETECT

DOUT/RDY

SCLK

IOV

TEMP

SENSOR

DIN

SYNC

REFIN1(–)

REFIN1(+)

REF

AIN1

REFIN2(+)

REFIN2(–)

AIN2

AIN3

PGA Σ-Δ

ADC

AD7124-4

DGND

RTD

RL1

RL2

RL3

PSW

DIAGNOSTICS

CHANNEL

SEQUENCER

NOTES

1. SIMP LI FIE D BLO CK DIAG RAM S HOWN. REGCAPA REGCAPD

DIGITAL

FILTER

13197-137

Figure 131. 3-Wire RTD Application

AD7124-4 Data Sheet

Rev. D | Page 76 of 93

FLOWMETER

Figure 132 shows the AD7124-4 being used in a flowmeter

application that consists of two pressure transducers, with the

rate of flow being equal to the pressure difference. The pressure

transducers are arranged in a bridge network and give a differential

output voltage between its OUT+ and OUT− terminals. With

rated full-scale pressure (in this case, 300 mmHg) on the

transducer, the differential output voltage is 3 mV/V of the input

voltage (that is, the voltage between the IN+ and IN−

terminals).

Assuming a 3 V excitation voltage, the full-scale output range

from the transducer is 9 mV. The excitation voltage for the

bridge can directly provide the reference for the ADC, as the

reference input range includes the supply voltage.

A second advantage of using the AD7124-4 in transducer-based

applications is that the low-side power switch can be fully utilized

in low power applications. The low-side power switch is connected

in series with the cold side of the bridges. In normal operation,

the switch is closed and measurements are taken. In applications

where power is of concern, the AD7124-4 can be placed in standby

mode, thus significantly reducing the power consumed in the

application. In addition, the low-side power switch can be opened

while in standby mode, thus avoiding unnecessary power

consumption by the front-end transducers. When the device is

taken out of standby mode, and the low-side power switch is

closed, the user must ensure that the front-end circuitry is fully

settled before attempting a read from the AD7124-4. The power

switch can be closed prior to taking the device out of standby, if

needed. This allows time for the sensor to power up and settle

before the ADC powers up and begins sampling the analog input.

In the diagram, temperature compensation is performed using a

thermistor. The on-chip excitation current supplies the thermistor.

In addition, the reference voltage for the temperature measurement

is derived from a precision resistor in series with the thermistor.

This allows a ratiometric measurement so that variation of the

excitation current has no effect on the measurement (it is the

ratio of the precision reference resistance to the thermistor

resistance that is measured).

If the sensor sensitivity is 3 mV/V and the excitation voltage is 3 V,

the maximum output from the sensor is 9 mV. The AD7124-4

PGA can be set to 128 to amplify the sensor signal.

The AD7124-4 PGA amplifies the signal to

9 mV × 128 = 1.152 V

This value does not exceed the reference voltage (3 V).

A typical procedure for reading the sensors is as follows:

1. Reset the ADC.

2. Select the power mode.

3. Set the CHANNEL_0 register analog input to AIN0/AIN1.

Assign Setup 0 to this channel. Configure Setup 0 to have a

gain of 128 and select the reference source to REFIN1(±).

Select the filter type and set the output data rate.

4. Set the CHANNEL_1 register analog input to AIN2/AIN3.

Assign Setup 0 to this channel (both channels use the same

setup).

5. Set the CHANNEL_2 register analog input to AIN4/AIN5.

Assign Setup 1 to this channel. Configure Setup 1 to have a

gain of 1 and select the reference source REFIN2(±). Select

the filter type and set the output data rate.

6. Program the excitation current and output the current on

the AIN4 pin.

7. Enable both CHANNEL_0 and CHANNEL_1. Enable the

DATA_STATUS bit to identify the channel from which the

conversion originated. The ADC automatically sequences

through these channels.

8. Wait until RDY goes low. Read the conversion value.

9. Repeat Step 8 until the temperature is to be read (every 10

conversions of the pressure sensor readings, for example).

10. Disable CHANNEL_0 and CHANNEL_1. Enable

CHANNEL_2.

11. Wait until RDY goes low. Read the conversion.

12. Repeat Step 6 to Step 10.

In the processor, the conversion information is converted to

pressure and the flow rate can be calculated. The processor

typically contains a lookup table for each pressure sensor so its

variation with temperature can be compensated.

The external antialias filter is omitted for clarity. However, such

a filter is required to reject any interference at the modulator

frequency and multiples of the modulator frequency. Also,

some filtering may be needed for EMI purposes. Both the

analog inputs and reference inputs can be buffered, which

allows the user to connect any RC combination to the reference

or analog input pins.

The power mode to use depends on the performance required

from the system along with the current consumption allowance

for the system. In a field transmitter, low current consumption

is essential. In this application, low power mode or mid power

mode is most suitable. In process control applications, power

consumption is not a priority. Thus, full power mode may be

selected. Full power mode offers higher throughput and lower

noise.

Data Sheet AD7124-4

Rev. D | Page 77 of 93

The AD7124-4 on-chip diagnostics allow the user to check the

circuit connections, monitor power supply, reference, and LDO

voltages, check all conversions and calibrations for any errors, as

well as monitor any read/write operations. The REF_DET_ERR

flag is set if the external reference REFIN2(±) or REFIN1(±) is

missing. The decoupling capacitors on the LDOs can also be

checked. The ADC indicates if the capacitor is not present.

As part of the conversion process, the analog input

overvoltage/undervoltage monitors are useful to detect any

excessive voltages on AINP and AINM. The power supply

voltages and reference voltages are selectable as inputs to the

ADC. Thus, the user can periodically check these voltages to

confirm whether they are within the system specification. In

addition, the user can check that the LDO voltages are within

specification. The conversion process and calibration process

can also be checked. This ensures that any invalid conversions

or calibrations are flagged to the user.

Finally, the CRC check, SCLK counter, and the SPI read/write

checks make the interface more robust as any read/write

operation that is not valid is detected. The CRC check

highlights if any bits are corrupted when being transmitted

between the processor and the ADC.

BIAS

SERIAL

INTERFACE

AND

CONTROL

LOGIC

INTERNAL

CLOCK

DIAGNOSTICS

CHANNEL

SEQUENCER

DIGITAL

FILTER

CLK

AIN0

X-MUX

AVDD

REFERENCE

DETECT

DOUT/RDY

SCLK

IOVDD

VDD

TEMP

SENSOR

DIN

SYNC

AVSS

NOTES

1. SIMP LI FIE D BLO CK DIAG RAM S HOWN.

AVSS

PSW

OUT+OUT–

IN+

IN–

REFIN1(–)

REFIN1(+)

RREF

OUT+OUT–

IN+

IN–

AIN1

AIN2

AIN3

AIN4

AIN5

REFIN2(+)

REFIN2(–)

PGA Σ-Δ

ADC

AD7124-4

REGCAPA REGCAPD AVSS DGND

13197-138

Figure 132. Flowmeter Application

AD7124-4 Data Sheet

Rev. D | Page 78 of 93

ON-CHIP REGISTERS

The ADC is controlled and configured via a number of on-chip registers that are described in the following sections. In the following

descriptions, set implies a Logic 1 state and cleared implies a Logic 0 state, unless otherwise noted.

Table 64. Register Summary

Addr. Name Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset RW

0x00 COMMS WEN R/W RS[5:0] 0x00 W

0x00 Status RDY ERROR_FLAG 0 POR_FLAG CH_ACTIVE 0x00 R

0x01 ADC_

CONTROL

0 DOUT_RDY_

DEL

CONT_READ DATA_STATUS CS_EN REF_EN 0x0000 RW

POWER_MODE Mode CLK_SEL

0x02 Data Data [23:16] 0x000000 R

Data [15:8]

Data [7:0]

0x03 IO_

CONTROL_1

GPIO_DAT2 GPIO_DAT1 0 0 GPIO_CTRL2 GPIO_CTRL1 0 0 0x000000 RW

PDSW 0 IOUT1 IOUT0

IOUT1_CH IOUT0_CH

0x04 IO_

CONTROL_2

VBIAS7 VBIAS6 0 0 VBIAS5 VBIAS4 0 0 0x0000 RW

0 0 VBIAS3 VBIAS2 0 0 VBIAS1 VBIAS0

0x05 ID DEVICE_ID SILICON_REVISION 0x04/0x06 R

0x06 Error 0 LDO_CAP_ERR ADC_CAL_ERR ADC_CONV_

ERR

ADC_SAT_ERR 0x000000 R

AINP_OV_ERR AINP_UV_ERR AINM_OV_ERR AINM_UV_

ERR

REF_DET_ERR 0 DLDO_PSM_

ERR

ALDO_PSM_

ERR

SPI_IGNORE_

ERR

SPI_SCLK_CNT_

ERR

SPI_READ_

ERR

SPI_WRITE_

ERR

SPI_CRC_ERR MM_CRC_ERR ROM_CRC_ERR

0x07 ERROR_EN 0 MCLK_CNT_EN LDO_CAP_CHK_

TEST_EN

LDO_CAP_CHK ADC_CAL_ERR_

ADC_CONV_

ERR_EN

ADC_SAT_

ERR_EN

0x000040 RW

AINP_OV_ERR_

AINP_UV_ERR_

AINM_OV_ERR_

AINM_UV_

ERR_EN

REF_DET_ERR_

DLDO_PSM_

TRIP_TEST_EN

DLDO_PSM_

ERR_EN

ALDO_PSM_

TRIP_TEST_EN

ALDO_PSM_

ERR_EN

SPI_IGNORE_

ERR_EN

SPI_SCLK_CNT_

ERR_EN

SPI_READ_

ERR_EN

SPI_WRITE_

ERR_EN

SPI_CRC_ERR_EN MM_CRC_ERR_

ROM_CRC_

ERR_EN

0x08 MCLK_

COUNT

MCLK_COUNT 0x00 R

0x09

0x18

CHANNEL_0

CHANNEL_15

Enable Setup 0 AINP[4:3] 0x80011 RW

AINP[2:0] AINM[4:0]

0x19

0x20

CONFIG_0 to

CONFIG_7

0 Bipolar Burnout REF_BUFP 0x0860 RW

REF_BUFM AIN_BUFP AIN_BUFM REF_SEL PGA

0x21

0x28

FILTER_0 to

FILTER_7

Filter REJ60 POST_FILTER SINGLE_CYCLE 0x060180 RW

0 FS[10:8]

FS[7:0]

0x29

0x30

OFFSET_0 to

OFFSET_7

Offset [23:16] 0x800000 RW

Offset [15:8]

Offset [7:0]

0x31

0x38

GAIN_0 to

GAIN_7

Gain [23:16] 0x5XXXXX RW

Gain [15:8]

Gain [7:0]

1 CHANNEL_0 is reset to 0x8001. All other channels are reset to 0x0001.

Data Sheet AD7124-4

Rev. D | Page 79 of 93

COMMUNICATIONS REGISTER

RS[5:0] = 0, 0, 0, 0, 0, 0

The communications register is an 8-bit, write only register. All

communications to the device must start with a write operation

to the communications register. The data written to the communi-

cations register determines whether the next operation is a read

or write operation, and to which register this operation takes

place, the RS[5:0] bits selecting the register to be accessed.

For read or write operations, after the subsequent read or write

operation to the selected register is complete, the interface

returns to where it expects a write operation to the

communications register. This is the default state of the interface

and, on power-up or after a reset, the ADC is in this default state

waiting for a write operation to the communications register.

In situations where the interface sequence is lost, a write

operation of at least 64 serial clock cycles with DIN high returns

the ADC to this default state by resetting the entire device.

Table 65 outlines the bit designations for the communications

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

WEN (0) R/W (0) RS[5:0] (0)

Table 65. Communications Register Bit Descriptions

Bits Bit Name Description

7 WEN Write enable bit. A 0 must be written to this bit so that the write to the communications register actually occurs. If

a 1 is the first bit written, the device does not clock on to subsequent bits in the register. It stays at this bit location

until a 0 is written to this bit. As soon as a 0 is written to the WEN bit, the next seven bits are loaded to the

communications register.

6 R/W A 0 in this bit location indicates that the next operation is a write to a specified register. A 1 in this position

indicates that the next operation is a read from the designated register.

5:0 RS[5:0] Register address bits. These address bits select which registers of the ADC are being selected during this serial

interface communication. See Table 64.

STATUS REGISTER

RS[5:0] = 0, 0, 0, 0, 0, 0

Power-On/Reset = 0x00

The status register is an 8-bit, read only register. To access the ADC status register, the user must write to the communications register,

select the next operation to be read, and set the register address bits RS[5:0] to 0.

Table 66 outlines the bit designations for the status register. Bit 7 denotes the first bit of the data stream. The number in parentheses

indicates the power-on/reset default status of that bit.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

RDY (0) ERROR_FLAG (0) 0 (0) POR_FLAG (0) CH_ACTIVE (0)

Table 66. Status Register Bit Descriptions

Bits Bit Name Description

7 RDY Ready bit for the ADC. This bit is cleared when data is written to the ADC data register. The RDY bit is set

automatically after the ADC data register is read or a period of time before the data register is updated with a

new conversion result to indicate to the user not to read the conversion data. It is also set when the device is

placed in power-down or standby mode. The end of a conversion is also indicated by the DOUT/RDY pin. This

pin can be used as an alternative to the status register for monitoring the ADC for conversion data.

6 ERROR_FLAG ADC error bit. This bit indicates if one of the error bits has been asserted in the error register. This bit is high if

one or more of the error bits in the error register has been set. This bit is cleared by a read of the error register.

5 0 This bit is set to 0.

4 POR_FLAG Power-on reset flag. This bit indicates when a power-on reset occurs. A power-on reset occurs on power-up,

when the power supply voltage goes below a threshold voltage, when a reset is performed, and when coming

out of power-down mode. The status register must be read to clear the bit.

AD7124-4 Data Sheet

Rev. D | Page 80 of 93

Bits Bit Name Description

3:0 CH_ACTIVE These bits indicate which channel is being converted by the ADC.

0000 = Channel 0.

0001 = Channel 1.

0010 = Channel 2.

0011 = Channel 3.

0100 = Channel 4.

0101 = Channel 5.

0110 = Channel 6.

0111 = Channel 7.

1000 = Channel 8.

1001 = Channel 9.

1010 = Channel 10.

1011 = Channel 11.

1100 = Channel 12.

1101 = Channel 13.

1110 = Channel 14.

1111 = Channel 15.

ADC_CONTROL REGISTER

RS[5:0] = 0, 0, 0, 0, 0, 1

Power-On/Reset = 0x0000

Table 67 outlines the bit designations for the register. Bit 15 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

0 (0) 0 (0) 0 (0) DOUT_RDY_DEL (0) CONT_READ (0) DATA_STATUS (0) CS_EN (0) REF_EN (0)

POWER_MODE (0) Mode (0) CLK_SEL (0)

Table 67. ADC Control Register Bit Descriptions

Bits Bit Name Description

15:13 0 These bits must be programmed with a Logic 0 for correct operation.

12 DOUT_RDY_DEL Controls the SCLK inactive edge to DOUT/RDY high time. When DOUT_RDY_DEL is cleared, the delay is

10 ns minimum. When DOUT_RDY_DEL is set, the delay is increased to 100 ns minimum. This function is

useful when CS is tied low (the CS_EN bit is set to 0).

11 CONT_READ Continuous read of the data register. When this bit is set to 1 (and the data register is selected), the serial

interface is configured so that the data register can be continuously read; that is, the contents of the data

goes low to indicate that a conversion is complete. The communications register does not have to be

written to for subsequent data reads. To enable continuous read, the CONT_READ bit is set. To disable

continuous read, write a read data command while the DOUT/ RDY pin is low. While continuous read is

enabled, the ADC monitors activity on the DIN line so that it can receive the instruction to disable

continuous read. Additionally, a reset occurs if 64 consecutive 1s occur on DIN; therefore, hold DIN low

until an instruction is written to the device.

10 DATA_STATUS This bit enables the transmission of the status register contents after each data register read. When

DATA_STATUS is set, the contents of the status register are transmitted along with each data register

read. This function is useful when several channels are selected because the status register identifies the

channel to which the data register value corresponds.

9 CS_EN This bit controls the operation of DOUT/RDY during data read operations.

When CS_EN is cleared, the DOUT pin returns to being a RDY pin within nanoseconds of the SCLK

inactive edge (the delay is determined by the DOUT_RDY_DEL bit).

When set, the DOUT/RDY pin continues to output the LSB of the register being read until CS is taken

high. CS must frame all read operations when CS_EN is set. CS_EN must be set to use the diagnostic

functions SPI_WRITE_ERR, SPI_READ_ERR, and SPI_SCLK_CNT_ERR.

Data Sheet AD7124-4

Rev. D | Page 81 of 93

Bits Bit Name Description

8 REF_EN Internal reference voltage enable. When this bit is set, the internal reference is enabled and available at

the REFOUT pin. When this bit is cleared, the internal reference is disabled.

7:6 POWER_MODE Power Mode Select. These bits select the power mode. The current consumption and output data rate

ranges are dependent on the power mode.

00 = low power.

01 = mid power.

10 = full power.

11 = full power.

5:2 Mode These bits control the mode of operation for ADC. See Table 68.

1:0 CLK_SEL These bits select the clock source for the ADC. Either the on-chip 614.4 kHz clock can be used or an

external clock can be used. The ability to use an external clock allows several AD7124-4 devices to be

synchronized. Also, 50 Hz and 60 Hz rejection is improved when an accurate external clock drives the ADC.

00 = internal 614.4 kHz clock. The internal clock is not available at the CLK pin.

01 = internal 614.4 kHz clock. This clock is available at the CLK pin.

10 = external 614.4 kHz clock.

11 = external clock. The external clock is divided by 4 within the AD7124-4.

Table 68. Operating Modes

Mode

Value Description

0000

Continuous conversion mode (default). In continuous conversion mode, the ADC continuously performs conversions and places

the result in the data register. RDY goes low when a conversion is complete. The user can read these conversions by placing the device

in continuous read mode whereby the conversions are automatically placed on the DOUT line when SCLK pulses are applied.

Alternatively, the user can instruct the ADC to output the conversion by writing to the communications register. After power-on,

a reset, or a reconfiguration of the ADC, the complete settling time of the filter is required to generate the first valid conversion.

Subsequent conversions are available at the selected output data rate, which is dependent on filter choice.

0001 Single conversion mode. When single conversion mode is selected, the ADC powers up and performs a single conversion on the

selected channel. The conversion requires the complete settling time of the filter. The conversion result is placed in the data

active (low) until the data is read or another conversion is performed.

0010 Standby mode. In standby mode, all sections of the AD7124-4 can be powered down except the LDOs. The internal reference, on-

chip oscillator, low-side power switch, and bias voltage generator can be enabled or disabled while in standby mode. The on-

chip registers retain their contents in standby mode.

Any enabled diagnostics remain active when the ADC is in standby mode. The diagnostics can be enabled/disabled while in

standby mode. However, any diagnostics that require the master clock (reference detect, undervoltage/overvoltage detection,

LDO trip tests, memory map CRC, and MCLK counter) must be enabled when the ADC is in continuous conversion mode or idle

mode; these diagnostics do not function if enabled in standby mode.

0011 Power-down mode. In power-down mode, all the AD7124-4 circuitry is powered down, including the current sources, power

switch, burnout currents, bias voltage generator, and clock circuitry. The LDOs are also powered down. In power-down mode, the

on-chip registers do not retain their contents. Therefore, coming out of power-down mode, all registers must be reprogrammed.

0100 Idle mode. In idle mode, the ADC filter and modulator are held in a reset state even though the modulator clocks continue to be

provided.

0101 Internal zero-scale (offset) calibration. An internal short is automatically connected to the input. RDY goes high when the

calibration is initiated and returns low when the calibration is complete. The ADC is placed in idle mode following a calibration.

The measured offset coefficient is placed in the offset register of the selected channel. Select only one channel when zero-scale

calibration is being performed. An internal zero-scale calibration takes a time of one settling period to be performed.

0110 Internal full-scale (gain) calibration. A full-scale input voltage is automatically connected to the selected analog input for this

calibration. RDY goes high when the calibration is initiated and returns low when the calibration is complete. The ADC is placed

in idle mode following a calibration. The measured full-scale coefficient is placed in the gain register of the selected channel. A

full-scale calibration is required each time the gain of a channel is changed to minimize the full-scale error. Select only one

channel when full-scale calibration is being performed. The AD7124-4 is factory calibrated at a gain of 1. Further internal full-scale

calibrations at a gain of 1 are not supported. An internal full-scale calibration (gain > 1) takes a time of four settling periods.

Internal full-scale calibrations cannot be performed in the full power mode. So, if using the full-power mode, select mid or low

power mode for the internal full-scale calibration. This calibration is valid in full power mode as the same reference and gain are

used. When performing internal zero-scale and internal full-scale calibrations, the internal full-scale calibration must be

performed before the internal zero-scale calibration. Therefore, write 0x800000 to the offset register before performing any

internal full-scale calibration, which resets the offset register to its default value.

AD7124-4 Data Sheet

Rev. D | Page 82 of 93

Mode

Value Description

0111 System zero-scale (offset) calibration. Connect the system zero-scale input to the channel input pins of the selected channel. RDY

goes high when the calibration is initiated and returns low when the calibration is complete. The ADC is placed in idle mode

following a calibration. The measured offset coefficient is placed in the offset register of the selected channel. A system zero-

scale calibration is required each time the gain of a channel is changed. Select only one channel when full-scale calibration is

being performed. A system zero-scale calibration takes a time of one settling period to be performed.

1000 System full-scale (gain) calibration. Connect the system full-scale input to the channel input pins of the selected channel. RDY goes

high when the calibration is initiated and returns low when the calibration is complete. The ADC is placed in idle mode following

a calibration. The measured full-scale coefficient is placed in the gain register of the selected channel. A full-scale calibration is

required each time the gain of a channel is changed. Select only one channel when full-scale calibration is being performed. A

system full-scale calibration takes a time of one settling period to be performed.

1001

to1111

Reserved.

DATA REGISTER

RS[5:0] = 0, 0, 0, 0, 1, 0

Power-On/Reset = 0x000000

The conversion result from the ADC is stored in this data register. This is a read-only register. On completion of a read operation from

this register, the RDY bit/pin is set.

IO_CONTROL_1 REGISTER

RS[5:0] = 0, 0, 0, 0, 1, 1

Power-On/Reset = 0x000000

Table 69 outlines the bit designations for the register. Bit 23 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

GPIO_DAT2 (0) GPIO_DAT1 (0) 0 (0) 0 (0) GPIO_CTRL2 (0) GPIO_CTRL1 (0) 0 (0) 0 (0)

PDSW (0) 0 (0) IOUT1 (0) IOUT0 (0)

IOUT1_CH (0) IOUT0_CH (0)

Table 69. IO_CONTROL_1 Register Bit Descriptions

Bits Bit Name Description

23 GPIO_DAT2 Digital Output P2. When GPIO_CTRL2 is set, the GPIO_DAT2 bit sets the value of the P2 general-purpose

output pin. When GPIO_DAT2 is high, the P2 output pin is high. When GPIO_DAT2 is low, the P2 output

pin is low. When the IO_CONTROL_1 register is read, the GPIO_DAT2 bit reflects the status of the P2 pin if

GPIO_CTRL2 is set.

22 GPIO_DAT1 Digital Output P1. When GPIO_CTRL1 is set, the GPIO_DAT1 bit sets the value of the P1 general-purpose

output pin. When GPIO_DAT1 is high, the P1 output pin is high. When GPIO_DAT1 is low, the P1 output

pin is low. When the IO_CONTROL_1 register is read, the GPIO_DAT1 bit reflects the status of the P1 pin if

GPIO_CTRL1 is set.

21, 20 0 This bit must be programmed with a Logic 0 for correct operation.

19 GPIO_CTRL2 Digital Output P2 enable. When GPIO_CTRL2 is set, the digital output P2 is active. When GPIO_CTRL2 is

cleared, the pin functions as an analog input, AIN3.

18 GPIO_CTRL1 Digital Output P1 enable. When GPIO_CTRL1 is set, the digital output P1 is active. When GPIO_CTRL1 is

cleared, the pin functions as an analog input, AIN2.

17, 16 0 This bit must be programmed with a Logic 0 for correct operation.

15 PDSW Bridge power-down switch control bit. Set this bit to close the bridge power-down switch PDSW to

AGND. The switch can sink up to 30 mA. Clear this bit to open the bridge power-down switch. When the

ADC is placed in standby mode, the bridge power-down switch remains active.

This bit must be programmed with a Logic 0 for correct operation.

Data Sheet AD7124-4

Rev. D | Page 83 of 93

Bits Bit Name Description

13:11 IOUT1 These bits set the value of the excitation current for IOUT1.

000 = off.

001 = 50 µA.

010 = 100 µA

011 = 250 µA.

100 = 500 µA.

101 = 750 µA.

110 = 1000 µA

111 = 1000 µA.

10:8 IOUT0 These bits set the value of the excitation current for IOUT0.

000 = off.

001 = 50 µA.

010 = 100 µA

011 = 250 µA.

100 = 500 µA.

101 = 750 µA.

110 = 1000 µA

111 = 1000 µA.

7:4 IOUT1_CH Channel select bits for the excitation current for IOUT1.

0000 = IOUT1 is available on the AIN0 pin.

0001 = IOUT1 is available on the AIN1 pin.

0010 = reserved

0011 = reserved

0100 = IOUT1 is available on the AIN2 pin.

0101 = IOUT1 is available on the AIN3 pin.

0110 = reserved

0111 = reserved

1000 = reserved

1001 = reserved

1010 = IOUT1 is available on the AIN4 pin.

1011 = IOUT1 is available on the AIN5 pin.

1100 = reserved

1101 = reserved

1110 = IOUT1 is available on the AIN6 pin.

0111 = IOUT1 is available on the AIN7 pin.

3:0 IOUT0_CH Channel select bits for the excitation current for IOUT0.

0000 = IOUT0 is available on the AIN0 pin.

0001 = IOUT0 is available on the AIN1 pin.

0010 = reserved

0011 = reserved

0100 = IOUT0 is available on the AIN2 pin.

0101 = IOUT0 is available on the AIN3 pin.

0110 = reserved

0111 = reserved

1000 = reserved

1001 = reserved

1010 = IOUT0 is available on the AIN4 pin.

1011 = IOUT0 is available on the AIN5 pin.

1100 = reserved

1101 = reserved

1110 = IOUT0 is available on the AIN6 pin.

1111 = IOUT0 is available on the AIN7 pin.

AD7124-4 Data Sheet

Rev. D | Page 84 of 93

IO_CONTROL_2 REGISTER

RS[5:0] = 0, 0, 0, 1, 0, 0

Power-On/Reset = 0x0000

Table 70 outlines the bit designations for the register. Bit 15 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit. The internal bias voltage can be enabled on multiple channels.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

VBIAS7 (0) VBIAS6 (0) 0 (0) 0 (0) VBIAS5 (0) VBIAS4 (0) 0 (0) 0 (0)

0 (0) 0 (0) VBIAS3 (0) VBIAS2 (0) 0 (0) 0 (0) VBIAS1 (0) VBIAS0 (0)

Table 70. IO_CONTROL_2 Register Bit Descriptions

Bits Bit Name Description

15 VBIAS7 Enable the bias voltage on the AIN7 channel. When set, the internal bias voltage is available on AIN7.

14 VBIAS6 Enable the bias voltage on the AIN6 channel. When set, the internal bias voltage is available on AIN6.

13, 12 0 This bit must be programmed with a Logic 0 for correct operation.

11 VBIAS5 Enable the bias voltage on the AIN5 channel. When set, the internal bias voltage is available on AIN5.

10 VBIAS4 Enable the bias voltage on the AIN4 channel. When set, the internal bias voltage is available on AIN4.

9, 8, 7, 6 0 This bit must be programmed with a Logic 0 for correct operation.

5 VBIAS3 Enable the bias voltage on the AIN3 channel. When set, the internal bias voltage is available on AIN3.

4 VBIAS2 Enable the bias voltage on the AIN2 channel. When set, the internal bias voltage is available on AIN2.

3, 2 0 This bit must be programmed with a Logic 0 for correct operation.

1 VBIAS1 Enable the bias voltage on the AIN1 channel. When set, the internal bias voltage is available on AIN1.

0 VBIAS0 Enable the bias voltage on the AIN0 channel. When set, the internal bias voltage is available on AIN0.

ID REGISTER

RS[5:0] = 0, 0, 0, 1, 0, 1

Power-On/Reset = 0x04 (AD7124-4)/0x06 (AD7124-4 B Grade)

The identification number for the AD7124-4 is stored in the ID register. This is a read only register.

ERROR REGISTER

RS[5:0] = 0, 0, 0, 1, 1, 0

Power-On/Reset = 0x000000

Diagnostics, such as checking overvoltages and checking the SPI interface, are included on the AD7124-4. The error register contains the

flags for the different diagnostic functions. The functions are enabled and disabled using the ERROR_EN register.

Table 71 outlines the bit designations for the register. Bit 23 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

0 (0) LDO_CAP_ERR

(0)

ADC_CAL_ERR

(0)

ADC_CONV_ERR

(0)

ADC_SAT_ERR

(0)

AINP_OV_ERR

(0)

AINP_UV_ERR (0) AINM_OV_ERR (0) AINM_UV_ERR

(0)

REF_DET_ERR

(0)

0 (0) DLDO_PSM_ERR

(0)

0 (0)

ALDO_PSM_ERR

(0)

SPI_IGNORE_ERR

(0)

SPI_SCLK_CNT_ERR

(0)

SPI_READ_ERR

(0)

SPI_WRITE_ERR

(0)

SPI_CRC_ERR

(0)

MM_CRC_ERR

(0)

ROM_CRC_ERR

(0)

Data Sheet AD7124-4

Rev. D | Page 85 of 93

Table 71. Error Register Bit Descriptions

Bits Bit Name Description

23:20 0 These bits must be programmed with a Logic 0 for correct operation.

19 LDO_CAP_ERR Analog/digital LDO decoupling capacitor check. This flag is set if the decoupling capacitors required for the

analog and digital LDOs are not connected to the AD7124-4.

18 ADC_CAL_ERR Calibration check. If a calibration is initiated but not completed, this flag is set to indicate that an error

occurred during the calibration. The associated calibration register is not updated.

17 ADC_CONV_ERR This bit indicates whether a conversion is valid. This flag is set if an error occurs during a conversion.

16 ADC_SAT_ERR ADC saturation flag. This flag is set if the modulator is saturated during a conversion.

15 AINP_OV_ERR Overvoltage detection on AINP.

AINP_UV_ERR

Undervoltage detection on AINP.

13 AINM_OV_ERR Overvoltage detection on AINM.

12 AINM_UV_ERR Undervoltage detection on AINM.

11 REF_DET_ERR Reference detection. This flag indicates when the external reference being used by the ADC is open circuit or

less than 0.7 V.

10 0 This bit must be programmed with a Logic 0 for correct operation.

9 DLDO_PSM_ERR Digital LDO error. This flag is set if an error is detected with the digital LDO.

This bit must be programmed with a Logic 0 for correct operation.

7 ALDO_PSM_ERR Analog LDO error. This flag is set if an error is detected with the analog LDO voltage.

6 SPI_IGNORE_ERR When a CRC check of the internal registers is being performed, the on-chip registers cannot be written to.

User instructions are ignored by the ADC. This bit is set when the CRC check of the registers is occurring. The

bit is cleared when the check is complete; write operations can only be performed then.

SPI_SCLK_CNT_ERR

All serial communications are some multiple of eight bits. This bit is set when the number of SCLK cycles is

not a multiple of eight.

4 SPI_READ_ERR This bit is set when an error occurs during an SPI read operation.

3 SPI_WRITE_ERR This bit is set when an error occurs during an SPI write operation.

2 SPI_CRC_ERR This bit is set if an error occurs in the CRC check of the serial communications.

1 MM_CRC_ERR Memory map error. A CRC calculation is performed on the memory map each time that the registers are

written to. Following this, periodic CRC checks are performed on the on-chip registers. If the register

contents have changed, the MM_CRC_ERR bit is set.

0 ROM_CRC_ERR ROM error. A CRC calculation is performed on the ROM contents (contains the default register values) on

power-up. If the contents have changed, the ROM_CRC_ERR bit is set.

ERROR_EN REGISTER

RS[5:0] = 0, 0, 0, 1, 1, 1

Power-On/Reset = 0x000040

All the diagnostic functions can be enabled or disabled by setting the appropriate bits in this register.

Table 72 outlines the bit designations for the register. Bit 23 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit.

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

0 (0) MCLK_

CNT_

EN (0)

LDO_CAP_CHK_

TEST_EN (0)

LDO_CAP_CHK (0) ADC_CAL_ERR_

EN (0)

ADC_CONV_

ERR_

EN (0)

ADC_SAT_

ERR_EN (0)

AINP_OV_

ERR_EN (0)

AINP_UV_

ERR_EN (0)

AINM_OV_ERR_

EN (0)

AINM_UV_

ERR_EN (0)

REF_DET_ER

R_EN (0)

DLDO_PSM_

TRIP_TEST_EN

(0)

DLDO_PSM_

ERR_EN (0)

ALDO_PSM_

TRIP_TEST_EN (0)

ALDO_

PSM_

ERR_EN (0)

SPI_

IGNORE_

ERR_EN (0)

SPI_SCLK_CNT_

ERR_EN (0)

SPI_READ_

ERR_EN (0)

SPI_WRITE_

ERR_EN (0)

SPI_CRC_ERR_

EN (0)

MM_CRC_ERR_

ROM_CRC_ERR_EN

AD7124-4 Data Sheet

Rev. D | Page 86 of 93

Table 72. ERROR_EN Register Bit Descriptions

Bits Bit Name Description

23 0 This bit must be programmed with a Logic 0 for correct operation.

22 MCLK_CNT_EN Master clock counter. When this bit is set, the master clock counter is enabled and the result is

reported via the MCLK_COUNT register. The counter monitors the master clock being used by the

ADC. If an external clock is the clock source, the MCLK counter monitors this external clock.

Similarly, if the on-chip oscillator is selected as the clock source to the ADC, the MCLK counter

monitors the on-chip oscillator.

21 LDO_CAP_CHK_TEST_EN Test of analog/digital LDO decoupling capacitor check. When this bit is set, the decoupling

capacitor is internally disconnected from the LDO, forcing a fault condition. This allows the user to

test the circuitry which is used for the analog and digital LDO decoupling capacitor check.

20:19 LDO_CAP_CHK Analog/digital LDO decoupling capacitor check. These bits enable the capacitor check. When a

check is enabled, the ADC checks for the presence of the external decoupling capacitor on the

selected supply. When the check is complete, the LDO_CAP_CHK bits are both reset to 0.

00 = check is not enabled.

01 = check the analog LDO capacitor.

10 = check the digital LDO capacitor.

11 = check is not enabled.

18 ADC_CAL_ERR_EN When this bit is set, the calibration fail check is enabled.

17 ADC_CONV_ERR_EN When this bit is set, the conversions are monitored and the ADC_CONV_ERR bit is set when a

conversion fails.

16 ADC_SAT_ERR_EN When this bit is set, the ADC modulator saturation check is enabled.

15 AINP_OV_ERR_EN When this bit is set, the overvoltage monitor on all enabled AINP channels is enabled.

14 AINP_UV_ERR_EN When this bit is set, the undervoltage monitor on all enabled AINP channels is enabled.

13 AINM_OV_ERR_EN When this bit is set, the overvoltage monitor on all enabled AINM channels is enabled.

12 AINM_UV_ERR_EN When this bit is set, the undervoltage monitor on all enabled AINM channels is enabled.

11 REF_DET_ERR_EN When this bit is set, any external reference being used by the ADC is continuously monitored. An

error is flagged if the external reference is open circuit or has a value of less than 0.7 V.

DLDO_PSM_TRIP_TEST_EN

Checks the test mechanism that monitors the digital LDO. When this bit is set, the input to the test

circuit is tied to DGND instead of the LDO output. Set the DLDO_PSM_ERR bit in the error register.

9 DLDO_PSM_ERR_ERR When this bit is set, the digital LDO voltage is continuously monitored. The DLDO_PSM_ERR bit in

the error register is set if the voltage being output from the digital LDO is outside specification.

8 ALDO_PSM_TRIP_TEST_EN Checks the test mechanism that monitors the analog LDO. When this bit is set, the input to the

test circuit is tied to AVSS instead of the LDO output. Set the ALDO_PSM_ERR bit in the error

7 ALDO_PSM_ERR_EN When this bit is set, the analog LDO voltage is continuously monitored. The ALDO_PSM_ERR bit in

the error register is set if the voltage being output from the analog LDO is outside specification.

6 SPI_IGNORE_ERR_EN When a CRC check of the internal registers is being performed, the on-chip registers cannot be

accessed. User write instructions are ignored by the ADC. Set this bit so that the SPI_IGNORE_ERR

bit in the error register informs the user when write operations must not be performed.

5 SPI_SCLK_CNT_ERR_EN When this bit is set, the SCLK counter is enabled. All read and write operations to the ADC are

multiples of eight bits. For every serial communication, the SCLK counter counts the number of

SCLK pulses. CS must be used to frame each read and write operation. If the number of SCLK

pulses used during a communication is not a multiple of eight, the SPI_SCLK_CNT_ERR bit in the

error register is set. For example, a glitch on the SCLK pin during a read or write operation can be

interpreted as an SCLK pulse. In this case, the SPI_SCLK_CNT_ERR bit is set as there is an excessive

number of SCLK pulses detected. CS_EN in the ADC_CONTROL register must be set to 1 when the

SCLK counter function is being used.

4 SPI_READ_ERR_EN When this bit is set, the SPI_READ_ERR bit in the error register is set when an error occurs during a

read operation. An error occurs if the user attempts to read from invalid addresses. CS_EN in the

ADC_CONTROL register must be set to 1 when the SPI read check function is being used.

3 SPI_WRITE_ERR_EN When this bit is set, the SPI_WRITE_ERR bit in the error register is set when an error occurs during a

write operation. An error occurs if the user attempts to write to invalid addresses or write to read-

only registers. CS_EN in the ADC_CONTROL register must be set to 1 when the SPI write check

function is being used.

Data Sheet AD7124-4

Rev. D | Page 87 of 93

Bits Bit Name Description

2 SPI_CRC_ERR_EN This bit enables a CRC check of all read and write operations. The SPI_CRC_ERR bit in the error

from the AD7124-4.

1 MM_CRC_ERR_EN When this bit is set, a CRC calculation is performed on the memory map each time that the

registers are written to. Following this, periodic CRC checks are performed on the on-chip

registers. If the register contents have changed, the MM_CRC_ERR bit is set.

0 ROM_CRC_ERR_EN When this bit is set, a CRC calculation is performed on the ROM contents on power-on. If the ROM

contents have changed, the ROM_CRC_ERR bit is set.

MCLK_COUNT REGISTER

RS[5:0] = 0, 0, 1, 0, 0, 0

Power-On/Reset = 0x00

The master clock frequency can be monitored using this register.

Table 73 outlines the bit designations for the register. Bit 7 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

MCLK_COUNT (0)

Table 73. MCLK_COUNT Register Bit Descriptions

Bits Bit Name Description

7:0

MCLK_COUNT

This register allows the user to determine the frequency of the internal/external oscillator. Internally, a clock counter

increments every 131 pulses of the sampling clock (614.4 kHz in full power mode, 153.6 kHz in mid power mode,

and 768 kHz in low power mode). The 8-bit counter wraps around on reaching its maximum value. The counter

output is read back via this register. Note that the incrementation of the register is asynchronous to the register

read. If a register read coincides with the register incrementation, it is possible to read an invalid value. To prevent

this, read the register four times, then read the register four times again at a later point. By reading four values, it is

possible to identify the correct register value at the start and end of the timing instants.

CHANNEL REGISTERS

RS[5:0] = 0, 0, 1, 0, 0, 1 to 0, 1, 1, 0, 0, 0

Power-On/Reset = 0x8001 for CHANNEL_0; all other channel registers are set to 0x0001

Sixteen channel registers are included on the AD7124-4, CHANNEL_0 to CHANNEL_15. The channel registers begin at Address 0x09

(CHANNEL_0) and end at Address 0x18 (CHANNEL_15). Via each register, the user can configure the channel (AINP input and AINM

input), enable or disable the channel, and select the setup. The setup is selectable from eight different options defined by the user. When

the ADC converts, it automatically sequences through all enabled channels. This allows the user to sample some channels multiple times

in a sequence, if required. In addition, it allows the user to include diagnostic functions in a sequence also.

Table 74 outlines the bit designations for the register. Bit 15 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

Enable (1) Setup (0) 0 (0) AINP[4:3](00)

AINP[2:0](000) AINM[4:0](00001)

Table 74. Channel Register Bit Descriptions

Bits

Bit Name

Description

15 Enable Channel enable bit. Setting this bit enables the device channel for the conversion sequence. By default, only the

enable bit for Channel 0 is set. The order of conversions starts with the lowest enabled channel, then cycles

through successively higher channel numbers, before wrapping around to the lowest channel again.

When the ADC writes a result for a particular channel, the four LSBs of the status register are set to the channel

number, 0 to 15. This allows the channel the data corresponds to be identified. When the DATA_STATUS bit in the

ADC_CONTROL register is set, the contents of the status register are appended to each conversion when it is

read. Use this function when several channels are enabled to determine to which channel the conversion value

read corresponds.

AD7124-4 Data Sheet

Rev. D | Page 88 of 93

Bits Bit Name Description

14:12 Setup Setup select. These bits identify which of the eight setups are used to configure the ADC for this channel. A setup

comprises a set of four registers: analog configuration, output data rate/filter selection, offset register, and gain

all active channels. Alternatively, up to eight channels can be configured differently.

11:10 0 These bits must be programmed with a Logic 0 for correct operation.

9:5 AINP[4:0] Positive analog input AINP input select. These bits select which of the analog inputs is connected to the positive

input for this channel.

00000 = AIN0 (default).

00001 = AIN1.

00010 = AIN2.

00011 = AIN3.

00100 = AIN4.

00101 = AIN5.

00110 = AIN6.

00111 = AIN7.

01000 to 01111 = reserved.

10000 = temperature sensor.

10001 = AVSS.

10010 = internal reference.

10011 = DGND.

10100 = (AVDD − AVSS)/6+. Use in conjunction with (AVDD − AVSS)/6− to monitor supply AVDD − AVSS.

10101 = (AV

− AV

)/6−. Use in conjunction with (AV

− AV

)/6+ to monitor supply AV

− AV

10110 = (IOVDD − DGND)/6+. Use in conjunction with (IOVDD − DGND)/6− to monitor IOVDD − DGND.

10111 = (IOVDD − DGND)/6−. Use in conjunction with (IOVDD − DGND)/6+ to monitor IOVDD − DGND.

11000 = (ALDO − AVSS)/6+. Use in conjunction with (ALDO − AVSS)/6− to monitor the analog LDO.

11001 = (ALDO − AVSS)/6−. Use in conjunction with (ALDO − AVSS)/6+ to monitor the analog LDO.

11010 = (DLDO − DGND)/6+. Use in conjunction with (DLDO − DGND)/6− to monitor the digital LDO.

11011 = (DLDO − DGND)/6−. Use in conjunction with (DLDO − DGND)/6+ to monitor the digital LDO.

11100 = V_20MV_P. Use in conjunction with V_20MV_M to apply a 20 mV p-p signal to the ADC.

11101 = V_20MV_M. Use in conjunction with V_20MV_P to apply a 20 mV p-p signal to the ADC.

11110 = reserved.

11111 = reserved.

4:0 AINM[4:0] Negative analog input AINM input select. These bits select which of the analog inputs is connected to the

negative input for this channel.

00000 = AIN0.

00001 = AIN1 (default).

00010 = AIN2.

00011 = AIN3.

00100 = AIN4.

00101 = AIN5.

00110 = AIN6.

00111 = AIN7.

01000 to 01111 = reserved.

10000 = temperature sensor.

10001 = AVSS.

10010 = internal reference.

10011 = DGND.

10100 = (AVDD − AVSS)/6+. Use in conjunction with (AVDD − AVSS)/6− to monitor supply AVDD − AVSS.

10101 = (AVDD − AVSS)/6−. Use in conjunction with (AVDD − AVSS)/6+ to monitor supply AVDD − AVSS.

10110 = (IOVDD − DGND)/6+. Use in conjunction with (IOVDD − DGND)/6− to monitor IOVDD − DGND.

10111 = (IOVDD − DGND)/6−. Use in conjunction with (IOVDD − DGND)/6+ to monitor IOVDD − DGND.

11000 = (ALDO − AVSS)/6+. Use in conjunction with (ALDO − AVSS)/6− to monitor the analog LDO.

11001 = (ALDO − AVSS)/6−. Use in conjunction with (ALDO − AVSS)/6+ to monitor the analog LDO.

11010 = (DLDO − DGND)/6+. Use in conjunction with (DLDO − DGND)/6− to monitor the digital LDO.

Data Sheet AD7124-4

Rev. D | Page 89 of 93

Bits Bit Name Description

11011 = (DLDO − DGND)/6−. Use in conjunction with (DLDO − DGND)/6+ to monitor the digital LDO.

11100 = V_20MV_P. Use in conjunction with V_20MV_M to apply a 20 mV p-p signal to the ADC.

11101 = V_20MV_M. Use in conjunction with V_20MV_P to apply a 20 mV p-p signal to the ADC.

11110 = reserved.

11111 = reserved.

CONFIGURATION REGISTERS

RS[5:0] = 0, 1, 1, 0, 0, 1 to 1, 0, 0, 0, 0, 0

Power-On/Reset = 0x0860

The AD7124-4 has eight configuration registers, CONFIG_0 to CONFIG_7. Each configuration register is associated with a setup;

CONFIG_x is associated with Setup x. In the configuration register, the reference source, polarity, and reference buffers are configured.

Table 75 outlines the bit designations for the register. Bit 15 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

0 (0) Bipolar (1) Burnout (0) REF_BUFP (0)

REF_BUFM (0) AIN_BUFP (1) AIN_BUFM (1) REF_SEL (0) PGA (0)

Table 75. Configuration Register Bit Descriptions

Bits Bit Name Description

15:12 0 These bits must be programmed with a Logic 0 for correct operation.

11 Bipolar Polarity select bit. When this bit is set, bipolar operation is selected. When this bit is cleared, unipolar operation is

selected.

10:9

Burnout

These bits select the magnitude of the sensor burnout detect current source.

00 = burnout current source off (default).

01 = burnout current source on, 0.5 μA.

10 = burnout current source on, 2 μA.

11 = burnout current source on, 4 μA.

8 REF_BUFP Buffer enable on REFINx(+). When this bit is set, the positive reference input (internal or external) is buffered. When

this bit is cleared, the positive reference input (internal or external) is unbuffered.

7 REF_BUFM Buffer enable on REFINx(−). When this bit is set, the negative reference input (internal or external) is buffered. When

this bit is cleared, the negative reference input (internal or external) is unbuffered.

AIN_BUFP

Buffer enable on AINP. When this bit is set, the selected positive analog input pin is buffered. When this bit is cleared,

the selected positive analog input pin is unbuffered.

5 AIN_BUFM Buffer enable on AINM. When this bit is set, the selected negative analog input pin is buffered. When this bit is

cleared, the selected negative analog input pin is unbuffered.

4:3 REF_SEL Reference source select bits. These bits select the reference source to use when converting on any channels using

this configuration register.

00 = REFIN1(+)/REFIN1(−).

01 = REFIN2(+)/REFIN2(−).

10 = internal reference.

11 = AVDD.

2:0 PGA Gain select bits. These bits select the gain to use when converting on any channels using this configuration register.

PGA Gain Input Range When VREF = 2.5 V (Bipolar Mode)

000 1 ±2.5 V

001 2 ±1.25 V

010 4 ± 625 mV

011 8 ±312.5 mV

100 16 ±156.25 mV

101 32 ±78.125 mV

110 64 ±39.06 mV

111

128

±19.53 mV

AD7124-4 Data Sheet

Rev. D | Page 90 of 93

FILTER REGISTERS

RS[5:0] = 1, 0, 0, 0, 0, 1 to 1, 0, 1, 0, 0, 0

Power-On/Reset = 0x060180

The AD7124-4 has eight filter registers, FILTER_0 to FILTER_7. Each filter register is associated with a setup; FILTER_x is associated

with Setup x. In the filter register, the filter type and output word rate are set.

Table 76 outlines the bit designations for the register. Bit 15 is the first bit of the data stream. The number in parentheses indicates the

power-on/reset default status of that bit.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

Filter (0) REJ60 (0) POST_FILTER (0) SINGLE_CYCLE (0)

0 (0) FS[10:8] (0)

FS[7:0] (0)

Table 76. Filter Register Bit Descriptions

Bits Bit Name Description

23:21 Filter Filter type select bits. These bits select the filter type.

000 = sinc4 filter (default).

001 = reserved.

010 = sinc3 filter.

011 = reserved.

100 = fast settling filter using the sinc4 filter. The sinc4 filter is followed by an averaging block, which results

in a settling time equal to the conversion time. In full power and mid power modes, averaging by 16 occurs

whereas averaging by 8 occurs in low power mode.

101 = fast settling filter using the sinc3 filter. The sinc3 filter is followed by an averaging block, which results

in a settling time equal to the conversion time. In full power and mid power modes, averaging by 16 occurs

whereas averaging by 8 occurs in low power mode.

110 = reserved.

111 = post filter enabled. The AD7124-4 includes several post filters, selectable using the POST_FILTER bits.

The post filters have single cycle settling, the settling time being considerably better than a simple

sinc3/sinc4 filter. These filters offer excellent 50 Hz and60 Hz rejection.

20 REJ60 When this bit is set, a first order notch is placed at 60 Hz when the first notch of the sinc filter is at 50 Hz.

This allows simultaneous 50 Hz and 60 Hz rejection.

19:17 POST_FILTER Post filter type select bits. When the filter bits are set to 1, the sinc3 filter is followed by a post filter which

offers good 50 Hz and 60 Hz rejection at output data rates that have zero latency approximately.

POST_FILTER Output Data Rate (SPS) Rejection at 50 Hz and 60 Hz ± 1 Hz (dB)

000 Reserved Not applicable

001 Reserved Not applicable

010 27.27 47

011 25 62

100 Reserved Not applicable

101 20 86

110 16.7 92

111 Reserved Not applicable

16 SINGLE_CYCLE Single cycle conversion enable bit. When this bit is set, the AD7124-4 settles in one conversion cycle so that

it functions as a zero latency ADC. This bit has no effect when multiple analog input channels are enabled

or when the single conversion mode is selected. When the fast filters are used, this bit has no effect.

15:11

These bits must be programmed with a Logic 0 for correct operation.

10:0 FS[10:0] Filter output data rate select bits. These bits set the output data rate of the sinc3 and sinc4 filters as well as

the fast settling filters. In addition, they affect the position of the first notch of the filter and the cutoff

frequency. In association with the gain selection, they also determine the output noise and, therefore, the

effective resolution of the device (see noise tables). FS can have a value from 1 to 2047.

Data Sheet AD7124-4

Rev. D | Page 91 of 93

OFFSET REGISTERS

RS[5:0] = 1, 0, 1, 0, 0, 1 to 1, 1, 0, 0, 0, 0

Power-On/Reset = 0x800000

The AD7124-4 has eight offset registers, OFFSET_0 to OFFSET_7.

Each offset register is associated with a setup; OFFSET_x is

associated with Setup x. The offset registers are 24-bit registers

and hold the offset calibration coefficient for the ADC and its

power-on reset value is 0x800000. Each of these registers is a

read/write register. These registers are used in conjunction with

the associated gain register to form a register pair. The power-

on reset value is automatically overwritten if an internal or

system zero-scale calibration is initiated by the user. The ADC

must be placed in standby mode or idle mode when writing to

the offset registers.

GAIN REGISTERS

RS[5:0] = 1, 1, 0, 0, 0, 1 to 1, 1, 1, 0, 0, 0

Power-On/Reset = 0x5XXXXX

The AD7124-4 has eight gain registers, GAIN_0 to GAIN_7. Each

gain register is associated with a setup; GAIN_x is associated

with Setup x. The gain registers are 24-bit registers and hold the

full-scale calibration coefficient for the ADC. The AD7124-4 is

factory calibrated to a gain of 1. The gain register contains this

factory generated value on power-on and after a reset. The gain

registers are read/write registers. However, when writing to the

registers, the ADC must be placed in standby mode or idle

mode. The default value is automatically overwritten if an

internal or system full-scale calibration is initiated by the user

or the full-scale registers are written to.

AD7124-4 Data Sheet

Rev. D | Page 92 of 93

OUTLINE DIMENSIONS

0.50

0.40

0.30

10-20-2017-C

0.50

BSC

BOTTOM VIEWTOP VIEW

TOP VIEW

PIN 1

INDICATOR 32

EXPOSED

PAD

SEATING

PLANE

0.05 M AX

0.02 NO M

0.20 REF

COPLANARITY

0.08

0.30

0.25

0.18

5.10

5.00 SQ

4.90

0.80

0.75

0.70

FOR PRO P E R CONNECTION O F

THE EXPOSED PAD, REFER TO

THE PIN CO NFI GURATIO N AND

FUNCTION DES CRIPT IO NS

SECTION OF THIS DATA SHEET.

0.20 M IN

3.75

3.60 SQ

3.55

COM P LIANT T O JEDEC S TANDARDS M O-220-WHHD-5

PKG-004570

PIN 1

INDIC ATOR AREA O P TIONS

(SEE DETAIL A)

DETAIL A

(JEDEC 95)

Figure 133. 32-Lead Lead Frame Chip Scale Package [LFCSP]

5 mm × 5 mm Body and 0.75 mm Package Height

(CP-32-12)

Dimensions shown in millimeters

24 13

121

6.40 BSC

4.50

4.40

4.30

PIN 1

7.90

7.80

7.70

0.15

0.05

0.30

0.19

0.65

BSC 1.20

MAX

0.20

0.09

0.75

0.60

0.45

8°

0°

SEATING

PLANE

0.10 COPLANARITY

COMPLIANT TO JEDEC STANDARDS MO-153-AD

Figure 134. 24-Lead Thin Shrink Small Outline Package [TSSOP]

(RU-24)

Dimensions shown in millimeters

Data Sheet AD7124-4

Rev. D | Page 93 of 93

0.50

BSC

BOTTOM VIEW

TOP VIEW

PIN 1

INDICATOR

0.05 M AX

0.02 NO M

0.20 REF

COPLANARITY

0.08

0.30

0.25

0.18

5.10

5.00 SQ

4.90

1.00

0.95

0.85

0.50

0.40

0.30

0.20 M IN

3.70

3.60 SQ

3.50

01-16-2016-A

COM P LIANT T O JEDEC S TANDARDS M O-220-VHHD-5.

PKG-004754/005209

SEATING

PLANE

EXPOSED

PAD

END VIEW

PIN 1

INDIC ATOR AREA O P TIONS

(SEE DETAIL A)

DETAIL A

(JEDEC 95)

FOR PRO P E R CONNECTION O F

THE EXPOSED PAD, REFER TO

THE PIN CO NFI GURATIO N AND

FUNCTION DES CRIPT IO NS

SECTION OF THIS DATA SHEET.

Figure 135. 32-Lead Lead Frame Chip Scale Package [LFCSP]

5 mm × 5 mm Body and 0.95 mm Package Height

(CP-32-30)

Dimensions shown in millimeters

ORDERING GUIDE

Model1 Temperature Range Package Description Package Option

AD7124-4BCPZ −40°C to +125°C 32-Lead Lead Frame Chip Scale Package [LFCSP] CP-32-12

AD7124-4BCPZ-RL −40°C to +125°C 32-Lead Lead Frame Chip Scale Package [LFCSP] CP-32-12

AD7124-4BCPZ-RL7 −40°C to +125°C 32-Lead Lead Frame Chip Scale Package [LFCSP] CP-32-12

AD7124-4BBCPZ −40°C to +125°C 32-Lead Lead Frame Chip Scale Package [LFCSP] CP-32-30

AD7124-4BBCPZ-RL −40°C to +125°C 32-Lead Lead Frame Chip Scale Package [LFCSP] CP-32-30

AD7124-4BBCPZ-RL7 −40°C to +125°C 32-Lead Lead Frame Chip Scale Package [LFCSP] CP-32-30

AD7124-4BRUZ −40°C to +125°C 24-Lead Thin Shrink Small Outline Package [TSSOP] RU-24

AD7124-4BRUZ-RL −40°C to +125°C 24-Lead Thin Shrink Small Outline Package [TSSOP] RU-24

AD7124-4BRUZ-RL7 −40°C to +125°C 24-Lead Thin Shrink Small Outline Package [TSSOP] RU-24

EVAL-AD7124-4SDZ Evaluation Board

EVAL-SDP-CB1Z

Evaluation Controller Board

1 Z = RoHS Compliant Part.

registered trademarks are the property of their respective owners.

D13197-0-6/18(D)