4.8 kHz Ultralow Noise 24-Bit
Sigma-Delta ADC with PGA
AD7190
Rev. B
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700 www.analog.com
Fax: 781.461.3113 ©2008–2009 Analog Devices, Inc. All rights reserved.
FEATURES
RMS noise: 8.5 nV @ 4.7 Hz (gain = 128)
16 noise free bits @ 2.4 kHz (gain = 128)
Up to 22.5 noise free bits (gain = 1)
Offset drift: 5 nV/°C
Gain drift: 1 ppm/°C
Specified drift over time
2 differential/4 pseudo differential input channels
Automatic channel sequencer
Programmable gain (1 to 128)
Output data rate: 4.7 Hz to 4.8 kHz
Internal or external clock
Simultaneous 50 Hz/60 Hz rejection
4 general-purpose digital outputs
Power supply
AVDD: 4.75 V to 5.25 V
DVDD: 2.7 V to 5.25 V
Current: 6 mA
Temperature range: –40°C to +105°C
Interface
3-wire serial
SPI, QSPI™, MICROWIRE™, and DSP compatible
Schmitt trigger on SCLK
APPLICATIONS
Weigh scales
Strain gauge transducers
Pressure measurement
Temperature measurement
Chromatography
PLC/DCS analog input modules
Data acquisition
Medical and scientific instrumentation
GENERAL DESCRIPTION
The AD7190 is a low noise, complete analog front end for high
precision measurement applications. It contains a low noise,
24-bit sigma-delta (∑-∆) analog-to-digital converter (ADC).
The on-chip low noise gain stage means that signals of small
amplitude can be interfaced directly to the ADC.
The device can be configured to have two differential inputs or
four pseudo differential inputs. The on-chip channel sequencer
allows several channels to be enabled, and the AD7190
sequentially converts on each enabled channel. This simplifies
communication with the part. The on-chip 4.92 MHz clock can
be used as the clock source to the ADC or, alternatively, an
external clock or crystal can be used. The output data rate from
the part can be varied from 4.7 Hz to 4.8 kHz.
The device has two digital filter options. The choice of filter
affects the rms noise/noise-free resolution at the programmed
output data rate, the settling time, and the 50 Hz/60 Hz
rejection. For applications that require all conversions to be
settled, the AD7190 includes a zero latency feature.
The part operates with 5 V analog power supply and a digital
power supply from 2.7 V to 5.25 V. It consumes a current of
6 mA. It is housed in a 24-lead TSSOP package.
FUNCTIONAL BLOCK DIAGRAM
MCLK1 MCLK2 P0/REFIN2(–) P1/REFIN2(+)
DV
DD
DGND REFIN1(+) REFIN1(–)
AIN1
AIN2
AIN3
AIN4
A
INCOM
BPDSW
AGND
AD7190
REFERENCE
DETECT
SERIAL
INTERFACE
AND
CONTROL
LOGIC
TEMP
SENSOR
CLOCK
CIRCUITRY
DOUT/RDY
DIN
SCLK
CS
SYNC
P3
P2
AV
DD
AGND
Σ-Δ
ADC
PGA
MUX
07640-001
Figure 1.
AD7190
Rev. B | Page 2 of 40
TABLE OF CONTENTS
Features .............................................................................................. 1
Applications ....................................................................................... 1
General Description ......................................................................... 1
Functional Block Diagram .............................................................. 1
Revision History ............................................................................... 2
Specifications ..................................................................................... 3
Timing Characteristics ................................................................ 7
Circuit and Timing Diagrams ..................................................... 7
Absolute Maximum Ratings ............................................................ 9
Thermal Resistance ...................................................................... 9
ESD Caution .................................................................................. 9
Pin Configuration and Function Descriptions ........................... 10
Typical Performance Characteristics ........................................... 12
RMS Noise and Resolution ............................................................ 15
Sinc4 Chop Disabled ................................................................... 15
Sinc3 Chop Disabled ................................................................... 16
Sinc4 Chop Enabled .................................................................... 17
Sinc3 Chop Enabled .................................................................... 18
On-Chip Registers .......................................................................... 19
Communications Register ......................................................... 19
Status Register ............................................................................. 20
Mode Register ............................................................................. 20
Configuration Register .............................................................. 22
Data Register ............................................................................... 24
ID Register ................................................................................... 24
GPOCON Register ..................................................................... 24
Offset Register ............................................................................. 25
Full-Scale Register ...................................................................... 25
ADC Circuit Information .............................................................. 26
Overview ..................................................................................... 26
Filter, Output Data Rate, Settling Time ................................... 26
Digital Interface .......................................................................... 29
Circuit Description......................................................................... 33
Analog Input Channel ............................................................... 33
PGA .............................................................................................. 33
Bipolar/Unipolar Configuration .............................................. 33
Data Output Coding .................................................................. 33
Clock ............................................................................................ 33
Burnout Currents ....................................................................... 34
Reference ..................................................................................... 34
Reference Detect ......................................................................... 34
Reset ............................................................................................. 34
System Synchronization ............................................................ 35
Temperature Sensor ................................................................... 35
Bridge Power-Down Switch ...................................................... 35
Logic Outputs ............................................................................. 35
Enable Parity ............................................................................... 36
Calibration ................................................................................... 36
Grounding and Layout .............................................................. 37
Applications Information .............................................................. 38
Weigh Scales ................................................................................ 38
Outline Dimensions ....................................................................... 39
Ordering Guide .......................................................................... 39
REVISION HISTORY
5/09—Rev. A to Rev. B
Changes to Table 3 ............................................................................ 9
5/09—Rev. 0 to Rev. A
Changes to Table 1 ............................................................................ 3
Changes to Table 3 and Table 4 ....................................................... 9
Changes to Table 5 .......................................................................... 10
Changes to Table 6 and Table 7 ..................................................... 15
Changes to Status Register Section .............................................. 20
Changes to Table 17 ........................................................................ 21
Changes to Table 19 ........................................................................ 23
Changes to Table 20 ........................................................................ 24
Added ID Register Section ............................................................ 24
Changes to Table 21 ....................................................................... 25
Changes to Filter, Output Data Rate, Settling Time Section .... 26
Changes to Continuous Conversion Mode Section ................... 31
Changes to Analog Input Channel and Bipolar/Unipolar
Configuration Sections .................................................................. 33
Changes to Burnout Currents, Reference, Reference Detect, and
Reset Sections .................................................................................. 34
Changes to Temperature Sensor Section ..................................... 35
Changes to Calibration Section .................................................... 36
Changes to Grounding and Layout Section ................................ 37
Changes to Weigh Scales Section ................................................. 38
Changes to Ordering Guide .......................................................... 39
10/08—Revision 0—Initial Version
AD7190
Rev. B | Page 3 of 40
SPECIFICATIONS
AVDD = 4.75 V to 5.25 V, DVDD = 2.7 V to 5.25 V, AGND = DGND = 0 V, REFINx(+) = AVDD , REFINx(−) = AGND, MCLK = 4.92 MHz,
TA = TMIN to TMAX, unless otherwise noted.
Table 1.
Parameter AD7190B Unit Test Conditions/Comments1
ADC
Output Data Rate 4.7 to 4800 Hz nom Chop disabled.
1.17 to 1200 Hz nom Chop enabled, sinc4 filter.
1.56 to 1600 Hz nom Chop enabled, sinc3 filter.
No Missing Codes2 24 Bits min FS > 1, sinc4 filter3.
24 Bits min FS > 4, sinc3 filter3.
Resolution See the RMS Noise and
Resolution section
RMS Noise and Output Data Rates See the RMS Noise and
Resolution section
Integral Nonlinearity ±5 ppm of FSR max ±1 ppm typical, gain = 1.
±15 ppm of FSR max ±5 ppm typical, gain > 1.
Offset Error4, 5 ±75/gain μV typ Chop disabled.
±0.5 μV typ Chop enabled.
Offset Error Drift vs. Temperature5 ±100/gain nV/°C typ Gain = 1 to 16. chop disabled.
±5 nV/°C typ Gain = 32 to 128. chop disabled.
±5 nV/°C typ Chop enabled.
Offset Error Drift vs. Time 25 nV/1000 hours typ Gain ≥ 32.
Gain Error4 ±0.005 % max ±0.001 % typical, gain = 1, AVDD = 5 V6.
±0.0075 % typ Gain > 1, post internal full-scale calibration.
Gain Drift vs. Temperature ±1 ppm/°C typ
Gain Drift vs. Time 10 ppm/1000 hours typ Gain = 1.
Power Supply Rejection 95 dB typ Gain = 1, VIN = 1 V.
100 dB min Gain > 1, VIN = 1 V/gain. 110 dB typical.
Common-Mode Rejection
@ DC 100 dB min Gain = 1, VIN = 1 V2.
110 dB min Gain > 1, VIN = 1 V/gain.
@ 50 Hz, 60 Hz2 120 dB min 10 Hz output data rate, 50 ± 1 Hz, 60 ± 1 Hz.
@ 50 Hz, 60 Hz2 120 dB min
50 ± 1 Hz (50 Hz output data rate), 60 ± 1 Hz
(60 Hz output data rate).
Normal Mode Rejection2
Sinc4 Filter
Internal Clock
@ 50 Hz, 60 Hz 100 dB min 10 Hz output data rate, 50 ± 1 Hz, 60 ± 1 Hz.
74 dB min
50 Hz output data rate, REJ607 = 1,
50 ± 1 Hz, 60 ± 1 Hz.
@ 50 Hz 96 dB min 50 Hz output data rate, 50 ± 1 Hz.
@ 60 Hz 97 dB min 60 Hz output data rate, 60 ± 1 Hz.
AD7190
Rev. B | Page 4 of 40
Parameter AD7190B Unit Test Conditions/Comments1
External Clock
@ 50 Hz, 60 Hz 120 dB min 10 Hz output data rate, 50 ± 1 Hz, 60 ± 1 Hz.
82 dB min
50 Hz output data rate, REJ607 = 1,
50 ± 1 Hz, 60 ± 1 Hz.
@ 50 Hz 120 dB min 50 Hz output data rate, 50 ± 1 Hz.
@ 60 Hz 120 dB min 60 Hz output data rate, 60 ± 1 Hz.
Sinc3 Filter
Internal Clock
@ 50 Hz, 60 Hz 75 dB min 10 Hz output data rate, 50 ± 1 Hz, 60 ± 1 Hz.
60 dB min
50 Hz output data rate, REJ60 = 1,
50 ± 1 Hz, 60 ± 1 Hz.
@ 50 Hz 70 dB min 50 Hz output data rate, 50 ± 1 Hz.
@ 60 Hz 70 dB min 60 Hz output data rate, 60 ± 1 Hz.
External Clock
@ 50 Hz, 60 Hz 100 dB min 10 Hz output data rate, 50 ± 1 Hz, 60 ± 1 Hz.
67 dB min
50 Hz output data rate, REJ607 = 1,
50 ± 1 Hz, 60 ± 1 Hz.
@ 50 Hz 95 dB min 50 Hz output data rate, 50 ± 1 Hz.
@ 60 Hz 95 dB min 60 Hz output data rate, 60 ± 1 Hz.
ANALOG INPUTS
Differential Input Voltage Ranges ±VREF/gain V nom VREF = REFINx(+) − REFINx(−),
gain = 1 to 128.
±(AVDD – 1.25 V)/gain V min/max Gain > 1.
Absolute AIN Voltage Limits2
Unbuffered Mode AGND − 50 mV V min
AVDD + 50 mV V max
Buffered Mode AGND + 250 mV V min
AVDD − 250 mV V max
Analog Input Current
Buffered Mode
Input Current2 ±2 nA max Gain = 1.
±3 nA max Gain > 1.
Input Current Drift ±5 pA/°C typ
Unbuffered Mode
Input Current ±5 μA/V typ Gain = 1, input current varies with input
voltage.
±1 μA/V typ Gain > 1.
Input Current Drift ±0.05 nA/V/°C typ External clock.
±1.6 nA/V/°C typ Internal clock.
REFERENCE INPUT
REFIN Voltage AVDD V nom REFIN = REFINx(+) − REFINx(−).
Reference Voltage Range2 1 V min
AVDD V max The differential input must be limited to
± (AVDD – 1.25 V)/gain when gain > 1.
Absolute REFIN Voltage Limits2 AGND – 50 mV V min
AVDD + 50 mV V max
Average Reference Input Current 7 μA/V typ
Average Reference Input Current
Drift
±0.03 nA/V/°C typ External clock.
1.3 nA/V/°C typ Internal clock.
AD7190
Rev. B | Page 5 of 40
Parameter AD7190B Unit Test Conditions/Comments1
Normal Mode Rejection2 Same as for analog inputs
Common-Mode Rejection 95 dB typ
Reference Detect Levels 0.3 V min
0.6 V max
TEMPERATURE SENSOR
Accuracy ±2 °C typ Applies after user calibration at 25°C.
Sensitivity 2815 Codes/°C typ Bipolar mode.
BRIDGE POWER-DOWN SWITCH
RON 10 Ω max
Allowable Current2 30 mA max Continuous current.
BURNOUT CURRENTS
AIN Current 500 nA nom Analog inputs must be buffered and chop
disabled.
DIGITAL OUTPUTS (P0 to P3)
Output High Voltage, VOH2 4 V min AVDD = 5V, ISOURCE = 200 μA.
Output Low Voltage, VOL2 0.4 V max AVDD = 5V, ISINK = 800 μA.
Floating-State Leakage Current ±100 nA max
Floating-State Output
Capacitance
10 pF typ
INTERNAL/EXTERNAL CLOCK
Internal Clock
Frequency 4.92 ± 4% MHz min/max
Duty Cycle 50:50 % typ
External Clock/Crystal2
Frequency 4.9152 MHz nom
2.4576/5.12 MHz min/max
Input Low Voltage, VINL 0.8 V max DVDD = 5 V.
0.4 V max DVDD = 3 V.
Input High Voltage, VINH 2.5 V min DVDD = 3 V.
3.5 V min DVDD = 5 V.
Input Current ±10 μA max
LOGIC INPUTS
Input High Voltage, VINH2 2 V min
Input Low Voltage, VINL2 0.8 V max
Hysteresis2 0.1/0.25 V min/V max
Input Currents ±10 μA max
LOGIC OUTPUT (DOUT/RDY)
Output High Voltage, VOH2 DVDD − 0.6 V min DVDD = 3 V, ISOURCE = 100 μA.
Output Low Voltage, VOL2 0.4 V max DVDD = 3 V, ISINK = 100 μA.
Output High Voltage, VOH2 4 V min DVDD = 5 V, ISOURCE = 200 μA.
Output Low Voltage, VOL2 0.4 V max DVDD = 5 V, ISINK = 1.6 mA.
Floating-State Leakage Current ±10 μA max
Floating-State Output
Capacitance
10 pF typ
Data Output Coding Offset binary
SYSTEM CALIBRATION2
Full-Scale Calibration Limit 1.05 × FS V max
Zero-Scale Calibration Limit −1.05 × FS V min
Input Span 0.8 × FS V min
2.1 × FS V max
AD7190
Rev. B | Page 6 of 40
Parameter AD7190B Unit Test Conditions/Comments1
POWER REQUIREMENTS8
Power Supply Voltage
AVDD − AGND 4.75/5.25 V min/max
DVDD − DGND 2.7/5.25 V min/max
Power Supply Currents
AIDD Current 1 mA max 0.85 mA typical, gain = 1, buffer off.
1.3 mA max 1.1 mA typical, gain = 1, buffer on.
4.5 mA max 3.5 mA typical, gain = 8, buffer off.
4.75 mA max 4 mA typical, gain = 8, buffer on.
6.2 mA max 5 mA typical, gain = 16 to 128, buffer off.
6.75 mA max 5.5 mA typical, gain = 16 to 128, buffer on.
DIDD Current 0.4 mA max 0.35 mA typical, DVDD = 3 V.
0.6 mA max 0.5 mA typical, DVDD = 5 V.
1.5 mA typ External crystal used.
IDD (Power-Down Mode) 2 μA max
1 Temperature range: TMIN = −40°C, TMAX = +105°C.
2 Specification is not production tested but is supported by characterization data at initial product release.
3 FS = decimal equivalent of Bit FS9 to Bit FS0 in the mode register.
4 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.
5 The analog inputs are configured for differential mode.
6 Applies at the factory calibration conditions (AVDD = 5 V, gain = 1, TA = 25°C).
7 REJ60 is a bit in the mode register. When the output data rate is set to 50 Hz, setting REJ60 to 1 places a notch at 60 Hz, allowing simultaneous 50 Hz/60 Hz rejection.
8 Digital inputs equal to DVDD or DGND.
AD7190
Rev. B | Page 7 of 40
TIMING CHARACTERISTICS
AVDD = 4.75 V to 5.25 V, DVDD = 2.7 V to 5.25 V, AGND = DGND = 0 V, Input Logic 0 = 0 V, Input Logic 1 = DVDD, unless
otherwise noted.
Table 2.
Parameter Limit at TMIN, TMAX (B Version) Unit Conditions/Comments1, 2
t3 100 ns min SCLK high pulse width
t4 100 ns min SCLK low pulse width
READ OPERATION
t1 0 ns min CS falling edge to DOUT/RDY active time
60 ns max DVDD = 4.75 V to 5.25 V
80 ns max DVDD = 2.7 V to 3.6 V
t23 0 ns min SCLK active edge to data valid delay4
60 ns max DVDD = 4.75 V to 5.25 V
80 ns max DVDD = 2.7 V to 3.6 V
t55, 6 10 ns min Bus relinquish time after CS inactive edge
80 ns max
t6 0 ns min SCLK inactive edge to CS inactive edge
t7 10 ns min SCLK inactive edge to DOUT/RDY high
WRITE OPERATION
t8 0 ns min CS falling edge to SCLK active edge setup time4
t9 30 ns min Data valid to SCLK edge setup time
t10 25 ns min Data valid to SCLK edge hold time
t11 0 ns min CS rising edge to SCLK edge hold time
1 Sample tested during initial release to ensure compliance. All input signals are specified with tR = tF = 5 ns (10% to 90% of DVDD) and timed from a voltage level of 1.6 V.
2 See Figure 3 and Figure 4.
3 These numbers 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.
4 The SCLK active edge is the falling edge of SCLK.
5 These numbers are derived from the measured time taken by the data output to change 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 50 pF capacitor. This means that the times quoted in the timing characteristics are the
true bus relinquish times of the part and, as such, are independent of external bus loading capacitances.
6 RDY returns high after a read of the data register. In single conversion mode and continuous conversion mode, the same data can be read again, if required, while RDY
is high, although care should be taken to ensure that subsequent reads do not occur close to the next output update. If the continuous read feature is enabled, the
digital word can be read only once.
CIRCUIT AND TIMING DIAGRAMS
I
SINK
(1.6mA WITH DV
DD
= 5V,
100µA WITH DV
DD
= 3V)
I
SOURCE
(200µA WI TH DV
DD
= 5V,
100µA WITH DV
DD
= 3V)
1.6V
TO
OUTPUT
PIN 50pF
0
7640-002
Figure 2. Load Circuit for Timing Characterization
AD7190
Rev. B | Page 8 of 40
t
2
t
3
t
4
t
1
t
6
t
5
t
7
CS (I)
DOUT/RDY ( O)
SCLK (I)
I = INPUT, O = OUTPUT
MSB LSB
0
7640-003
Figure 3. Read Cycle Timing Diagram
I = INPUT, O = OUTPUT
CS (I )
S
CLK (I)
DIN ( I) MSB LSB
t
8
t
9
t
10
t
11
0
7640-004
Figure 4. Write Cycle Timing Diagram
AD7190
Rev. B | Page 9 of 40
ABSOLUTE MAXIMUM RATINGS
TA = 25°C, unless otherwise noted.
Table 3.
Parameter Rating
AVDD to AGND 0.3 V to +6.5 V
DVDD to AGND 0.3 V to +6.5 V
AGND to DGND 0.3 V to +0.3 V
Analog Input Voltage to AGND 0.3 V to AVDD + 0.3 V
Reference Input Voltage to AGND 0.3 V to AVDD + 0.3 V
Digital Input Voltage to DGND 0.3 V to DVDD + 0.3 V
Digital Output Voltage to DGND 0.3 V to DVDD + 0.3 V
AIN/Digital Input Current 10 mA
Operating Temperature Range 40°C to +105°C
Storage Temperature Range 65°C to +150°C
Maximum Junction Temperature 150°C
Lead Temperature, Soldering
Reflow 260°C
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device 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 4. Thermal Resistance
Package Type θJA θ
JC Unit
24-Lead TSSOP 128 42 °C/W
ESD CAUTION
AD7190
Rev. B | Page 10 of 40
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
NC = NO CONNECT
1
2
3
4
5
6
7
8
9
10
12
11
MCLK2
SCLK
CS
P1/REFIN2(+)
P2
P3
MCLK1
P0/REFIN2(–)
NC
AINCOM
AIN2
AIN1
20
21
22
23
24
19
18
17
16
15
14
13
DOUT/RDY
SYNC
DV
DD
AGND
DGND
AV
DD
BPDSW
REFIN1(–)
AIN3
AIN4
REFIN1(+)
DIN
AD7190
TOP VIEW
(No t t o S cale)
07640-005
Figure 5. Pin Configuration
Table 5. Pin Function Descriptions
Pin No. Mnemonic Description
1 MCLK1 When the master clock for the device is provided externally by a crystal, the crystal is connected between
MCLK1 and MCLK2.
2 MCLK2 Master Clock Signal for the Device. The AD7190 has an internal 4.92 MHz clock. This internal clock can be
made available on the MCLK2 pin. The clock for the AD7190 can be provided externally also in the form of
a crystal or external clock. A crystal can be tied across the MCLK1 and MCLK2 pins. Alternatively, the
MCLK2 pin can be driven with a CMOS-compatible clock and the MCLK1 pin left unconnected.
3 SCLK Serial Clock Input. This serial clock input is for data transfers to and from the ADC. The SCLK 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 noncon-
tinuous clock with the information transmitted to or from the ADC in smaller batches of data.
4 CS Chip Select Input. This is an active low logic input used to select the ADC. CS can be used 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, allowing the ADC to operate in 3-wire mode
with SCLK, DIN, and DOUT used to interface with the device.
5 P3 Digital Output Pin. This pin can function as a general-purpose output bit referenced between AVDD and AGND.
6 P2 Digital Output Pin. This pin can function as a general-purpose output bit referenced between AVDD and AGND.
7 P1/REFIN2(+)
Digital Output Pin/Positive Reference Input. This pin functions as a general-purpose output bit referenced
between AVDD and AGND. When REFSEL = 1, this pin functions as REFIN2(+). An external reference can be
applied between REFIN2(+) and REFIN2(−). REFIN2(+) can lie anywhere between AVDD and AGND + 1 V. The
nominal reference voltage, (REFIN2(+) − REFIN2(−)), is AVDD, but the part functions with a reference from
1 V to AVDD.
8 P0/REFIN2(−)
Digital Output Pin/Negative Reference Input. This pin functions as a general-purpose output bit referenced
between AVDD and AGND. When REFSEL = 1, this pin functions as REFIN2(−). This reference input can lie
anywhere between AGND and AVDD − 1 V.
9 NC No Connect. This pin should be tied to AGND.
10 AINCOM Analog Input AIN1 to Analog Input AIN4 are referenced to this input when configured for pseudo
differential operation.
11 AIN1 Analog Input. It can be configured as the positive input of a fully differential input pair when used with
AIN2 or as a pseudo differential input when used with AINCOM.
12 AIN2 Analog Input. It can be configured as the negative input of a fully differential input pair when used with
AIN1 or as a pseudo differential input when used with AINCOM.
AD7190
Rev. B | Page 11 of 40
Pin No. Mnemonic Description
13 AIN3 Analog Input. It can be configured as the positive input of a fully differential input pair when used with
AIN4 or as a pseudo differential input when used with AINCOM.
14 AIN4 Analog Input. It can be configured as the negative input of a fully differential input pair when used with
AIN3 or as a pseudo differential input when used with AINCOM.
15 REFIN1(+) Positive Reference Input. An external reference can be applied between REFIN1(+) and REFIN1(−).
REFIN1(+) can lie anywhere between AVDD and AGND + 1 V. The nominal reference voltage, (REFIN1(+) −
REFIN1(−)), is AVDD, but the part functions with a reference from 1 V to AVDD.
16 REFIN1(−) Negative Reference Input. This reference input can lie anywhere between AGND and AVDD − 1 V.
17 BPDSW Bridge Power-Down Switch to AGND.
18 AGND Analog Ground Reference Point.
19 DGND Digital Ground Reference Point.
20 AVDD Analog Supply Voltage, 4.75 V to 5.25 V. AVDD is independent of DVDD.
21 DVDD Digital Supply Voltage, 2.7 V to 5.25 V. DVDD is independent of AVDD.
22 SYNC Logic input that allows for synchronization of the digital filters and analog modulators when using
multiple AD7190 devices. While 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 its reset state. SYNC does not affect
the digital interface but does reset RDY to a high state if it is low. SYNC has a pull-up resistor internally to
DVDD.
23 DOUT/RDY Serial Data Output/Data Ready Output. DOUT/RDYserves a dual purpose. It 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 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. With CS 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.
24 DIN Serial Data Input to the Input Shift Register on the ADC. Data in this shift register is transferred to the
control registers in the ADC, with the register selection bits of the communications register identifying the
appropriate register.
AD7190
Rev. B | Page 12 of 40
TYPICAL PERFORMANCE CHARACTERISTICS
8,388,760
8,388,758
8,388,756
8,388,754
8,388,752
8,388,750
8,388,748
8,388,746 0 200 400 600 800 1000
CODE
SAMPLE
07640-106
8,388,950
8,388,900
8,388,800
8,388,750
8,388,650
8,388,600
8,388,850
8,388,700
8,388,550
8,388,500
8,388,450 0 200 400 600 800 1000100 300 500 700 900
CODE
SAMPLES
07640-108
Figure 6. Noise (VREF = 5 V, Output Data Rate = 4.7 Hz, Gain = 128, Chop
Disabled, Sinc4 Filter)
Figure 8. Noise (VREF = 5 V, Output Data Rate = 4800 Hz, Gain = 128, Chop
Disabled, Sinc4 Filter)
250
200
150
100
50
0
8,388,746
8,388,748
8,388,750
8,388,752
8,388,754
8,388,756
8,388,758
8,388,760
FREQUENCY
CODE
07640-107
30
20
25
15
10
5
0
8,388,490
8,388,576
8,388,662
8,388,748
8,388,834
8,388,920
FREQUENCY
CODE
07640-109
Figure 9. Noise Distribution Histogram (VREF = 5 V,
Output Data Rate = 4800 Hz, Gain = 128, Chop Disabled, Sinc4 Filter)
Figure 7. Noise Distribution Histogram (VREF = 5 V,
Output Data Rate = 4.7 Hz, Gain = 128, Chop Disabled, Sinc4 Filter)
AD7190
Rev. B | Page 13 of 40
8,388,820
8,388,800
8,388,760
8,388,740
8,388,700
8,388,680
8,388,780
8,388,720
8,388,660
8,388,640
8,388,620 0 200 400 600 800 1000100 300 500 700 900
CODE
SAMPLES
07640-110
Figure 10. Noise (VREF = 5 V, Output Data Rate = 4800 Hz, Gain = 1, Chop
Disabled, Sinc4 Filter)
80
50
70
40
60
30
20
10
0
8,388,620
8,388,660
8,388,700
8,388,740
8,388,780
8,388,820
FREQUENCY
CODE
0
7640-111
Figure 11. Noise Distribution Histogram (VREF = 5 V,
Output Data Rate = 4800 Hz, Gain = 1, Chop Disabled, Sinc4 Filter)
3.0
2.0
1.0
0
–1.0
–2.0
–3.0
–2.5 –2.0 –1.5 –1.0 0.5 0 0.5 1.0 1.5 2.0 2.5
INL (ppm of FSR)
V
IN
(V)
07640-112
Figure 12. INL (Gain = 1)
6
4
2
0
–2
–4
–6
–0.020 –0.015 –0.010 –0.005 0 0.005 0.010 0.015 0.020
INL (ppm of FSR)
V
IN
(V)
07640-113
Figure 13. INL (Gain = 128)
AD7190
Rev. B | Page 14 of 40
1.000008
1.000007
1.000006
1.000005
1.000004
1.000003
1.000002
1.000001
1.000000
–60 –40 –20 0 20 40 60 80 100 120
GAIN
TEMPERAT URE (°C)
07640-116
66
64
62
60
58
56
54
–60 –40 –20 0 20 40 60 80 100 120 140
OUT P UT VO LTAGE (µV)
TEM P E RATURE (°C)
07640-114
Figure 14. Offset Error (Gain = 1, Chop Disabled) Figure 16. Gain Error (Gain = 1, Chop Disabled)
0
–0.1
–0.2
–0.3
–0.4
–0.5
–0.6
–0.7
–60 –40 –20 0 20 40 60 80 100 120
OFFSET (µV)
TEME RA TUREC)
07640-115
128.003
128.002
128.001
128.000
127.999
127.998
127.997
127.996
–60 –40 –20 0 20 40 60 80 100 120
GAIN
TEM P E RATURE (°C)
07640-117
Figure 15. Offset Error (Gain = 128, Chop Disabled) Figure 17. Gain Error (Gain = 128, Chop Disabled)
AD7190
Rev. B | Page 15 of 40
RMS NOISE AND RESOLUTION
The AD7190 has a choice of two filter types: sinc4 and sinc3.
In addition, the AD7190 can be operated with chop enabled
or chop disabled.
The following tables show the rms noise of the AD7190 for some
of the output data rates and gain settings with chop disabled
and enabled for the sinc4 and sinc3 filters. The numbers given
are for the bipolar input range with the external 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. The effective resolution is also shown, and
the output peak-to-peak (p-p) resolution, or noise-free resol-
ution, is listed in parentheses. It is important to note that the
effective resolution is calculated using the rms noise, wheras the
p-p resolution is calculated based on peak-to-peak noise. The
p-p resolution represents the resolution for which there is no
code flicker. These numbers are typical and are rounded to the
nearest ½ LSB.
SINC4 CHOP DISABLED
Table 6. RMS Noise (nV) vs. Gain and Output Data Rate
Filter Word
(Decimal)
Output Data
Rate (Hz)
Settling
Time (ms) Gain of 1 Gain of 8 Gain of 16 Gain of 32 Gain of 64 Gain of 128
1023 4.7 852.5 250 38 21 12 10 8.5
640 7.5 533 310 45 25 16 12 10.5
480 10 400 330 50 30 18 14 11.5
96 50 80 900 125 78 45 33 28
80 60 66.7 970 140 88 52 36 31
32 150 26.7 1460 215 125 75 55 48
16 300 13.3 1900 285 170 100 75 67
5 960 4.17 3000 480 280 175 140 121
2 2400 1.67 5000 780 440 280 220 198
1 4800 0.83 14,300 1920 1000 550 380 295
Table 7. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate
Filter Word
(Decimal)
Output Data
Rate (Hz)
Settling
Time (ms) Gain of 11 Gain of 81 Gain of 161 Gain of 321 Gain of 641 Gain of 1281
1023 4.7 852.5 24 (22.5) 24 (22) 24 (22) 24 (22) 24 (21) 23 (20.5)
640 7.5 533 24 (22) 24 (22) 24 (22) 24 (21.5) 23.5 (21) 23 (20)
480 10 400 24 (22) 24 (22) 24 (21.5) 24 (21.5) 23.5 (20.5) 22.5 (20)
96 50 80 23.5 (20.5) 23.5 (20.5) 23 (20) 22.5 (20) 22 (19.5) 21.5 (18.5)
80 60 66.7 23.5 (20.5) 23 (20.5) 22.5 (20) 22.5 (20) 22 (19.5) 21.5 (18.5)
32 150 26.7 22.5 (20) 22.5 (19.5) 22.5 (19.5) 22 (19.5) 21.5 (18.5) 20.5 (18)
16 300 13.3 22.5 (19.5) 22 (19.5) 22 (19) 21.5 (19) 21 (18.5) 20 (17.5)
5 960 4.17 21.5 (19) 21.5 (18.5) 21 (18.5) 21 (18) 20 (17.5) 19.5 (16.5)
2 2400 1.67 21 (18) 20.5 (18) 20.5 (17.5) 20 (17.5) 19.5 (16.5) 18.5 (16)
1 4800 0.83 19.5 (16.5) 19.5 (16.5) 19.5 (16.5) 19 (16.5) 18.5 (16) 18 (15.5)
1 The output peak-to-peak (p-p) resolution is listed in parentheses.
AD7190
Rev. B | Page 16 of 40
SINC3 CHOP DISABLED
Table 8. RMS Noise (nV) vs. Gain and Output Data Rate
Filter Word
(Decimal)
Output Data
Rate (Hz)
Settling
Time (ms) Gain of 1 Gain of 8 Gain of 16 Gain of 32 Gain of 64 Gain of 128
1023 4.7 639.4 270 42 23 13.5 10.5 9
640 7.5 400 320 50 27 17 13 11.5
480 10 300 350 60 35 19 15 12.5
96 50 60 1000 134 86 50 35 29
80 60 50 1050 145 95 55 40 32
32 150 20 1500 225 130 80 58 50
16 300 10 1950 308 175 110 83 73
5 960 3.125 4000 590 330 200 150 133
2 2400 1.25 56,600 7000 3500 1800 900 490
1 4800 0.625 442,000 55,000 28,000 14,000 7000 3450
Table 9. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate
Filter Word
(Decimal)
Output Data
Rate (Hz)
Settling
Time (ms) Gain of 11 Gain of 81 Gain of 161 Gain of 321 Gain of 641 Gain of 1281
1023 4.7 639.4 24 (22.5) 24 (22) 24 (22) 24 (21.5) 24 (21) 23 (20.5)
640 7.5 400 24 (22) 24 (22) 24 (21.5) 24 (21.5) 23.5 (21) 22.5 (20)
480 10 300 24 (22) 24 (21.5) 24 (21.5) 24 (21) 23.5 (20.5) 22.5 (20)
96 50 60 23.5 (20.5) 23 (20.5) 23 (20) 22.5 (20) 22 (19.5) 21.5 (18.5)
80 60 50 23 (20.5) 23 (20.5) 22.5 (20) 22.5 (19.5) 22 (19) 21 (18.5)
32 150 20 22.5 (20) 22.5 (19.5) 22 (19.5) 22 (19) 21.5 (18.5) 20.5 (18)
16 300 10 22.5 (19.5) 22 (19) 22 (19) 21.5 (18.5) 21 (18) 20 (17.5)
5 960 3.125 21.5 (18.5) 21 (18.5) 21 (18) 20.5 (18) 20 (17.5) 19 (16.5)
2 2400 1.25 17.5 (14.5) 17.5 (14.5) 17.5 (14.5) 17.5 (14.5) 17.5 (14.5) 17.5 (14.5)
1 4800 0.625 14.5 (11.5) 14.5 (11.5) 14.5 (11.5) 14.5 (11.5) 14.5 (11.5) 14.5 (11.5)
1 The output peak-to-peak (p-p) resolution is listed in parentheses.
AD7190
Rev. B | Page 17 of 40
SINC4 CHOP ENABLED
Table 10. RMS Noise (nV) vs. Gain and Output Data Rate
Filter Word
(Decimal)
Output Data
Rate (Hz)
Settling
Time (ms) Gain of 1 Gain of 8 Gain of 16 Gain of 32 Gain of 64 Gain of 128
1023 1.175 1702 177 27 15 8.5 7 6
640 1.875 1067 219 32 18 11.5 8.5 7.5
480 2.5 800 234 36 21 13 10 8.5
96 12.5 160 637 89 55 32 24 20
80 15 133 686 99 63 37 26 22
32 37.5 53 1033 152 89 53 39 34
16 75 26.7 1343 202 120 71 53 48
5 240 8.33 2121 340 198 124 99 86
2 600 3.33 3536 552 311 198 156 140
1 1200 1.67 10,200 1360 707 389 26 209
Table 11. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate
Filter Word
(Decimal)
Output Data
Rate (Hz)
Settling
Time (ms) Gain of 11 Gain of 81 Gain of 161 Gain of 321 Gain of 641 Gain of 1281
1023 1.175 1702 24 (23) 24 (22.5) 24 (22.5) 24 (22.5) 24 (21.5) 23.5 (21)
640 1.875 1067 24 (22.5) 24 (22.5) 24 (22.5) 24 (22) 24 (21.5) 23.5 (20.5)
480 2.5 800 24 (22.5) 24 (22.5) 24 (22) 24 (22) 24 (21) 23 (20.5)
96 12.5 160 24 (21) 24 (21) 23.5 (20.5) 23 (20.5) 22.5 (20) 22 (19)
80 15 133 24 (21) 23.5 (21) 23.5 (20.5) 23 (20.5) 22.5 (20) 22 (19)
32 37.5 53 23 (20.5) 23 (20) 23 (20) 22.5 (20) 22 (19) 21 (18.5)
16 75 26.7 23 (20) 22.5 (20) 22.5 (19.5) 22 (19.5) 21.5 (19) 20.5 (18)
5 240 8.33 22 (19.5) 22 (19) 21.5 (19) 21.5 (18.5) 20.5 (18) 20 (17)
2 600 3.33 21.5 (18.5) 21 (18.5) 21 (18) 20.5 (18) 20 (17) 19 (16.5)
1 1200 1.67 20 (17) 20 (17) 20 (17) 19.5 (17) 19 (16.5) 18.5 (16)
1 The output peak-to-peak (p-p) resolution is listed in parentheses.
AD7190
Rev. B | Page 18 of 40
SINC3 CHOP ENABLED
Table 12. RMS Noise (nV) vs. Gain and Output Data Rate
Filter Word
(Decimal)
Output Data
Rate (Hz)
Settling
Time (ms) Gain of 1 Gain of 8 Gain of 16 Gain of 32 Gain of 64 Gain of 128
1023 1.56 1282 191 30 16.5 10 8 6.5
640 2.5 800 226 36 19 12 9 8.5
480 3.33 600 248 43 25 14 11 9
96 16.6 120 708 95 61 36 25 21
80 20 100 743 103 68 39 29 23
32 50 40 1061 159 92 57 41 36
16 100 20 1380 218 124 78 59 52
5 320 6.25 2829 418 234 142 106 94
2 800 2.5 40,100 4950 2475 1273 637 347
1 1600 1.25 312,550 38,540 19,800 9900 4950 2440
Table 13. Effective Resolution (Peak-to-Peak Resolution) vs. Gain and Output Data Rate
Filter Word
(Decimal)
Output Data
Rate (Hz)
Settling
Time (ms) Gain of 11 Gain of 81 Gain of 161 Gain of 321 Gain of 641 Gain of 1281
1023 1.56 1282 24 (23) 24 (22.5) 24 (22.5) 24 (22) 24 (21.5) 23.5 (21)
640 2.5 800 24 (22.5) 24 (22.5) 24 (22) 24 (22) 24 (21.5) 23 (20.5)
480 3.33 600 24 (22.5) 24 (22) 24 (22) 24 (21.5) 24 (21) 23 (20.5)
96 16.6 120 24 (21) 23.5 (21) 23.5 (20.5) 23 (20.5) 22.5 (20) 22 (19)
80 20 100 23.5 (21) 23.5 (21) 23 (20.5) 23 (20) 22.5 (19.5) 21.5 (19)
32 50 40 23 (20.5) 23 (20) 22.5 (20) 22.5 (19.5) 22 (19) 21 (18.5)
16 100 20 23 (20) 22.5 (19.5) 22.5 (19.5) 22 (19) 21.5 (18.5) 20.5 (18)
5 320 6.25 22 (19) 21.5 (19) 21.5 (18.5) 21 (18.5) 20.5 (18) 19.5 (17)
2 800 2.5 18 (15) 18 (15) 18 (15) 18 (15) 18 (15) 18 (15)
1 1600 1.25 15 (12) 15 (12.5) 15 (12) 15 (12) 15 (12) 15 (12)
1 The output peak-to-peak (p-p) resolution is listed in parentheses.
AD7190
Rev. B | Page 19 of 40
ON-CHIP REGISTERS
The ADC is controlled and configured via a number of on-chip
registers, which are described in the following sections. In the
descriptions, set implies a Logic 1 state and cleared implies a
Logic 0 state, unless otherwise noted.
COMMUNICATIONS REGISTER
(RS2, RS1, RS0 = 0, 0, 0)
The communications register is an 8-bit write-only register. All
communications to the part 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 in which register this operation takes
place. For read or write operations, when 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 communi-
cations register. In situations where the interface sequence is
lost, a write operation of at least 40 serial clock cycles with DIN
high returns the ADC to this default state by resetting the entire
part. Table 14 outlines the bit designations for the
communications register. CR0 through CR7 indicate the bit
locations, CR denoting that the bits are in the communications
register. CR7 denotes the first bit of the data stream. The
number in parentheses indicates the power-on/reset default
status of that bit.
CR7 CR6 CR5 CR4 CR3 CR2 CR1 CR0
WEN(0) R/W(0) RS2(0) RS1(0) RS0(0) CREAD(0) 0(0) 0(0)
Table 14. Communications Register Bit Designations
Bit Location Bit Name Description
CR7 WEN Write enable bit. A 0 must be written to this bit for a write to the communications register to occur. If a 1 is
the first bit written, the part does not clock on to subsequent bits in the register. It stays at this bit location
until a 0 is written to this bit. After a 0 is written to the WEN bit, the next seven bits are loaded to the
communications register.
CR6 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.
CR5 to CR3 RS2 to RS0 Register address bits. These address bits are used to select which registers of the ADC are selected during
the serial interface communication. See Table 15.
CR2 CREAD 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
register are automatically placed on the DOUT pin when the SCLK pulses are applied after the RDY pin
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 instruction 01011100 must be written
to the communications register. To disable continuous read, the instruction 01011000 must be written to
the communications register while the 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 40 consecutive 1s are seen on DIN. Therefore, DIN should be held low until an instruction is to be
written to the device.
CR1 to CR0 These bits must be programmed to Logic 0 for correct operation.
Table 15. Register Selection
RS2 RS1 RS0 Register Register Size
0 0 0 Communications register during a write operation 8 bits
0 0 0 Status register during a read operation 8 bits
0 0 1 Mode register 24 bits
0 1 0 Configuration register 24 bits
0 1 1 Data register/data register plus status information 24 bits/32 bits
1 0 0 ID register 8 bits
1 0 1 GPOCON register 8 bits
1 1 0 Offset register 24 bits
1 1 1 Full-scale register 24 bits
AD7190
Rev. B | Page 20 of 40
STATUS REGISTER
(RS2, RS1, RS0 = 0, 0, 0; Power-On/Reset = 0x80)
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 a read, and load Bit RS2, Bit RS1, and Bit RS0 with 0. Table 16 outlines the bit designations for the status
register. SR0 through SR7 indicate the bit locations, SR denoting that the bits are in the status register. SR7 denotes the first bit of the data
stream. The number in parentheses indicates the power-on/reset default status of that bit.
SR7 SR6 SR5 SR4 SR3 SR2 SR1 SR0
RDY(1) ERR(0) NOREF(0) Parity(0) 0(0) CHD2(0) CHD1(0) CHD0(0)
Table 16. Status Register Bit Designations
Bit Location Bit Name Description
SR7 RDY Ready bit for the ADC. 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 that the conversion data should not be read. It is also
set when the part is placed in power-down mode or idle mode or when SYNC is taken low.
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.
SR6 ERR ADC error bit. This bit is written to at the same time as the RDY bit. The ERR bit is set to indicate that the
result written to the ADC data register is clamped to all 0s or all 1s. Error sources include overrange or
underrange or the absence of a reference voltage. The bit is cleared by a write operation to start a conversion.
SR5 NOREF No external reference bit. This bit is set to indicate that the selected reference (REFIN1 or REFIN2) is at a
voltage that is below a specified threshold. When set, conversion results are clamped to all 1s. This bit is
cleared to indicate that a valid reference is applied to the selected reference pins. The NOREF bit is enabled
by setting the REFDET bit in the configuration register to 1.
SR4 Parity Parity check of the data register. If the ENPAR bit in the mode register is set, the parity bit is set if there is an
odd number of 1s in the data register. It is cleared if there is an even number of 1s in the data register. The
DAT_STA bit in the mode register should be set when the parity check is used. When the DAT_STA bit is set,
the contents of the status register are transmitted along with the data for each data register read.
SR3 0 This bit will be set to 0.
SR2 to SR0 CHD2 to
CHD0
These bits indicate which channel corresponds to the data register contents. They do not indicate which
channel is presently being converted but indicate which channel was selected when the conversion
contained in the data register was generated.
MODE REGISTER
(RS2, RS1, RS0 = 0, 0, 1; Power-On/Reset = 0x080060)
The mode register is a 24-bit register from which data can be read or to which data can be written. This register is used to select the
operating mode, the output data rate, and the clock source. Table 17 outlines the bit designations for the mode register. MR0 through
MR23 indicate the bit locations, MR denoting that the bits are in the mode register. MR23 denotes the first bit of the data stream. The
number in parentheses indicates the power-on/reset default status of that bit. Any write to the mode register resets the modulator and
filter and sets the RDY bit.
MR23 MR22 MR21 MR20 MR19 MR18 MR17 MR16
MD2(0) MD1(0) MD0(0) DAT_STA(0) CLK1(1) CLK0(0) 0 0
MR15 MR14 MR13 MR12 MR11 MR10 MR9 MR8
Sinc3(0) 0 ENPAR(0) 0 Single(0) REJ60(0) FS9(0) FS8(0)
MR7 MR6 MR5 MR4 MR3 MR2 MR1 MR0
FS7(0) FS6(1) FS5(1) FS4(0) FS3(0) FS2(0) FS1(0) FS0(0)
AD7190
Rev. B | Page 21 of 40
Table 17. Mode Register Bit Designations
Bit Location Bit Name Description
MR23 to MR21 MD2 to MD0 Mode select bits. These bits select the operating mode of the AD7190 (see Table 18).
MR20 DAT_STA
This bit enables the transmission of status register contents after each data register read. When
DAT_STA 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.
MR19 to MR18 CLK1 to CLK0 These bits are used to select the clock source for the AD7190. Either the on-chip 4.92 MHz clock or an
external clock can be used. The ability to use an external clock allows several AD7190 devices to be
synchronized. Also, 50 Hz/60 Hz rejection is improved when an accurate external clock drives the
AD7190.
CLK1 CLK0 ADC Clock Source
0 0 External crystal. The external crystal is connected from MCLK1 to MCLK2.
0 1 External clock. The external clock is applied to the MCLK2 pin.
1 0 Internal 4.92 MHz clock. Pin MCLK2 is tristated.
1 1 Internal 4.92 MHz clock. The internal clock is available on MCLK2.
MR17 to MR16 These bits must be programmed with a Logic 0 for correct operation.
MR15 SINC3
Sinc3 filter select bit. When this bit is cleared, the sinc4 filter is used (default value). When this bit is set,
the sinc3 filter is used. The benefit of the sinc3 filter compared to the sinc4 filter is its lower settling time
when chop is disabled. For a given output data rate, fADC, the sinc3 filter has a settling time of 3/fADC
while the sinc4 filter has a settling time of 4/fADC. The sinc4 filter, due to its deeper notches, gives better
50 Hz/60 Hz rejection. At low output data rates, both filters give similar rms noise and similar no
missing codes for a given output data rate. At higher output data rates (FS values less than 5), the sinc4
filter gives better performance than the sinc3 filter for rms noise and no missing codes.
MR14 This bit must be programmed with a Logic 0 for correct operation.
MR13 ENPAR
Enable parity bit. When ENPAR is set, parity checking on the data register is enabled. The DAT_STA bit
in the mode register should be set when the parity check is used. When the DAT_STA bit is set, the
contents of the status register are transmitted along with the data for each data register read.
MR12 This bit must be programmed with a Logic 0 for correct operation.
MR11 Single
Single cycle conversion enable bit. When this bit is set, the AD7190 settles in one conversion cycle so
that it functions as a zero latency ADC. This bit has no affect when multiple analog input channels are
enabled or when the single conversion mode is selected.
MR10 REJ60
This bit enables a notch at 60 Hz when the first notch of the sinc filter is at 50 Hz. When REJ60 is set, a
filter notch is placed at 60 Hz when the sinc filter first notch is at 50 Hz. This allows simultaneous
50 Hz/60 Hz rejection.
MR9 to MR0 FS9 to FS0 Filter output data rate select bits. The 10 bits of data programmed into these bits determine the filter
cutoff frequency, the position of the first notch of the filter, and the output data rate for the part. In
association with the gain selection, it also determines the output noise (and, therefore, the effective
resolution) of the device. (see Table 6 through Table 13)
When chop is disabled and continuous conversion mode is selected, the output data rate equals
Output Data Rate = (fmod/64)/FS
where FS is the decimal equivalent of the code in bits FS0 to FS9 and is in the range 1 to 1023, and
fmod is the modulator frequency, which is equal to MCLK/16. With a nominal MCLK of 4.92 MHz, this
results in a output data rate from 4.69 Hz to 4.8 kHz. With chop disabled, the filter first notch
frequency is equal to the output data rate when converting on a single channel.
When chop is enabled, the output data rate equals
Output Data Rate = (fmod/64)/(N × FS)
where:
FS is the decimal equivalent of the code in Bit FS0 to Bit FS9 and is in the range 1 to 1023.
fmod is the modulator frequency, which is equal to MCLK/16. With a nominal MCLK of 4.92 MHz, this
results in a conversion rate from 4.69/N Hz to 4.8/N kHz, where N is the order of the sinc filter. The sinc
filters first notch frequency is equal to N × Output Data Rate. The chopping introduces notches at odd
integer multiples of (Output Data Rate/2).
AD7190
Rev. B | Page 22 of 40
Table 18. Operating Modes
MD2 MD1 MD0 Mode
0 0 0 Continuous conversion mode (default). In continuous conversion mode, the ADC continuously performs conversions
and places the result in the data register. The DOUT/ RDY pin and the RDY bit in the status register go low when a
conversion is complete. The user can read these conversions by setting the CREAD bit in the communications
register to 1, which enables continuous read. When continuous read is enabled, the conversions are automatically
placed on the DOUT line when SCLK pulses are applied. Alternatively, the user can instruct the ADC to output each
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.
0 0 1 Single conversion mode. When single conversion mode is selected, the ADC powers up and performs a single
conversion on the selected channel. The internal clock requires up to 1 ms to power up and settle. The ADC then
performs the conversion, which requires the complete settling time of the filter. The conversion result is placed in
the data register, RDY goes low, and the ADC returns to power-down mode. The conversion remains in the data
register and RDY remains active (low) until the data is read or another conversion is performed.
0 1 0 Idle mode. In idle mode, the ADC filter and modulator are held in a reset state even though the modulator clocks are
still provided.
0 1 1 Power-down mode. In power-down mode, all AD7190 circuitry, except the bridge power-down switch, is powered
down. The bridge power-down switch remains active because the user may need to power up the sensor prior to
powering up the AD7190 for settling reasons. The external crystal, if selected, remains active.
1 0 0 Internal zero-scale 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.
1 0 1 Internal full-scale calibration. A full-scale input voltage is automatically connected to the 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 full-scale 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.
1 1 0 System zero-scale calibration. The user should connect the system zero-scale input to the channel input pins as
selected by the CH7 to CH0 bits in the configuration register. 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.
1 1 1 System full-scale calibration. The user should connect the system full-scale input to the channel input pins as
selected by the CH7 to CH0 bits in the configuration register. 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 full-scale register of the selected channel. A full-scale calibration is required
each time the gain of a channel is changed.
CONFIGURATION REGISTER
(RS2, RS1, RS0 = 0, 1, 0; Power-On/Reset = 0x000117)
The configuration register is a 24-bit register from which data can be read or to which data can be written. This register is used to
configure the ADC for unipolar or bipolar mode, to enable or disable the buffer, to enable or disable the burnout currents, to select the
gain, and to select the analog input channel.
Tabl e 19 outlines the bit designations for the configuration register. CON0 through CON23 indicate the bit locations. CON denotes that
the bits are in the configuration register. CON23 denotes the first bit of the data stream. The number in parentheses indicates the power-
on/reset default status of that bit.
AD7190
Rev. B | Page 23 of 40
CON23 CON22 CON21 CON20 CON19 CON18 CON17 CON16
Chop(0) 0(0) 0(0) REFSEL(0) 0(0) 0(0) 0(0) (0)
CON15 CON14 CON13 CON12 CON11 CON10 CON9 CON8
CH7(0) CH6(0) CH5(0) CH4(0) CH3(0) CH2(0) CH1(0) CH0(1)
CON7 CON6 CON5 CON4 CON3 CON2 CON1 CON0
Burn(0) REFDET(0) 0(0) BUF(1) U/B (0) G2(1) G1(1) G0(1)
Table 19. Configuration Register Bit Designations
Bit Location Bit Name Description
CON23 Chop
Chop enable bit. When the chop bit is cleared, chop is disabled. When the chop bit is set, chop is
enabled. When chop is enabled, the offset and offset drift of the ADC are continuously minimized.
However, this increases the conversion time and settling time of the ADC. For example, when FS = 96
decimal and the sinc4 filter is selected, the conversion time with chop enabled equals 80 ms and the
settling time equals 160 ms. With chop disabled, higher conversion rates are allowed. For an FS word of
96 decimal and the sinc4 filter selected, the conversion time is 20 ms and the settling time is 80 ms.
However, at low gains, periodic calibrations may be required to remove the offset and offset drift.
CON22, CON21 These bits must be programmed with a Logic 0 for correct operation.
CON20 REFSEL Reference select bits. The reference source for the ADC is selected using these bits.
REFSEL Reference Voltage
0 External reference applied between REFIN1(+) and REFIN1().
1 External reference applied between the P1/REFIN2(+) and P0/REFIN2(-) pins.
CON19 to CON16 These bits must be programmed with a Logic 0 for correct operation.
CON15 to CON8 CH7 to CH0 Channel select bits. These bits are used to select which channels are enabled on the AD7190. See Table 20.
Several channels can be selected, and the AD7190 automatically sequences them. The conversion on
each channel requires the complete settling time.
CON7 Burn
When this bit is set to 1, the 500 nA current sources in the signal path are enabled. When burn = 0, the
burnout currents are disabled. The burnout currents can be enabled only when the buffer is active and
when chop is disabled.
CON6 REFDET Enables the reference detect function. When set, the NOREF bit in the status register indicates when the
external reference being used by the ADC is open circuit or less than 0.6 V maximum. The reference
detect circuitry only operates when the ADC is active.
CON5 This bit must be programmed with a Logic 0 for correct operation.
CON4 BUF Enables the buffer on the analog inputs. If cleared, the analog inputs are unbuffered, lowering the
power consumption of the device. If set, the analog inputs are buffered, allowing the user to place
source impedances on the front end without contributing gain errors to the system. With the buffer
disabled, the voltage on the analog input pins can be from 50 mV below AGND to 50 mV above AVDD.
When the buffer is enabled, it requires some headroom; therefore, the voltage on any input pin must be
limited to 250 mV within the power supply rails.
CON3 U/B Polarity select bit. When this bit is set, unipolar operation is selected. When this bit is cleared, bipolar
operation is selected.
CON2 to CON0 G2 to G0 Gain select bits. Written by the user to select the ADC input range as follows:
G2 G1 G0 Gain ADC Input Range (5 V Reference, Bipolar Mode)
0 0 0 1 ±5 V
0 0 1 Reserved
0 1 0 Reserved
0 1 1 8 ±625 mV
1 0 0 16 ±312.5 mV
1 0 1 32 ±156.2 mV
1 1 0 64 ±78.125 mV
1 1 1 128 ±39.06 mV
AD7190
Rev. B | Page 24 of 40
Table 20. Channel Selection
Channel Enable Bits in the Configuration Register Channel Enabled
Status Register
Bits CHD[2:0]
Calibration
Register Pair
CH7 CH6 CH5 CH4 CH3 CH2 CH1 CH0
Positive Input
AIN(+)
Negative Input
AIN(−)
1 AIN1 AIN2 000 0
1 AIN3 AIN4 001 1
1 Temperature sensor 010 None
1 AIN2 AIN2 011 0
1 AIN1 AINCOM 100 0
1 AIN2 AINCOM 101 1
1 AIN3 AINCOM 110 2
1 AIN4 AINCOM 111 3
DATA REGISTER
(RS2, RS1, RS0 = 0, 1, 1; Power-On/Reset = 0x000000)
The conversion result from the ADC is stored in this data
register. This is a read-only, 24-bit register. On completion of a
read operation from this register, the RDY pin/bit is set. When
the DAT_STA bit in the mode register is set to 1, the contents of
the status register are appended to each 24-bit conversion. This
is advisable when several analog input channels are enabled
because the three LSBs of the status register (CHD2 to CHD0)
identify the channel from which the conversion originated.
ID REGISTER
RS2, RS1, RS0 = 1, 0, 0; Power-On/Reset = 0xX4
The identification number for the AD7190 is stored in the ID
register. This is a read-only register.
GPOCON REGISTER
(RS2, RS1, RS0 = 1, 0, 1; Power-On/Reset = 0x00)
The GPOCON register is an 8-bit register from which data can
be read or to which data can be written. This register is used to
enable the general-purpose digital outputs.
Table 21 outlines the bit designations for the GPOCON register.
GP0 through GP7 indicate the bit locations. GP denotes that the
bits are in the GPOCON register. GP7 denotes the first bit of
the data stream. The number in parentheses indicates the
power-on/reset default status of that bit.
AD7190
Rev. B | Page 25 of 40
GP7 GP6 GP5 GP4 GP3 GP2 GP1 GP0
0(0) BPDSW(0) GP32EN(0) GP10EN(0) P3DAT(0) P2DAT(0) P1DAT(0) P0DAT(0)
Table 21. Register Bit Designations
Bit Location Bit Name Description
GP7 0 This bit must be programmed with a Logic 0 for correct operation.
GP 6 BPDSW Bridge power-down switch control bit. This bit is set by the user to close the bridge power-down switch
BPDSW to AGND. The switch can sink up to 30 mA. The bit is cleared by the user to open the bridge power-
down switch. When the ADC is placed in power-down mode, the bridge power-down switch remains active.
GP5 GP32EN Digital Output P3 and Digital Output P2 enable. When GP32EN is set, the digital outputs, P3 and P2, are
active. When GP32EN is cleared, the P3 and P2 pins are tristated, and the P3DAT and P2DAT bits are ignored.
GP4 GP10EN Digital Output P1 and Digital Output P0 enable. When GP10EN is set, the digital outputs, P1 and P0, are
active. When GP10EN is cleared, the P1 and P0 outputs are tristated, and the P1DAT and P0DAT bits are
ignored. The P1 and P0 pins can be used as a reference input REFIN2 when the REFSEL bit in the
configuration register is set to 1.
GP3 P3DAT Digital Output P3. When GP32EN is set, the P3DAT bit sets the value of the P3 general-purpose output pin.
When P3DAT is high, the P3 output pin is high. When P3DAT is low, the P3 output pin is low. When the
GPOCON register is read, the P3DAT bit reflects the status of the P3 pin if GP32EN is set.
GP2 P2DAT
Digital Output P2. When GP32EN is set, the P2DAT bit sets the value of the P2 general-purpose output pin.
When P2DAT is high, the P2 output pin is high. When P2DAT is low, the P2 output pin is low. When the
GPOCON register is read, the P2DAT bit reflects the status of the P2 pin if GP32EN is set.
GP1 P1DAT
Digital Output P1. When GP10EN is set, the P1DAT bit sets the value of the P1 general-purpose output pin.
When P1DAT is high, the P1 output pin is high. When P1DAT is low, the P1 output pin is low. When the
GPOCON register is read, the P1DAT bit reflects the status of the P1 pin if GP10EN is set.
GP0 P0DAT
Digital Output P0. When GP10EN is set, the P0DAT bit sets the value of the P0 general-purpose output pin.
When P0DAT is high, the P0 output pin is high. When P0DAT is low, the P0 output pin is low. When the
GPOCON register is read, the P0DAT bit reflects the status of the P0 pin if GP10EN is set.
OFFSET REGISTER
(RS2, RS1, RS0 = 1, 1, 0; Power-On/Reset = 0x800000)
The offset register holds the offset calibration coefficient for the
ADC. The power-on reset value of the offset register is 0x800000.
The AD7190 has four offset registers; therefore, each channel
has a dedicated offset register. Each of these registers is a 24-bit
read/write register. This register is used in conjunction with its
associated full-scale 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 AD7190
must be placed in power-down mode or idle mode when writing
to the offset register.
FULL-SCALE REGISTER
(RS2, RS1, RS0 = 1, 1, 1; Power-On/Reset = 0x5XXXX0)
The full-scale register is a 24-bit register that holds the full-scale
calibration coefficient for the ADC. The AD7190 has four full-
scale registers; therefore, each channel has a dedicated full-scale
register. The full-scale registers are read/write registers. However,
when writing to the full-scale registers, the ADC must be placed
in power-down mode or idle mode. These registers are configured
at power-on with factory-calibrated, full-scale calibration coef-
ficients, the calibration being performed at gain = 1. Therefore,
every device has different default coefficients. The default value
is automatically overwritten if an internal or system full-scale
calibration is initiated by the user or if the full-scale register is
written to.
AD7190
Rev. B | Page 26 of 40
ADC CIRCUIT INFORMATION
MCLK1 MCLK2 P0/REFIN2(–) P1/REFIN2(+)
DV
DD
DGND
5
V
AIN1
IN+
IN–
OUT– OUT+ AIN2
AIN3
AIN4
AINCOM
REFIN1(–)
BPDSW
AGND
AD7190
REFIN1(+) REFERENCE
DETECT
SERIAL
INTERFACE
AND
CONTROL
LOGIC
TEMP
SENSOR
CLOCK
CIRCUITRY
AV
DD
AGND
DOUT/RDY
DIN
SCLK
CS
SYNC
P3
P2
AV
DD
AGND
Σ-Δ
ADC
PGA
MUX
0
7640-012
Figure 18. Basic Connection Diagram
OVERVIEW
The AD7190 is an ultralow noise ADC that incorporates a
∑-∆ modulator, a buffer, PGA, and on-chip digital filtering
intended for the measurement of wide dynamic range signals
such as those in pressure transducers, weigh scales, and strain
gauge applications.
The part can be configured to have two differential inputs or four
pseudo differential inputs that can be buffered or unbuffered.
Figure 18 shows the basic connections required to operate the part.
FILTER, OUTPUT DATA RATE, SETTLING TIME
A ∑-∆ ADC consists of a modulator followed by a digital filter.
The AD7190 has two filter options: a sinc3 filter and a sinc4
filter. The filter is selected using the SINC3 bit in the mode
register. When SINC3 is set to 0 (default value), the sinc4 filter is
selected. The sinc3 filter is selected when SINC3 is set to 1.
At low output data rates (<1 kHz), the noise-free resolution is
comparable for the two filter types. However, at the higher
output data rates, the sinc4 filter gives better noise free
resolution.
The sinc4 filter also leads to better 50 Hz and 60 Hz rejection.
While the notch positions are not affected by the order of the
filter, the higher order filter has wider notches, which leads to
better rejection in the band (±1 Hz) around the notches. It also
gives better stop-band attenuation. The benefit of the sinc3 filter
is its lower settling time for the same output data rate.
Chop Disabled
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/(1024 × FS[9:0])
where:
fADC is the output data rate.
fCLK = master clock (4.92 MHz nominal).
FS[9:0] is the decimal equivalent of Bit FS9 to Bit FS0 in the
mode register.
The output data rate can be programmed from 4.7 Hz to 4800 Hz;
that is, FS[9:0] can have a value from 1 to 1023.
The previous equation is valid for both the sinc3 and sinc4
filters. The settling time for the sinc4 filter is equal to
tSETTLE = 4/fADC
Whereas the settling time for the sinc3 filter is equal to
tSETTLE = 3/fADC
Figure 19 and Figure 20 show the frequency response of the sinc4
and sinc3 filters, respectively, for an output data rate of 50 Hz.
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 0 255075100125150
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-013
Figure 19. Sinc4 Filter Response (50 Hz Output Data Rate)
AD7190
Rev. B | Page 27 of 40
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 0 255075100125150
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-014
Figure 20. Sinc3 Filter Response (50 Hz Output Data Rate)
The sinc4 filter provides 50 Hz (±1 Hz) rejection in excess of
120 dB, assuming a stable master clock, while the sinc3 filter
gives a rejection of 100 dB. The stop-band attenuation is
typically 53 dB for the sinc4 filter but equal to 40 dB for the
sinc3 filter.
The 3 dB frequency for the sinc4 filter is equal to
f3dB = 0.23 × fADC
and for the sinc3 filter is equal to
f3dB = 0.272 × fADC
Chop Enabled
With chop enabled, the ADC offset and offset drift are
minimized. When chop is enabled, the analog input pins are
continuously swapped. Therefore, with the analog input pins
connected in one direction, the settling time of the sinc filter is
allowed to elapse until a valid conversion is available. The analog
input pins are then inverted and another valid conversion is
obtained. Subsequent conversions are then averaged so that the
offset is minimized. This continuous swapping of the analog
input pins and the averaging of subsequent conversions means
that the offset drift is also minimized.
Chopping affects the output data rate and settling time of the
ADC. For the sinc4 filter, the output data rate is equal to
fADC = fCLK/(4 × 1024 × FS[9:0])
For sinc3 filter, the output data rate is equal to
fADC = fCLK/(3 × 1024 × FS[9:0])
where:
fADC is the output data rate.
fCLK = master clock (4.92 MHz nominal).
FS[9:0] is the decimal equivalent of Bit FS9 to Bit FS0 in the
mode register.
The value of FS[9:0] can be varied from 1 to 1023. This results
in an output data rate of 1.173 Hz to 1200 Hz for the sinc4 filter
and 1.56 Hz to 1600 Hz for the sinc3 filter. The settling time for
the sinc3 or sinc4 filter is equal to
tSETTLE = 2/fADC
Therefore, with chop enabled, the settling time is reduced for a
given output data rate compared to the chop disabled mode.
However, for a given FS[9:0] value, the output data rate is less
with chop enabled compared with the chop disabled mode.
For either the sinc3 or the sinc4 filter, the cutoff frequency f3dB is
equal to
f3dB = 0.24 × fADC
Figure 21 and Figure 22 show the filter response for the sinc4
and sinc3 filters, respectively, when chop is enabled. As shown
in the plots, the stop-band attenuation is less compared with the
chop disabled modes.
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 0 255075100125150
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-015
Figure 21. Sinc4 Filter Response (Output Data Rate = 12.5 Hz, Chop Enabled)
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 0 255075100125150
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-016
Figure 22. Sinc3 Filter Response (Output Data Rate = 16.6 Hz, Chop Enabled)
AD7190
Rev. B | Page 28 of 40
50 Hz/60 Hz Rejection
Normal mode rejection is one of the main functions of the
digital filter. With chop disabled, 50 Hz rejection is obtained
when the output data rate is set to 50 Hz, whereas 60 Hz
rejection is achieved when the output data rate is set to 60 Hz.
Simultaneous 50 Hz/60 Hz rejection is obtained when the
output data rate is set to 10 Hz. Simultaneous 50 Hz/60 Hz
rejection can also be achieved using the REJ60 bit in the mode
register. When the output data rate is programmed to 50 Hz and
the REJ60 bit is set to 1, notches are placed at both 50 Hz and
60 Hz.
Figure 23 and Figure 24 show the frequency response of the
sinc4 and sinc3 filters, respectively, when the output data rate is
programmed to 50 Hz and REJ60 is set to 1.
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 0 255075100125150
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-017
Figure 23. Sinc4 Filter Response (50 Hz Output Data Rate, REJ60 = 1)
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 0 255075100125150
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-018
Figure 24. Sinc3 Filter Response (50 Hz Output Data Rate, REJ60 = 1)
Again, the sinc4 filter provides better 50 Hz/60 Hz rejection
than the sinc3 filter. In addition, better stop-band attenuation is
achieved with the sinc4 filter.
When chop is enabled, lower output data rates must be used to
achieve 50 Hz and 60 Hz rejection. With REJ60 set to 1, an output
data rate of 12.5 Hz gives simultaneous 50 Hz/60 Hz rejection
when the sinc4 filter is selected, whereas an output data rate of
16.7 Hz gives simultaneous 50 Hz/ 60 Hz rejection when the sinc3
filter is used. Figure 25 and Figure 26 show the filter response for
both output data rates when REJ60 is set to 1.
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 0 255075100125150
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-125
Figure 25. Sinc4 Filter Response (12.5 Hz Output Data Rate,
Chop Enabled, REJ60 = 1)
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 0 255075100125150
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-126
Figure 26. Sinc3 Filter Response (16.7 Hz Output Data Rate,
Chop Enabled, REJ60 = 1)
Zero Latency
Zero latency is enabled by setting the SINGLE bit in the mode
register to 1. With zero latency, the complete settling time is
allowed for each conversion. Therefore,
fADC = 1/tSETTLE
Zero latency means that the output data rate is constant
irrespective of the number of analog input channels enabled;
the user does not need to consider the effects of channel
changes on the output data rate. The disadvantages of zero
latency are the increased noise for a given output data rate
compared with the nonzero latency mode. For example, when
zero latency is not enabled, the AD7190 has a noise-free
resolution of 18.5 bits when the output data rate is 50 Hz and
the gain is set to 128. When zero latency is enabled, the ADC
has a resolution of 17.5 bits peak-to-peak when the output data
rate is 50 Hz. The filter response also changes. Figure 19 shows
the filter response for the sinc4 filter when the output data rate
is 50 Hz (zero latency disabled). Figure 27 shows the filter
response when zero latency is enabled and the output data rate
AD7190
Rev. B | Page 29 of 40
is 50 Hz (sinc4 filter); 50 Hz rejection is no longer achieved. The
ADC needs to operate with an output data rate of 12.5 Hz to
obtain 50 Hz rejection when zero latency is enabled. To obtain
simultaneous 50 Hz/60 Hz rejection, the REJ60 bit in the mode
register can be set when the output data rate is equal to 12.5 Hz.
The stop-band attenuation is considerably reduced also (3 dB
compared with 53 dB in the nonzero latency mode).
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100 010050 200 300 400 500150 250 350 450 550 600
FILTER GAIN (dB)
FREQUENCY (Hz )
07640-020
Figure 27. Sinc4 Filter Response (50 Hz Output Data Rate, Zero Latency)
Channel Sequencer
The AD7190 includes a channel sequencer, which simplifies
communications with the device in multichannel applications.
The sequencer also optimizes the channel throughput of the
device as the sequencer switches channels at the optimum rate
rather than waiting for instructions via the SPI interface.
Bits CH0 to Bit CH7 in the configuration register are used to
enable the required channels. In continuous conversion mode,
the ADC selects each of the enabled channels in sequence and
performs a conversion on the channel. The RDY pin goes low
when a valid conversion is available on each channel. When
several channels are enabled, the contents of the status register
should be attached to the 24-bit word so that the user can
identify the channel that corresponds to each conversion. To
attach the status register value to the conversion, Bit DAT_STA
in the mode register should be set to 1.
When several channels are enabled, the ADC must allow the
complete settling time to generate a valid conversion each time
that the channel is changed. The AD7190 takes care of this:
when a channel is selected, the modulator and filter are reset
and the RDY pin is taken high. The AD7190 then allows the
complete settling time to generate the first conversion.
RDY only goes low when a valid conversion is available. The
AD7190 then selects the next enabled channel and converts on
that channel. The user can then read the data register while the
ADC is performing the conversion on the next channel.
The time required to read a valid conversion from all enabled
channels is equal to
tSETTLE × Number of Enabled Channels
For example, if the sinc4 filter is selected, chop is disabled and
zero latency is disabled, conversions are available at 1/fADC when
converting on a single channel, where fADC is equal to the output
data rate. The settling time is equal to
tSETTLE = 4/fADC
The time required to sample N channels is
4/(fADC × N)
RDY
CONVERSIONS CHA NNE L A CHANNE L B
1/fADC
CHANNEL C
07640-019
Figure 28. Channel Sequencer
DIGITAL INTERFACE
As indicated in the On-Chip Registers section, the programmable
functions of the AD7190 are controlled using a set of on-chip
registers. Data is written to these registers via the serial interface
of the part. Read access to the on-chip registers is also provided
by this interface. All communication with the part 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 also determines which
register this read or write operation affects. Therefore, write
access to any of the other registers on the part begins with a write
operation to the communications register, followed by a write to
the selected register. A read operation from any other register
(except when 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 AD7190 consists of four signals: CS,
DIN, SCLK, and DOUT/RDY. The DIN line is used to transfer
data into the on-chip registers, whereas DOUT/RDY is used for
accessing 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 functions as a data ready signal also, the
line going 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 prior to the updating of the
data register 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 be used to decode the
AD7190 in systems where several components are connected to
the serial bus.
AD7190
Rev. B | Page 30 of 40
Figure 3 and Figure 4 show timing diagrams for interfacing to the
AD7190, with CS being used to decode the part. shows
the timing for a read operation from the output shift register of
the AD7190, and shows the timing for a write operation
to the input shift register. It is possible to read the same word
from the data register several times even though the DOUT/
Figure 3
Figure 4
RDY
line returns high after the first read operation. However, care
must be taken to ensure that the read operations have been com-
pleted before the next output update occurs. In continuous read
mode, the data register can be read only once.
The AD7190 can be configured to continuously convert or to
perform a single conversion. See Figure 29 through Figure 31.
Single Conversion Mode
In single conversion mode, the AD7190 is placed in power-
down mode after conversions. When a single conversion is
initiated by setting MD2, MD1, and MD0 to 0, 0, 1, respectively,
in the mode register, the AD7190 powers up, performs a single
conversion, and then returns to power-down mode. The
on-chip oscillator requires 1 ms approximately to power up.
DOUT/RDY goes low to indicate the completion of a conversion.
When the data word has been read from the data register,
DOUT/RDY goes high. If CS is low, DOUT/RDY remains high
until another conversion is initiated and completed. The data
register can be read several times, if required, even when
DOUT/RDY has gone high.
The serial interface can operate in 3-wire mode by tying CS low.
In this case, the SCLK, DIN, and DOUT/RDY lines are used to
communicate with the AD7190. The end of the conversion can be
monitored using the RDY bit or pin. 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.
If several channels are enabled, the ADC 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. 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
power-down mode.
The AD7190 can be operated with CS used as a frame synchron-
ization 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. The
SCLK can continue to run between data transfers, provided the
timing numbers are obeyed.
The serial interface can be reset by writing a series of 1s to the
DIN input. If a Logic 1 is written to the AD7190 DIN line for at
least 40 serial clock cycles, the serial interface is reset. This ensures
that the interface can be reset to a known state if the interface gets
lost due to a software error or some glitch in the system. Reset
returns the interface to the state in which it is expecting a write to
the communications register. This operation resets the contents of
all registers to their power-on values. Following a reset, the user
should allow a period of 500 μs before addressing the serial
interface.
If the DAT_STA bit in the mode 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.
DIN
SCLK
DOUT/RDY
CS
0x08 0x58
DATA
0x280060
07640-021
Figure 29. Single Conversion
AD7190
Rev. B | Page 31 of 40
Continuous Conversion Mode
Continuous conversion is the default power-up mode. The
AD7190 converts continuously, the RDY bit in the status
register going low each time a conversion is complete. If CS is
low, the DOUT/RDY line also goes low when a conversion is
completed. To read a conversion, the user writes to the com-
munications register, indicating that the next operation is a read
of the data register. When the data word has been 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 or else the new conversion
word is lost.
When several channels are enabled, the ADC continuously
loops through the enabled channels, performing one conversion
on each channel per loop. 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 on the next enabled channel.
If the DAT_STA bit in the mode 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 status register indicates
the channel to which the conversion corresponds.
DIN
SCLK
DOUT/RDY
CS
0x58 0x58
DATA DATA
07640-022
Figure 30. Continuous Conversion
AD7190
Rev. B | Page 32 of 40
Continuous Read
Rather than write to the communications register each time a
conversion is complete to access the data, the AD7190 can be
configured so that the conversions are placed on the DOUT/
RDY line automatically. By writing 01011100 to the commun-
ications register, the user need only apply the appropriate
number of SCLK cycles to the ADC, and the conversion word
is automatically placed on the DOUT/RDY line when a
conversion is complete. The ADC should be configured for
continuous conversion mode.
When DOUT/RDY goes low to indicate the end of a conversion,
sufficient SCLK cycles must be applied to the ADC; the data
conversion is then placed on the DOUT/RDY line. 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. Also, the user must 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 AD7190 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.
To exit the continuous read mode, the instruction 01011000
must be written to the communications register while the
RDY pin is low. While in the continuous read mode, the ADC
monitors activity on the DIN line so that it can receive the
instruction to exit the continuous read mode. Additionally, a
reset occurs if 40 consecutive 1s are seen on DIN. Therefore,
DIN should be held low in continuous read mode until an
instruction is to be written to the device.
When several channels are enabled, the ADC continuously
steps through the enabled channels and performs one con-
version on each channel each time that it is selected. DOUT/
RDY pulses low when a conversion is available. When the user
applies sufficient SCLK pulses, the data is automatically placed
on the DOUT/RDY pin. If the DAT_STA bit in the mode
register is set to 1, the contents of the status register are output
along with the conversion. The status register indicates the
channel to which the conversion corresponds.
DIN
SCLK
DOUT/RDY
CS
0x5C
DATA DATA DATA
0
7640-023
Figure 31. Continuous Read
AD7190
Rev. B | Page 33 of 40
CIRCUIT DESCRIPTION
ANALOG INPUT CHANNEL
The AD7190 has two differential/four pseudo differential analog
input channels which can be buffered or unbuffered. In buffered
mode (the BUF bit in the configuration register is set to 1), 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 gauges or resistance
temperature detectors (RTDs).
When BUF = 0, the part is operated in unbuffered mode. This
results in a higher analog input current. Note that this unbuffered
input path provides a dynamic load to the driving source.
Therefore, resistor/capacitor combinations on the input pins
can cause gain errors, depending on the output impedance of
the source that is driving the ADC input. Table 22 shows the
allowable external resistance/capacitance values for unbuffered
mode at a gain of 1 such that no gain error at the 20-bit level is
introduced.
Table 22. External R-C Combination for No 20-Bit Gain Error
C (pF) R (Ω)
50 1.4 k
100 850
500 300
1000 230
5000 30
The absolute input voltage range in buffered mode is restricted
to a range between AGND + 250 mV and AVDD – 250 mV. Care
must be taken in setting up the common-mode voltage so that
these limits are not exceeded. Otherwise, there is degradation in
linearity and noise performance.
The absolute input voltage in unbuffered mode includes the
range between AGND – 50 mV and AVDD + 50 mV. The
negative absolute input voltage limit does allow the possibility
of monitoring small true bipolar signals with respect to AGND.
PGA
When the gain stage is enabled, the output from the buffer is
applied to the input of the programmable gain array (PGA).
The presence of the PGA means that signals of small amplitude
can be gained within the AD7190 while still maintaining excel-
lent noise performance. For example, when the gain is set to
128, the rms noise is 8.5 nV, typically, when the output data rate
is 4.7 Hz, which is equivalent to 23 bits of effective resolution or
20.5 bits of noise-free resolution.
The AD7190 can be programmed to have a gain of 1, 8, 16, 32,
64, and 128 using Bit G2 to Bit G0 in the configuration register.
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.
The analog input range must be limited to (AVDD − 1.25 V)/gain
because the PGA requires some headroom. Therefore, if AVDD =
5 V, the maximum analog input that can be applied to the
AD7190 is 0 to 3.75 V/gain in unipolar mode or ±3.75 V/ gain
in bipolar mode.
BIPOLAR/UNIPOLAR CONFIGURATION
The analog input to the AD7190 can accept either unipolar or
bipolar input voltage ranges. A bipolar input range does not
imply that the part can tolerate negative voltages with respect
to system AGND. In pseudo-differential mode, signals are
referenced to AINCOM while in differential mode, signals are
referenced to the negative input of the differential pair. For
example, if AINCOM is 2.5 V and the AD7190 AIN1 analog
input is configured for unipolar mode with a gain of 2, the input
voltage range on the AIN1 pin is 2.5 V to 3.75 V when a 2.5 V
reference is used. If AINCOM is 2.5 V and the AD7190 AIN1
analog input is configured for bipolar mode with a gain of 2, the
analog input range on AIN1 is 1.25 V to 3.75 V.
The bipolar/unipolar option is chosen by programming the U/B
bit in the configuration register.
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:
AIN is the analog input voltage.
gain is the PGA setting (1 to 128).
N = 24.
CLOCK
The AD7190 includes an internal 4.92 MHz clock on-chip. This
internal clock has a tolerance of ±4%. Either the internal clock
or an external crystal/clock can be used as the clock source to
the AD7190. The clock source is selected using the CLK1 and
CLK0 bits in the mode register. When an external crystal is
used, it must be connected across the MCLK1 and MCLK2
pins. The crystal manufacturer recommends the load capaci-
tances required for the crystal. The MCLK1 and MCLK2 pins of
the AD7190 have a capacitance of 15 pF, typically. If an external
AD7190
Rev. B | Page 34 of 40
clock source is used, the clock source must be connected to the
MCLK2 pin and the MCLK1 pin must be left floating.
The internal clock can also be made available at the MCLK2
pin. This is useful when several ADCs are used in an application
and the devices need to 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 syn-
chronized by applying a common reset to all devices, or the
SYNC pin can be pulsed.
BURNOUT CURRENTS
The AD7190 contains two 500 nA constant current generators,
one sourcing current from AVDD to AIN(+) and one sinking
current from AIN(−) to AGND, where AIN(+) is the positive
analog input terminal and AIN(−) is the negative analog input
terminal in differential mode and AINCOM in pseudo-
differential mode. The currents are switched to the selected
analog input pair. Both currents are either on or off, depending
on the burnout current enable (burn) bit in the configuration
register. These currents can be used to verify that an external
transducer remains 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. It will take some time for the burnout currents to
detect an open circuit condition as the currents will need to
charge any external capacitors
There are several reasons why a fault condition can be detected.
The front-end sensor may be open circuit. It could also mean
that the front-end sensor is overloaded, or the reference may be
absent and the NOREF bit in the status register is set, thus
clamping the data to all 1s. The user needs to check these three
cases before making a judgment. If the voltage measured is 0 V,
it may indicate that the transducer has short circuited. The
current sources work over the normal absolute input voltage
range specifications when the analog inputs are buffered and
chop is disabled.
REFERENCE
The ADC has a fully differential input capability for the refer-
ence channel. In addition, the user has the option of selecting
one of two external reference options (REFIN1(x) or REFIN2(x)).
The reference source for the AD7190 is selected using the
REFSEL bit in the configuration register. The REFIN2(x) pins
are dual purpose: they can function as two general-purpose
output pins or as reference pins. When the REFSEL bit is set
to 1, these pins automatically function as reference pins.
The common-mode range for these differential inputs is from
AGND to AVDD. The reference input is unbuffered; therefore,
excessive R-C source impedances introduce gain errors. The
reference voltage REFIN (REFINx(+) − REFINx(−)) is AVDD
nominal, but the AD7190 is functional with reference voltages
from 1 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 part, the effect of the low frequency
noise in the excitation source is removed because the application is
ratiometric. If the AD7190 is used in a nonratiometric applica-
tion, use a low noise reference.
Recommended 2.5 V reference voltage sources for the AD7190
include the ADR421 and ADR431, which are low noise
references. Also note that the reference inputs provide a high
impedance, dynamic load. Because the input impedance of each
reference input is dynamic, resistor/capacitor combinations on
these inputs can cause dc gain errors, depending on the output
impedance of the source driving the reference inputs.
Reference voltage sources like those previously recommended
(for example, ADR431) 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. External decoupling on the REFINx pins is not
recommended in this type of circuit configuration.
REFERENCE DETECT
The AD7190 includes on-chip circuitry to detect whether the
part has a valid reference for conversions or calibrations. This
feature is enabled when the REFDET bit in the configuration
register is set to 1. If the voltage between the selected REFINx(+)
and REFINx(–) pins is between 0.3 V and 0.6 V, the AD7190
detects that it no longer has a valid reference. In this case, the
NOREF bit of the status register is set to 1. If the AD7190 is
performing normal conversions and the NOREF bit becomes
active, the conversion result is all 1s. Therefore, it is not
necessary to continuously monitor the status of the NOREF 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 AD7190 is performing either an offset or full-
scale calibration and the NOREF bit becomes active, the
updating of the respective calibration registers is inhibited to
avoid loading incorrect coefficients to these registers, and the
ERR bit in the status register 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 ERR bit at the
end of the calibration cycle.
RESET
The circuitry and serial interface of the AD7190 can be reset
by writing consecutive 1s to the device; 40 consecutive 1s are
required to perform the reset. This resets the logic, the digital
filter, and the analog modulator, whereas all on-chip registers
are reset to their default values. A reset is automatically
performed on power-up. When a reset is initiated, the user
must allow a period of 500 μs before accessing any of the
on-chip registers. A reset is useful if the serial interface loses
synchronization due to noise on the SCLK line.
AD7190
Rev. B | Page 35 of 40
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
part. 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. SYNC needs to be taken low for four master clock cycles
to implement the synchronization function.
If multiple AD7190 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 AD7190
into a consistent, known state. While the SYNC pin is low, the
AD7190 is maintained in this state. On the SYNC rising edge,
the modulator and filter are taken out of this reset state and, on
the next clock edge, the part starts to gather input samples again.
In a system using multiple AD7190 devices, a common signal to
their SYNC pins synchronizes their operation. This is normally
done after each AD7190 has performed its own calibration or
has had calibration coefficients loaded into its calibration
registers. The conversions from the AD7190s are then
synchronized.
The part is taken out of reset on the master clock falling edge
following the SYNC low-to-high transition. Therefore, when
multiple devices are being synchronized, the SYNC pin should
be taken 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 part to part 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 disadvantage of this scheme is that the settling time of the
filter has to be allowed for each data register update. This means
that the rate at which the data register is updated is reduced. For
example, if the ADC is configured to use the sinc4 filter, zero
latency is disabled and chop is disabled, the data register update
takes four times longer.
TEMPERATURE SENSOR
Embedded in the AD7190 is a temperature sensor. This is
selected using the CH2 bit in the configuration register. When
the CH2 bit is set to 1, the temperature sensor is enabled. When
the temperature sensor is selected and bipolar mode is selected,
the device should return a code of 0x800000 when the temper-
ature is 0 K. A one-point calibration is needed to get the optimum
performance from the sensor. Therefore, a conversion at 25°C
should be recorded and the sensitivity calculated. The sensitivity
is approximately 2815 codes/°C. The equation for the temperature
sensor is
Temp (K) = (Conversion – 0x800000)/2815 K
Temp (°C) = Temp (K) – 273
Following the one point calibration, the internal temperature
sensor has an accuracy of ±2 °C, typically.
BRIDGE POWER-DOWN SWITCH
In bridge applications such as strain gauges and load cells, the
bridge itself consumes the majority of the current in the system.
For example, a 350  load cell requires 15 mA of current when
excited with a 5 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. Figure 18
shows how the bridge power-down switch is used. The switch
can withstand 30 mA of continuous current, and it has an on
resistance of 10  maximum.
LOGIC OUTPUTS
The AD7190 has four general-purpose digital outputs, P0, P1,
P2, and P3. These are enabled using the GP32EN and GP10EN
bits in the GPOCON register. The pins can be pulled high or
low using the P0DAT to P3DAT bits in the GPOCON register;
that is, the value at the pin is determined by the setting of the
P0DAT to P3DAT bits. The logic levels for these pins are
determined by AVDD rather than by DVDD. When the GPOCON
register is read, the P0DAT to P3DAT 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 AD7190 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 AD7190, the AD7190 modulator and filter
should be reset using the SYNC pin each time that the multi-
plexer channel is changed.
AD7190
Rev. B | Page 36 of 40
ENABLE PARITY
The AD7190 also has a parity check function on-chip that
detects 1-bit errors in the serial communications between the
ADC and the microprocessor. When the ENPAR bit in the
mode register is set to 1, parity is enabled. The contents of the
status register must be transmitted along with each 24-bit
conversion when the parity function is enabled. To append the
contents of the status register to each conversion read, the
DAT_STA bit in the mode register should be set to 1. For each
conversion read, the parity bit in the status register is
programmed so that the overall number of 1s transmitted in the
24-bit data-word is even. Therefore, for example, if the 24-bit
conversion contains eleven 1s (binary format), the parity bit is
set to 1 so that the total number of 1s in the serial transmission is
even. If the microprocessor receives an odd number of 1s, it
knows that the data received has been corrupted.
The parity function only detects 1-bit errors. For example, two
bits of corrupt data can result in the microprocessor receiving an
even number of 1s. Therefore, an error condition is not detected.
CALIBRATION
The AD7190 provides four calibration modes that can be pro-
grammed via the mode bits in the mode register. These modes
are internal zero-scale calibration, internal full-scale calibration,
system zero-scale calibration, and system full-scale calibration.
A calibration can be performed at any time by setting the MD2
to MD0 bits in the mode register appropriately. A calibration
should be performed when the gain is changed. After each
conversion, the ADC conversion result is scaled using the ADC
calibration registers before being written to the data register.
The offset calibration coefficient is subtracted from the result
prior to multiplication by the full-scale coefficient.
To start a calibration, write the relevant value to the MD2 to
MD0 bits. The DOUT/RDY pin and the RDY bit in the status
register go high when the calibration is initiated. When the
calibration is complete, the contents of the corresponding
calibration registers are updated, the RDY bit in the status
register is reset, the DOUT/ RDY pin returns low (if CS is low),
and the AD7190 reverts to idle mode.
During an internal zero-scale or full-scale calibration, the res-
pective zero input and full-scale input are automatically connected
internally to the ADC input pins. A system calibration, however,
expects the system zero-scale and system full-scale voltages to
be applied to the ADC pins before initiating the calibration
mode. In this way, errors external to the ADC are removed.
From an operational point of view, treat a calibration like
another ADC conversion. A zero-scale calibration, if required,
must always be performed before a full-scale calibration. Set the
system software to monitor the RDY bit in the status register or
the DOUT/RDY pin to determine the end of calibration via a
polling sequence or an interrupt-driven routine.
With chop disabled, both an internal zero-scale calibration and
a system zero-scale calibration require a time equal to the
settling time, tSETTLE, (4/fADC for the sinc4 filter and 3/fADC for the
sinc3 filter).
With chop enabled, an internal zero-scale calibration is not
needed because the ADC itself minimizes the offset continuously.
However, if an internal zero-scale calibration is performed, the
settling time, tSETTLE, (2/fADC) is required to perform the calibra-
tion. Similarly, a system zero-scale calibration requires a time of
tSETTLE to complete.
To perform an internal full-scale calibration, a full-scale input
voltage is automatically connected to the selected analog input
for this calibration. For a gain of 1, the time required for an
internal full-scale calibration is equal to tSETTLE. For higher gains,
the internal full-scale calibration requires a time of 2 × tSETTLE.
A full-scale calibration is recommended each time the gain of a
channel is changed to minimize the full-scale error.
A system full-scale calibration requires a time of tSETTLE. With
chop disabled, the zero-scale calibration (internal or system
zero-scale) should be performed before the system full-scale
calibration is initiated.
An internal zero-scale calibration, system zero-scale calibration
and system full-scale calibration can be performed at any output
data rate. An internal full-scale calibration can be performed at
any output data rate for which the filter word FS[9:0] is divisible
by 16, FS[9:0] being the decimal equivalent of the 10-bit word
written to Bit FS9 to Bit FS0 in the mode register. Therefore,
internal full-scale calibrations can be performed at output data
rates such as 10 Hz or 50 Hz when chop is disabled. Using these
lower output data rates results in better calibration accuracy.
The offset error is, typically, 100 µV/gain. If the gain is changed,
it is advisable to perform a calibration. A zero-scale calibration
(an internal zero-scale calibration or system zero-scale
calibration) reduces the offset error to the order of the noise.
The gain error of the AD7190 is factory calibrated at a gain of 1
with a 5 V power supply at ambient temperature. Following this
calibration, the gain error is 0.001%, typically, at 5 V. Tabl e 2 3
shows the typical uncalibrated gain error for the different gain
settings. An internal full-scale calibration reduces the gain error
to 0.001%, typically, when the gain is equal to 1. For higher
gains, the gain error post internal full-scale calibration is
0.0075%, typically. A system full-sale calibration reduces the
gain error to the order of the noise.
Table 23. Typical Precalibration Gain Error vs. Gain
Gain Precalibration Gain Error (%)
8 −0.11
16 −0.20
32 −0.23
64 −0.29
128 −0.39
AD7190
Rev. B | Page 37 of 40
The AD7190 gives the user access to the on-chip calibration
registers, allowing the microprocessor to read the calibration
coefficients of the device and also to write its own calibration
coefficients from prestored values in the EEPROM. A read of
the registers can be performed at any time. However, the ADC
must be placed in power-down or idle mode when writing to
the registers. The values in the calibration registers are 24-bits
wide. The span and offset of the part can also be manipulated
using the registers.
GROUNDING AND LAYOUT
Because the analog inputs and reference inputs are differential,
most of the voltages in the analog modulator are common-
mode voltages. The high common-mode rejection of the part
removes common-mode noise on these inputs. The analog and
digital supplies to the AD7190 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 modulator sampling frequency.
Connect an R-C filter to each analog input pin to provide
rejection at the modulator sampling frequency. A 100 Ω
resistor in series with each analog input, a 0.1 F capacitor
between the analog inputs along with a 0.01 F capacitor from
each analog input to AGND is advised. The digital filter also
removes noise from the analog and reference inputs provided
these noise sources do not saturate the analog modulator. As a
result, the AD7190 is more immune to noise interference than a
conventional high resolution converter. However, because the
resolution of the AD7190 is so high and the noise levels from
the converter so low, care must be taken with regard to grounding
and layout.
The printed circuit board (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. This facilitates the
use of ground planes that can be easily separated. A minimum
etch technique is generally best for ground planes because it
gives the best shielding.
Although the AD7190 has separate pins for analog and digital
ground, the AGND and DGND pins are tied together internally
via the substrate. Therefore, the user must not tie these two
pins to separate ground planes unless the ground planes are
connected together near the AD7190.
In systems in which the AGND and DGND are connected
somewhere else in the system (that is, the power supply of the
system), they should not be connected again at the AD7190
because a ground loop results. In these situations, it is
recommended that ground pins of the AD7190 be tied to the
AGND plane.
In any layout, the user must keep in mind the flow of currents
in the system, ensuring that the paths for all currents are as close
as possible to the paths the currents took to reach their destin-
ations. Avoid forcing digital currents to flow through the AGND.
Avoid running digital lines under the device because this
couples noise onto the die and allow the analog ground plane to
run under the AD7190 to prevent noise coupling. The power
supply lines to the AD7190 must use as wide a trace as possible
to provide low impedance paths and reduce the effects of
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 through 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.
Decouple all analog supplies with 10 F tantalum in parallel with
0.1 F capacitors to AGND. To achieve the best from these
decoupling components, place them as close as possible to the
device, ideally right up against the device. Decouple all logic chips
with 0.1 F ceramic capacitors to DGND. In systems in which a
common supply voltage is used to drive both the AVDD and DVDD
of the AD7190, it is recommended that the system AVDD supply
be used. For this supply, place the recommended analog supply
decoupling capacitors between the AVDD pin of the AD7190 and
AGND and the recommended digital supply decoupling
capacitor between the DVDD pin of the AD7190 and DGND.
AD7190
Rev. B | Page 38 of 40
APPLICATIONS INFORMATION
The AD7190 provides a low-cost, high resolution analog-to-
digital function. Because the analog-to-digital function is
provided by a ∑-∆ architecture, it makes the part more
immune to noisy environments, making it ideal for use in
sensor measurement and industrial and process control
applications.
WEIGH SCALES
Figure 32 shows the AD7190 being used in a weigh scale
application. The load cell is arranged in a bridge network and
gives a differential output voltage between its OUT+ and OUT
terminals. Assuming a 5 V excitation voltage, the full-scale
output range from the transducer is 10 mV when the sensitivity
is 2 mV/V. The excitation voltage for the bridge can be used to
directly provide the reference for the ADC because the reference
input range includes the supply voltage.
A second advantage of using the AD7190 in transducer-based
applications is that the bridge power-down switch can be fully
utilized to minimize the power consumption of the system. The
bridge power-down switch is connected in series with the cold
side of the bridge. In normal operation, the switch is closed and
measurements can be taken. In applications in which current
consumption is being minimized, the AD7190 can be placed in
standby mode, thus significantly reducing the power consumed
in the application. In addition, the bridge power-down switch
can be opened while in standby mode, thus avoiding unnecessary
power consumption by the front-end transducer. When the part
is taken out of standby mode and the bridge power-down switch
is closed, the user should ensure that the front-end circuitry is
fully settled before attempting a read from the AD7190.
For simplicity, external filters are not included in Figure 32.
However, an R-C antialias filter should be included on each
analog input. This is required because the on-chip digital filter
does not provide any rejection around the modulator sampling
frequency or multiples of this frequency. Suitable values are a
100  resistor in series with each analog input, a 0.1 F capa-
citor between the analog inputs and 0.01 F capacitors from
each analog input pin to AGND.
MCLK1 MCLK2 P0/REFIN2(–) P1/REFIN2(+)
DV
DD
DGND
5
V
AIN1
IN+
IN–
OUT– OUT+ AIN2
AIN3
AIN4
AINCOM
REFIN1(–)
BPDSW
AGND
AD7190
REFIN1(+) REFERENCE
DETECT
SERIAL
INTERFACE
AND
CONTROL
LOGIC
TEMP
SENSOR
CLOCK
CIRCUITRY
AV
DD
AGND
DOUT/RDY
DIN
SCLK
CS
SYNC
P3
P2
AV
DD
AGND
Σ-Δ
ADC
PGA
MUX
0
7640-024
Figure 32. Typical Application (Weigh Scale)
AD7190
Rev. B | Page 39 of 40
OUTLINE DIMENSIONS
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
SEATING
PLANE
0.10 COPLANARITY
COMPLIANT TO JEDEC STANDARDS MO-153-AD
Figure 33. 24-Lead Thin Shrink Small Outline Package [TSSOP]
(RU-24)
Dimensions shown in millimeters
ORDERING GUIDE
Models Temperature Range Package Description Package Option
AD7190BRUZ1 –40°C to +105°C 24-Lead TSSOP RU-24
AD7190BRUZ-REEL1 –40°C to +105°C 24-Lead TSSOP RU-24
EVAL-AD7190EBZ1 Evaluation Board
1 Z = RoHS Compliant Part.
AD7190
Rev. B | Page 40 of 40
©2008–2009 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D07640-0-5/09(B)
NOTES