AD5260BRUZ20-REEL7 - Analog Devices, Inc.

REV. 0

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AD5260/AD5262

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781/329-4700www.analog.com

Fax: 781/326-8703 © Analog Devices, Inc., 2002

1-/2-Channel

15 V Digital Potentiometers

FEATURES

256 Positions

AD5260 – 1-Channel

AD5262 – 2-Channel (Independently Programmable)

Potentiometer Replacement

20 k⍀, 50 k⍀, 200 k⍀

Low Temperature Coefficient 35 ppm/ⴗC

4-Wire SPI-Compatible Serial Data Input

5 V to 15 V Single-Supply; ⴞ5.5 V Dual-Supply Operation

Power ON Mid-Scale Preset

APPLICATIONS

Mechanical Potentiometer Replacement

Instrumentation: Gain, Offset Adjustment

Stereo Channel Audio Level Control

Programmable Voltage to Current Conversion

Programmable Filters, Delays, Time Constants

Line Impedance Matching

Low Resolution DAC Replacement

GENERAL DESCRIPTION

The AD5260/AD5262 provide a single- or dual-channel, 256-

position, digitally controlled variable resistor (VR) device.* These

devices perform the same electronic adjustment function as a

potentiometer or variable resistor. Each channel of the AD5260/

AD5262 contains a fixed resistor with a wiper contact that taps the

fixed resistor value at a point determined by a digital code loaded

into the SPI-compatible serial-input register. The resistance between

the wiper and either end point of the fixed resistor varies linearly

with respect to the digital code transferred into the VR latch. The

variable resistor offers a completely programmable value of resistance,

between the A terminal and the wiper or the B terminal and the wiper.

The fixed A to B terminal resistance of 20 kW, 50 kW, or 200 kW has

a nominal temperature coefficient of 35 ppm/∞C. Unlike the majority

of the digital potentiometers in the market, these devices can operate

up to 15 V or ±5 V provided proper supply voltages are furnished.

Each VR has its own VR latch, which holds its programmed resistance

value. These VR latches are updated from an internal serial-to-parallel

shift register, which is loaded from a standard 3-wire serial-input

digital interface. The AD5260 contains an 8-bit serial register

while the AD5262 contains a 9-bit serial register. Each bit is clocked

into the register on the positive edge of the CLK. The AD5262

address bit determines the corresponding VR latch to be loaded

with the last 8 bits of the data word during the positive edging of

CS strobe. A serial data output pin at the opposite end of the serial

without additional external decoding logic. An optional reset pin

(PR) forces the wiper to the mid-scale position by loading 80

into

the VR latch.

*The terms digital potentiometers, VR, and RDAC are used interchangeably.

FUNCTIONAL BLOCK DIAGRAMS

RDAC

LOGIC

POWER-ON

RESET

SERIAL INPUT REGISTER

AD5260

HDN

CLK

SDI

GND

AWB

SDO

RDAC1 REGISTER

LOGIC

AD5262

HDN

CLK

SDI

GND

RDAC2 REGISTER

A1 W1 B1

SDO

A2 W2 B2

POWER-ON

RESET

SERIAL INPUT REGISTER

CODE – Decimal

100

064128192 256

PERCENT OF NOMINAL

END-TO-END RESISTANCE – % R

Figure 1. R

and R

vs. Code

The AD5260/AD5262 are available in thin surface-mount TSSOP-14

and TSSOP-16 packages. All parts are guaranteed to operate over

the extended industrial temperature range of –40∞C to +85∞C.

REV. 0

–2–

AD5260/AD5262–SPECIFICATIONS

(VDD = +15 V, VSS = 0 V or, VDD = +5 V, VSS = –5 V, VL = +5 V, VA = +5 V,

VB = 0 V, – 40ⴗC < TA < +85ⴗC unless otherwise noted.)

ELECTRICAL CHARACTERISTICS 20 kW, 50 kW, 200 kW VERSIONS

Parameter Symbol Conditions Min Typ

Max Unit

DC CHARACTERISTICS RHEOSTAT MODE Specifications apply to all VRs

Resistor Differential NL

R-DNL R

, V

=NC –1 ±1/4 +1 LSB

Resistor Nonlinearity

R-INL R

, V

=NC –1 ±1/2 +1 LSB

Nominal Resistor Tolerance

R

= 25∞C–30 30 %

Resistance Temperature Coefficient R

/TWiper = No Connect 35 ppm/∞C

Wiper Resistance R

= 1 V/R

60 150 W

Channel Resistance Matching (AD5262 only) R

Ch 1 and 2 R

WB,

0.1 %

Resistance Drift R

0.05 %

DC CHARACTERISTICS POTENTIOMETER DIVIDER MODE Specifications apply to all VRs

Resolution N 8 Bits

Differential Nonlinearity

DNL –1 ±1/4 +1 LSB

Integral Nonlinearity

INL –1 ±1/2 +1 LSB

Voltage Divider Temperature Coefficient DV

/DTCode = 80

5ppm/∞C

Full-Scale Error V

WFSE

Code = FF

–2 –1 +0 LSB

Zero-Scale Error V

WZSE

Code = 00

01 2LSB

RESISTOR TERMINALS

Voltage Range

A, B, W

Capacitance

Ax, Bx C

A,B

f = 5 MHz, 25 pF

measured to GND, Code = 80

Capacitance

Wx C

f = 1 MHz, 55 pF

measured to GND, Code = 80

Common-Mode Leakage Current I

= V

/2 1 nA

Shut Down Current

SHDN

5mA

DIGITAL INPUTS and OUTPUTS

Input Logic High V

2.4 V

Input Logic Low V

0.8 V

Input Logic High V

= 3 V, V

= 0 V 2.1 V

Input Logic Low V

= 3 V, V

= 0 V 0.6 V

Output Logic High (SDO) V

PULL-UP

= 2 kW to 5 V 4.9 V

Output Logic Low (SDO) V

= 1.6 mA, V

LOGIC

= 5 V 0.4 V

Input Current

= 0 V or 5 V ±1mA

Input Capacitance

5pF

POWER SUPPLIES

Logic Supply V

2.7 5.5 V

Power Single-Supply Range V

DD RANGE

= 0 V 4.5 16.5 V

Power Dual-Supply Range V

DD/SS RANGE

±4.5 ±5.5 V

Logic Supply Current I

=5 V 60 mA

Positive Supply Current I

= 5 V or V

= 0 V 1 mA

Negative Supply Current I

= –5 V 1 mA

Power Dissipation

DISS

= 5 V or V

= 0 V, 0.3 mW

= +5 V, V

= –5 V

Power Supply Sensitivity PSS DV

= +5 V, ±10% 0.003 0.01 %/%

DYNAMIC CHARACTERISTICS

6, 10

Bandwidth –3 dB BW R

= 20 kW/50 kW/200 kW310/130/30 kHz

Total Harmonic Distortion THD

= 1 V

RMS

, V

= 0 V, 0.014 %

f=1 kHz, R

= 20 kW

Settling Time t

= +5 V, V

= –5 V, 5 ms

±1 LSB error band, R

= 20 kW

Crosstalk

= V

, V

=0 V,

Measure V

with Adjacent

RDAC Making Full-Scale 1 nV–s

Code Change (AD5262 only)

Analog Crosstalk C

= V

, V

=0V,

Measure V

with

= 5 V p-p @ f = 10 kHz, –64 dB

= 20 kW/200 kW (AD5262 only)

Resistor Noise Voltage e

N_WB

= 20 kW13 nV/÷Hz

f = 1 kHz

REV. 0 –3–

AD5260/AD5262

Parameter Symbol Conditions Min Typ Max Unit

INTERFACE TIMING CHARACTERISTICS apply to all parts

6, 12

Clock Frequency f

CLK

25 MHz

Input Clock Pulsewidth t

, t

Clock level high or low 20 ns

Data Setup Time t

10 ns

Data Hold Time t

10 ns

CLK to SDO Propagation Delay

= 1 kΩ, C

< 20pF 1 160 ns

CS Setup Time t

CSS

5ns

CS High Pulsewidth t

CSW

20 ns

Reset Pulsewidth t

50 ns

CLK Fall to CS Rise Hold Time t

CSH

0ns

CS Rise to Clock Rise Setup t

CS1

10 ns

NOTES

The AD5260/AD5262 contains 1,968 transistors. Die Size: 89 mil. × 105 mil. 9,345 sq. mil.

Typicals represent average readings at 25°C and V

= +5 V, V

= –5 V.

Resistor position nonlinearity error R-INL is the deviation from an ideal value measured between the maximum resistance and the minimum resistance wiper positions.

R-DNL measures the relative step change from ideal between successive tap positions. Parts are guaranteed monotonic. I

= V

/R for both V

= +5 V, V

=–5V.

= V

, Wiper (V

) = No connect.

INL and DNL are measured at V

with the RDAC configured as a potentiometer divider similar to a voltage output D/A converter. VA = V

and V

= 0V. DNL

specification limits of ±1 LSB maximum are Guaranteed Monotonic operating conditions.

Resistor terminals A, B, W have no limitations on polarity with respect to each other.

Guaranteed by design and not subject to production test.

Measured at the Ax terminals. All Ax terminals are open-circuit in shutdown mode.

Worst-case supply current consumed when input all logic-input levels set at 2.4 V, standard characteristic of CMOS logic.

DISS

is calculated from (I

⫻ V

). CMOS logic level inputs result in minimum power dissipation.

All dynamic characteristics use V

= +5 V, V

= –5 V, V

= +5 V.

Measured at a V

pin where an adjacent V

pin is making a full-scale voltage change.

See timing diagram for location of measured values. All input control voltages are specified with t

= 2ns (10% to 90% of 3 V) and timed from a voltage level of 1.5 V.

Switching characteristics are measured using V

= 5 V.

Propagation delay depends on value of V

, R

, and C

Specifications subject to change without notice.

ABSOLUTE MAXIMUM RATINGS

= 25°C, unless otherwise noted.)

to GND . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V, +15 V

to GND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0 V, –7 V

to V

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 V

, V

to GND . . . . . . . . . . . . . . . . . . . . . . . . . . V

, V

– B

, A

– W

, B

– W

Intermittent

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±20 mA

Continuous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±5 mA

Digital Inputs and Output Voltage to GND . . . . . . . 0 V, 7 V

Operating Temperature Range . . . . . . . . . . . . –40°C to +85°C

Maximum Junction Temperature (T

J MAX

) . . . . . . . . . . . 150°C

Storage Temperature . . . . . . . . . . . . . . . . . . –65°C to +150°C

Lead Temperature (Soldering, 10 sec) . . . . . . . . . . . . 300°C

Vapor Phase (60 sec) . . . . . . . . . . . . . . . . . . . . . . . . 215°C

Infrared (15 sec) . . . . . . . . . . . . . . . . . . . . . . . . . . . 220°C

Thermal Resistance

TSSOP-14 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 206°C/W

TSSOP-16 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150°C/W

NOTES

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 listed in the operational sections of this

specification is not implied. Exposure to absolute maximum rating conditions for

extended periods may affect device reliability.

Maximum terminal current is bounded by the maximum current handling of the

switches, maximum power dissipation of the package, and maximum applied

voltage across any two of the A, B, and W terminals at a given resistance setting.

Package Power Dissipation = (T

J MAX

– T

)/ θ

REV. 0

–4–

AD5260/AD5262

CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily

accumulate on the human body and test equipment and can discharge without detection. Although

the AD5260/AD5262 features proprietary ESD protection circuitry, permanent damage may occur

on devices subjected to high-energy electrostatic discharges. Therefore, proper ESD precautions

are recommended to avoid performance degradation or loss of functionality.

WARNING!

ESD SENSITIVE DEVICE

ORDERING GUIDE

Package Package No. of Parts Branding

Model R

(kW)Temperature Description Option per Container Information

AD5260BRU20 20 –40∞C to +85∞CTSSOP-14 RU-14 96 AD5260B20

AD5260BRU20-REEL7 20 –40∞C to +85∞CTSSOP-14 RU-14 1000 AD5260B20

AD5260BRU50 50 –40∞C to +85∞CTSSOP-14 RU-14 96 AD5260B50

AD5260BRU50-REEL7 50 –40∞C to +85∞CTSSOP-14 RU-14 1000 AD5260B50

AD5260BRU200 200 –40∞C to +85∞CTSSOP-14 RU-14 96 AD5260B200

AD5260BRU200-REEL7 200 –40∞C to +85∞CTSSOP-14 RU-14 1000 AD5260B200

AD5262BRU20 20 –40∞C to +85∞CTSSOP-16 RU-16 96 AD5262B20

AD5262BRU20-REEL7 20 –40∞C to +85∞CTSSOP-16 RU-16 1000 AD5262B20

AD5262BRU50 50 –40∞C to +85∞CTSSOP-16 RU-16 96 AD5262B50

AD5262BRU50-REEL7 50 –40∞C to +85∞CTSSOP-16 RU-16 1000 AD5262B50

AD5262BRU200 200 –40∞C to +85∞CTSSOP-16 RU-16 96 AD5262B200

AD5262BRU200-REEL7 200 –40∞C to +85∞CTSSOP-16 RU-16 1000 AD5262B200

Line 1 contains part number, line 2 contains differentiating detail by part type and ADI logo symbol, line 3 contains date code YWW.

REV. 0 –5–

AD5260/AD5262

Table I. AD5260 8-Bit Serial-Data Word Format

DATA

B7 B6 B5 B4 B3 B2 B1 B0

D7 D6 D5 D4 D3 D2 D1 D0

MSB LSB

CLK 1

OUT

RDAC REGISTER LOAD

CS 1

D7 D6 D5 D4 D3 D2 D1 D0

SDI 1

Figure 2a. AD5260 Timing Diagram

RDAC REGISTER LOAD

D7 D6 D5 D4 D3 D2 D1 D0A0

CLK

OUT

SDI

Figure 2b. AD5262 Timing Diagram

Table II. AD5262 9-Bit Serial-Data Word Format

ADDR DATA

B8 B7 B6 B5 B4 B3 B2 B1 B0

A0 D7 D6 D5 D4 D3 D2 D1 D0

MSB LSB

SDI

(DATA IN)

SDO

(DATA OUT)

CLK

OUT

Ax OR Dx Dx

ⴕ

x OR D

ⴕ

tCSS

tDH

tPD_MAX

ⴞ1 LSB ERROR BAND

ⴞ1 LSB

tCSH

tCH

tCSW

tCL

tDS

tCS1

Figure 2c. Detail Timing Diagram

OUT

ⴞ1 LSB ERROR BAND ⴞ1 LSB

Figure 2d. Preset Timing Diagram

REV. 0

–6–

AD5260/AD5262

AD5260 PIN CONFIGURATION

TOP VIEW

(Not to Scale)

VDD

SHDN

CLK

SDI

SDO

VSS

AD5260

GND

AD5260 PIN FUNCTION DESCRIPTIONS

Number Mnemonic Description

1A A Terminal

2W Wiper Terminal

3B B Terminal

Positive power supply, specified

for operation at both 5 V or 15 V.

(Sum of |V

| + |V

| £ 15 V)

5SHDN Active low input. Terminal A

open-circuit. Shutdown controls.

Variable Resistors of RDAC.

6CLK Serial Clock Input, positive edge

triggered.

7SDI Serial Data Input

8CS Chip Select Input, Active Low.

When CS returns high, data will

be loaded into the RDAC register.

9PR Active low preset to mid-scale; sets

RDAC registers to 80

10 GND Ground

11 V

Negative Power Supply, specified

for operation from 0 V to –5 V.

12 V

Logic Supply Voltage, needs to be

same voltage as the digital logic

controlling the AD5260.

13 NC No Connect (Users should not

connect anything other than dummy

pad on this pin)

14 SDO Serial Data Output, Open Drain

transistor requires pull-up resistor.

AD5262 PIN CONFIGURATION

TOP VIEW

(Not to Scale)

VDD

SHDN

CLK

SDI

SDO

VSS

AD5262

GND

AD5262 PIN FUNCTION DESCRIPTIONS

Number Mnemonic Description

1SDO Serial Data Output, Open Drain

transistor requires pull-up resistor.

2A1A Terminal RDAC #1

3W1 Wiper RDAC #1, address A0 = 0

4B1B Terminal RDAC #1

Positive power supply, specified for

operation at both 5 V or 15 V.

(Sum of |V

|+|V

|£ 15 V)

6SHDN Active low input. Terminal A

open-circuit. Shutdown controls

Variable Resistors #1 through #2.

7CLK Serial Clock Input, positive edge

triggered.

8SDI Serial Data Input.

9CS Chip Select Input, Active Low.

When CS returns high, data in

the serial input register is decoded,

based on the address Bit A

, and

loaded into the target RDAC register.

10 PR Active low preset to mid-scale sets

RDAC registers to 80

11 GND Ground

12 V

Negative Power Supply, specified

for operation at both 0 V or –5 V

(Sum of |V

| + |V

| <15 V).

13 V

Logic Supply Voltage, needs to be

same voltage as the digital logic

controlling the AD5262.

14 B2 B Terminal RDAC #2

15 W2 Wiper RDAC #2, address A0 = 1

16 A2 A Terminal RDAC #2

REV. 0 –7–

AD5260/AD5262

THEORY OF OPERATION

The AD5260/AD5262 provide a single- or dual-channel, 256-position

digitally controlled variable resistor (VR) device and operate up to

15 V maximum voltage. Changing the programmed VR settings

is accomplished by clocking an 8-/9-bit serial data word into the

SDI (Serial Data Input) pin. For the AD5262, the format of this

data word is one address bit. A0 represents the first bit B8, then

followed by eight data bits B7–B0 with MSB first. Tables I and II

provide the serial register data word format. See Table III for the

AD5262 address assignment to decode the location of the VR latch

receiving the serial register data in bits B7 through B0. VR outputs

can be changed one at a time in random sequence. The AD5260/

AD5262 presets to a mid-scale, simplifying fault condition recov-

ery at power-up. Mid-scale can also be achieved at any time by

asserting the PR pin. Both parts have an internal power ON preset

that places the wiper in a mid-scale preset condition at power ON.

Operation of the power ON preset function depends only on the

state of the V

pin.

The AD5260/AD5262 contains a power shutdown SHDN pin,

which places the RDAC in an almost zero power consumption

state where terminals Ax are open circuited, and the wiper W is con-

nected to B, resulting in only leakage currents being consumed in

the VR structure. In the shutdown mode, the VR latch settings are

maintained so that, returning to operational mode from power

shutdown, the VR settings return to their previous resistance values.

Table III. AD5262 Address Decode Table

A0 Latch Loaded

0RDAC#1

1RDAC#2

DIGITAL INTERFACING

The AD5260/AD5262 contains a 4-wire SPI-compatible

digital interface (SDI, SDO, CS, and CLK). For the AD5260,

the 8-bit serial word must be loaded with MSB first, and the

format of the word is shown in Table I. For the AD5262, the

9-bit serial word must be loaded with address bit A0 first, then

MSB of the data. The format of the word is shown in Table II.

SER

REG

VDD

CLK

SDO

GND

RDAC

LATCH

RDAC

LATCH

VSS

SDI

SHDN

POWER-

PRESET

ADDR

DEC

Figure 3. AD5262 Block Diagram

The positive-edge sensitive CLK input requires clean transitions

to avoid clocking incorrect data into the serial input register.

Standard logic families work well. If mechanical switches are used

for product evaluation, they should be debounced by a flip-flop or

other suitable means. Figure 3 shows more detail of the internal

digital circuitry. When CS is low, the clock loads data into the

serial register on each positive clock edge (see Table IV).

Table IV. Truth Table

CLK CS PR SHDN Register Activity

LLHH No SR effect, enables SDO pin

≠*LHHShift one bit in from the SDI pin.

The eighth previously entered bit is

shifted out of the SDO pin.

X≠HH Load SR data into RDAC latch

XHHH No Operation

XXLH Sets all RDAC latches to Mid-Scale,

wiper centered, and SDO latch

cleared.

XH≠HLatches all RDAC latches to 80

XHHL Open circuits all resistor A–terminals,

connects W to B, turns off SDO

output transistor.

*≠ = positive edge, X = don’t care, SR = shift register

The data setup and data hold times in the specification table

determine the data valid time requirements. The AD5260 uses

an 8-bit serial input data register word that is transferred to the

internal RDAC register when the CS line returns to logic high.

For the AD5262 the last 9 bits of the data word entered into the

serial register are held when CS returns high. Any extra bits are

ignored. At the same time CS goes high, it gates the address

decoder enabling AD5262 one of two positive edge-triggered

AD5262 RDAC latches (see Figure 4).

RDAC 1

RDAC 2

AD5260/AD5262

SDI

CLK

ADDR

DECODE

SERIAL

Figure 4. Equivalent Input Control Logic

The target RDAC latch is loaded with the last 8 bits of the serial data

word completing one RDAC update. For the AD5262, two separate

9-bit data words must be clocked in to change both VR settings.

During shutdown (SHDN) the SDO output pin is forced to the

off (logic high state) to disable power dissipation in the pull-up

resistor. See Figure 5 for equivalent SDO output circuit schematic.

SDI

CLK

SHDN

SERIAL

CK RS

SDO

Figure 5. Detail SDO Output Schematic of the AD5260

REV. 0

AD5260/AD5262

–8–

All digital inputs are protected with a series input resistor and

parallel Zener ESD structure as shown in Figure 6. This applies

to digital input pins CS, SDI, SDO, PR, SHDN, and CLK.

340⍀

LOGIC

Figure 6. ESD Protection of Digital Pins

A, B, W

Figure 7. ESD Protection of Resistor Terminals

LAYOUT AND POWER SUPPLY BYPASSING

It is a good practice to employ compact, minimum-lead length

layout design. The leads to the input should be as direct as pos-

sible

with a minimum conductor length. Ground paths should

have low resistance and low inductance.

Similarly, it is also a good practice to bypass the power supplies

with quality capacitors for optimum stability. Supply leads to the

device should be bypassed with 0.01 mF–0.1 mF disc or chip ceram-

ics

capacitors. Low-ESR 1 mF to 10 mF tantalum or electrolytic

capaci

tors should also be applied at the supplies to minimize any

transient

disturbance (see Figure 8). Notice the digital ground

should also be joined remotely to the analog ground to minimize

the ground bounce.

VSS

10␮F

VSS

VDD

0.1␮F

GND

VDD

0.1␮F

10␮F

ⴙ

Figure 8. Power Supply Bypassing

TERMINAL VOLTAGE OPERATING RANGE

The AD5260/AD5262 positive V

and negative V

power

supply defines the boundary conditions for proper 3-terminal

digital potentiometer operation. Supply signals present on termi-

nals A, B, and W that exceed V

or V

will be clamped by the

internal forward biased diodes (see Figure 9).

Figure 9. Maximum Terminal Voltages Set by V

and V

The ground pin of the AD5260/AD5262 device is primarily used

as a digital ground reference, which needs to be tied to the PCB’s

common ground. The digital input control signals to the AD5260/

AD5262 must be referenced to the device ground pin (GND),

and must satisfy the logic level defined in the specification table

of this data sheet. An internal level shift circuit ensures that the

common-mode voltage range of the three terminals extends

from V

to V

regardless of the digital input level.

POWER-UP SEQUENCE

Since there are diodes to limit the voltage compliance at termi-

nals A, B, and W (see Figure 9), it is important to power V

first before applying any voltage to terminals A, B, and W. Other-

wise, the diode will be forward biased such that V

will be

powered unintentionally and may affect the rest of the user’s circuit.

The ideal power-up sequence is in the following order: GND,

, V

Digital Inputs, and V

A/B/W

. The order of powering

, V

, and Digital Inputs is not important as long as they

are powered after V

Daisy-Chain Operation

The serial-data output (SDO) pin contains an open drain

n-channel FET. This output requires a pull-up resistor to trans-

fer data to the next package’s SDI pin. This allows for daisy

chaining several RDACs from a single processor serial data line.

The pull-up resistor termination voltage can be larger than the V

supply voltage. It is recommended to increase the Clock period

when using a pull-up resistor to the SDI pin of the following device

in series because capacitive loading at the daisy-chain node

SDO-SDI between devices may induce time delay to subsequent

devices. Users should be aware of this potential problem to achieve

data transfer successfully (see Figure 10). If two AD5260s are daisy-

chained, this requires a total of 16 bits of data. The first 8 bits,

complying with the format shown in Table I, go to U2, and the

second 8 bits with the same format go to U1. The CS should be

kept low until all 16 bits are clocked into their respective serial

registers, and the CS is then pulled high to complete the operation.

CS CLK

SDOSDI

CS CLK

SDOSDIMOSI␮C

SCLK SS

2.2k⍀

AD5260 AD5260

U1 U2

Figure 10. Daisy-Chain Configuration

RDAC STRUCTURE

The RDAC contains a string of equal resistor segments, with an

array of analog switches, that act as the wiper connection. The

number of positions is the resolution of the device. The AD5260/

AD5262 have 256 connection points allowing it to provide better

than 0.4% set-ability resolution. Figure 11 shows an equivalent

structure of the connections between the three terminals that

make up one channel of the RDAC. The SW

and SW

will

always be ON, while one of the switches SW(0) to SW(2

– 1)

will be ON one at a time depending on the resistance position

decoded from the data bits. Since the switch is not ideal, there is

a 60 W wiper resistance, R

. Wiper resistance is a function of

supply voltage and temperature. The lower the supply voltage, the

higher the wiper resistance. Similarly, the higher the temperature,

the higher the wiper resistance. Users should be aware of the

contribution of the wiper resistance when accurate prediction of

the output resistance is needed.

REV. 0 –9–

AD5260/AD5262

RDAC

LATCH

AND

DECODE

= R

HDN

DIGITAL CIRCUITRY

OMITTED FOR CLARITY

Figure 11. Simplified RDAC Architecture

PROGRAMMING THE VARIABLE RESISTOR

Rheostat Operation

The nominal resistances of the RDAC between terminals A and B

are available with values of 20 kW, 50 kW, and 200 kW. The final

three digits of the part number determine the nominal resistance

value, e.g., 20 kW = 20; 50 kW = 50; 200 kW = 200. The nominal

resistance (R

) of the VR has 256 contact points accessed by the

wiper terminal, plus the B terminal contact. The 8-bit data in the

RDAC latch is decoded to select one of the 256 possible settings.

Assuming a 20 kW part is used, the wiper’s first connection starts

at the B terminal for data 00

. Since there is a 60 W wiper contact

resistance, such connection yields a minimum of 60 W resistance

between terminals W and B. The second connection is the first tap

point corresponds to 138 W (R

= R

/256  R

= 78 W  60 W)

for data 01

. The third connection is the next tap point represent-

ing 216 W (78  2  60) for data 02

and so on. Each LSB data

value increase moves the wiper up the resistor ladder until the last

tap point is reached at 19982 W [R

 1 LSB  R

]. The wiper

does not directly connect to the B terminal. See Figure 11 for a

simplified diagram of the equivalent RDAC circuit.

The general equation determining the digitally programmed

output resistance between W and B is:

RD DRR

WB AB W

()

=¥+

256

(1)

where D is the decimal equivalent of the binary code which is

loaded in the 8-bit RDAC register, and R

is the nominal end-

to-end resistance.

For example, R

= 20 kW, when V

= 0 V and A–terminal is

open circuit, the following output resistance values R

will be

set for the following RDAC latch codes. The result will be the

same if terminal A is tied to W:

(DEC) (W)Output State

256 19982 Full-Scale (R

– 1 LSB + R

)

128 10060 Mid-Scale

1138 1 LSB

060Zero-Scale (wiper contact resistance)

Note that in the zero-scale condition a finite wiper resistance of

60 W is present. Care should be taken to limit the current flow

between W and B in this state to no more than 20 mA to avoid

degradation or possible destruction of the internal switches.

Like the mechanical potentiometer the RDAC replaces, the

AD5260/AD5262 parts are totally symmetrical. The resistance

between the wiper W and terminal A also produces a digitally

controlled complementary resistance R

. Figure 12 shows the

symmetrical programmability of the various terminal connections.

When R

is used, the B–terminal can be let floating or tied to the

wiper. Setting the resistance value for R

starts at a maximum

value of resistance and decreases as the data loaded in the latch

is increased in value. The general equation for this operation is:

RD DRR

WA AB W

()

=-¥+

256

(2)

For example, R

= 20 kW, when V

= 0 V and B–terminal is open,

the following output resistance R

will be set for the following

RDAC latch codes. The result will be the same if terminal B is

tied to W:

(DEC) (W)Output State

256 60 Full-Scale

128 10060 Mid-Scale

119982 1 LSB

020060 Zero-Scale

= 20K⍀

D – CODE in decimal

064128192 256

(D), R

(D) ⴚ k⍀

Figure 12. AD5260/AD5262 Equivalent RDAC Circuit

The typical distribution of the nominal resistance R

from

channel to channel matches within ±1%. Device-to-device match-

ing is process lot dependent with the worst case of ±30% variation.

On the other hand, since the resistance element is processed in

thin film technology, the change in R

with temperature has a

low 35 ppm/∞C temperature coefficient.

REV. 0

AD5260/AD5262

–10–

CODE – Decimal

RHEOSTAT MODE INL – LSB

0256

–0.2 32 64 96 128 160 192 224

–0.1

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

ⴙ5V

ⴙ12V

ⴞ5V

ⴙ15V

TPC 1. R-INL vs. Code vs.

Supply Voltages

CODE – Decimal

POTENTIOMETER MODE DNL – LSB

0256

–0.5 32 64 96 128 160 192 224

–0.4

–0.2

–0.1

0.1

0.3

0.5

–0.3

0.2

0.4

TA = ⴙ125ⴗC

TA = ⴙ85ⴗC

TA = ⴙ25ⴗC

TA = ⴚ40ⴗC

TPC 4. DNL vs. Code,

5 V

VDD – VSS – V

POTENTIOMETER MODE INL – LSB

020

–1.0 51015

1.0

–0.5

0.5

AVG +3␴

AVG

AVG –3␴

TPC 7. INL vs. Supply Voltages

CODE – Decimal

RHEOSTAT MODE DNL – LSB

0256

–0.25 32 64 96 128 160 192 224

–0.20

–0.10

–0.05

0.05

0.10

–0.15

ⴙ5V

ⴙ12V ⴞ5V ⴙ15V

TPC 2. R-DNL vs. Code vs.

Supply Voltages

CODE – Decimal

POTENTIOMETER MODE INL – LSB

025632 64 96 128 160 192 224

–0.4

–0.2

–0.1

0.1

0.2

–0.3

ⴞ5V

0.3

ⴙ15V

ⴙ5V

TPC 5. INL vs. Code vs.

Supply Voltages

VDD – VSS – V

RHEOSTAT MODE INL – LSB

020

–2.0 51015

2.0

–1.0

1.0

AVG +3␴

AVG

1.5

–1.5

–0.5

0.5

AVG –3␴

TPC 8. R-INL vs. Supply Voltages

CODE – Decimal

POTENTIOMETER MODE INL – LSB

0256

–1.0 32 64 96 128 160 192 224

–0.8

–0.4

–0.2

0.2

0.6

1.0

–0.6

0.4

0.8

VDD = ⴙ5V

VSS = ⴚ5V

RAB = 20k⍀

TA = ⴙ25ⴗC

TA = ⴚ40ⴗC

TA = ⴙ125ⴗC

TA = ⴙ85ⴗC

TPC 3. INL vs. Code, V

5 V

CODE – Decimal

POTENTIOMETER MODE DNL – LSB

025632 64 96 128 160 192 224

–0.5

–0.3

–0.2

0.1

0.3

–0.4

–0.1

ⴞ5V

0.5

ⴙ15V

ⴙ5V

0.2

0.4

TPC 6. DNL vs. Code vs.

Supply Voltages

VDD – V

WIPER RESISTANCE – ⍀

ⴚ515

4ⴚ13 11

124

104

RON @ VDD/VSS = ⴙ5V/0V

RON @ VDD/VSS = ⴙ15V/0V

RON @ V DD/VSS = ⴙ5V/ⴚ5V

TPC 9. Wiper ON Resistance vs.

Bias Voltage

—Typical Performance Characteristics

REV. 0 –11–

AD5260/AD5262

TEMPERATURE – ⴗC

FSE – LSB

–40 100

–2.5

–20 20 80

–2.0

–1.0

–1.5

–0.5

= +15V/0V

060

= +5V/0V

= ⴞ5V

TPC 10. Full-Scale Error

TEMPERATURE – ⴗC

LOGIC

– ␮A

–40 125

24.5

–7 26 92

28.0

25.5

26.5

= +15V/0V

25.0

26.0

27.5

= ⴞ5V

27.0

TPC 13. I

LOGIC

vs. Temperature

TEMPERATURE – ⴗC

ZSE – LSB

–40 100

–20 20 80

2.5

0.5

1.5

1.0

2.0

060

= +5V/0V

= ⴞ5V

= +15V/0V

TPC 11. Zero-Scale Error

– V

LOGIC

– ␮A

0 5

100

= 5V/0V V

LOGIC

= 5V

= 5V/0V V

LOGIC

= 3V

1234

TPC 14. I

LOGIC

vs. Digital Input

Voltage

TEMPERATURE – ⴗC

SUPPLY CURRENT – ␮A

–40 125

0.001

–7 26 92

0.01

0.1

= ⴙ15V/0V

= ⴞ5V

LOGIC

= ⴙ5V

= 0V

TPC 12. Supply Current vs.

Temperature

CODE – Decimal

RHEOSTAT MODE TEMPCO – ppm/ⴗC

0256

–20

20k⍀

64 96 160 224

–10

19212832

50k⍀

200k⍀

TPC 15. Rheostat Mode Tempco

T vs. Code

CODE – Decimal

POTENTIOMETER MODE TEMPCO – ppm/ⴗC

0256

–60

120

20k⍀

64 96 160 224

–40

19212832

–20

100

50k⍀

200k⍀

TPC 16. Potentiometer Mode

T vs. Code

FREQUENCY – Hz

GAIN – dB

1k 1M

–54

–48

–42

–36

–30

–24

–18

–12

–6

10k 100k

CODE = FFH

01H

02H

04H

08H

10H

20H

40H

80H

TA = 25ⴗC

TPC 17. Gain vs. Frequency vs.

Code, R

= 20 k

REV. 0

AD5260/AD5262

–12–

FREQUENCY – Hz

GAIN – dB

1k 1M

–54

–48

–42

–36

–30

–24

–18

–12

–6

10k 100k

CODE = FF

= 25ⴗC

TPC 18. Gain vs. Frequency vs. Code

= 50 k

FREQUENCY – Hz

NORMALIZED GAIN FLATNESS – 0.1dB/DIV

0dB

100 100k1k 10k

CODE = 80

= ⴞ5V

= 25ⴗC

R = 20k⍀

R = 200k⍀

R = 50k⍀

TPC 21. Normalized Gain

Flatness vs. Frequency

20mV/DIV

1␮s/DIV

5V/DIV

TPC 24. Mid-Scale Glitch

Energy, Code 80

to 7F

FREQUENCY – Hz

GAIN – dB

1k 100k

–54

–48

–42

–36

–30

–24

–18

–12

–6

10k

CODE = FF

= 25ⴗC

TPC 19. Gain vs. Frequency vs.

Code R

= 200 k

FREQUENCY – Hz

ILOGIC – ␮A

10k 10M

600

100

100k

200

300

400

500

CODE FFH

VDD/VSS = +5V/0V

VDD/VSS = ⴞ5V

CODE 55H

TPC 22. I

LOGIC

vs. Frequency

5V/DIV

20␮s/DIV

5V/DIV

TPC 25. Large Signal Settling Time

FREQUENCY – Hz

GAIN – dB

1k 1M

–54

–48

–42

–36

–30

–24

–18

–12

–6

10k 100k

–3dB

BANDWIDTHS

= 50mV rms

= ⴞ5V

–3dB

= 310kHz, R = 20k⍀

–3dB

= 131kHz, R = 50k⍀

–3dB

= 30kHz, R = 200k⍀

TPC 20. –3 dB Bandwidth

FREQUENCY – Hz

PSRR – dB

100 1M

600

10k

100

200

300

400

500

100k

–PSRR @ V

= ⴞ5V DC ⴞ 10% p-p AC

+PSRR @ V

= ⴞ5V DC ⴞ 10% p-p AC

CODE = 80

, V

= V

, V

= 0V

TPC 23. PSRR vs. Frequency

10mV/DIV

40ns/DIV

TPC 26. Digital Feedthrough vs. Time

REV. 0 –13–

AD5260/AD5262

CODE – Decimal

THEORETICAL IWB_MAX – mA

0256

0.01

100

0.1

32 64 96 128 160 192 224

RAB = 200k⍀

VA = VB = OPEN

TA = 25ⴗC

RAB = 50k⍀

RAB = 20k⍀

TPC 27. I

MAX

vs. Code

HOURS OF OPERATION AT 150ⴗC

CHANGE IN TERMINAL RESISTANCE – %

0500

–0.20

0.10

–0.10

0.05

100 200 250 300 350 400 450

AVG –3␴

CODE = 80

= V

= ⴞ5V

SS = 135 UNITS

50 150

–0.05

–0.15

AVG +3␴

AVG

TPC 28. Long-Term Resistance Drift

CHANNEL-TO-CHANNEL R

MATCH – %

FREQUENCY

–0.50

CODE SET TO MID-SCALE

= 150ⴗC

3 LOTS

SAMPLE SIZE = 135

–0.40 –0.30 –0.20 –0.10 0 0.10 0.20

TPC 29. Channel-to-Channel

Resistance Matching (AD5262)

DUT

Vⴙ

V+ = VDD

1LSB = V+/2N

Test Circuit 1. Potentiometer Divider

Nonlinearity Error (INL, DNL)

DUT NC = NO CONNECT

Test Circuit 2. Resistor Position Nonlinearity Error

(Rheostat Operation; R-INL, R-DNL)

VMS1

IW = VDD /RNOMINAL

VMS2

RW = [VMS1 – VMS2]/IW

DUT

Test Circuit 3. Wiper Resistance

⌬V

PSS (%/%) =

V+ = V

10%

PSRR (dB) = 20 LOG

⌬V

( )

V+

Test Circuit 4. Power Supply Sensitivity (PSS, PSSR)

+13V

–13V

OUT

OFFSET

GND

DUT

AD8610

Test Circuit 5. Gain vs. Frequency

TO V

DUT

CODE = 00

=0.1V

0.1V

A = NC

Test Circuit 6. Incremental ON Resistance

GND

DUT

Test Circuit 7. Common-Mode Leakage Current

TEST CIRCUITS

Test Circuits 1 to 9 define the test conditions used in the product specification table.

REV. 0

–14–

AD5260/AD5262

TEST CIRCUITS (continued)

SDI

CLK

LOGIC

DIGITAL INPUT

VOLTAGE

Test Circuit 8. V

LOGIC

Current vs. Digital Input Voltage

GND

DUT

Test Circuit 9. Analog Crosstalk

PROGRAMMING THE POTENTIOMETER DIVIDER

Voltage Output Operation

The digital potentiometer easily generates output voltages at wiper-

to-B and wiper-to-A to be proportional to the input voltage at

A-to-B. Ignore the effect of the wiper resistance at the moment.

For example, connecting A-terminal to 5 V and B-terminal to

ground produces an output voltage at the wiper-to-B starting at

zero volts up to 1 LSB less than 5 V. Each LSB of voltage is equal

to the voltage applied across terminal AB divided by the 256 posi-

tion of the potentiometer divider. Since the AD5260/AD5262

operates from dual supplies, the general equation defining the

output voltage at V

with respect to ground for any given input

voltage applied to terminals AB is:

VD DVV

WABB

()

=¥+

256 (3)

Operation of the digital potentiometer in the divider mode results

in more accurate operation over temperature. Unlike the rheostat

mode, the output voltage is dependent on the ratio of the internal

resistors R

and R

and not the absolute values; therefore, the

drift reduces to 5 ppm/∞C.

APPLICATIONS

Bipolar DC or AC Operation from Dual Supplies

The AD5260/AD5262 can be operated from dual supplies enabling

control of ground referenced AC signals or bipolar operation.

The AC signal, as high as V

, can be applied directly across

terminals A–B with output taken from terminal W. See Figure 13

for a typical circuit connection.

VSS

+5.0V

CLK

GND

VDD

SDI

GND

VDD

–5.0V

SCLK

MOSI

␮C

SS ⴞ5V p-p

ⴞ2.5V p-p

D = 80H

Figure 13. Bipolar Operation from Dual Supplies

Gain Control Compensation

Digital potentiometers are commonly used in gain control as in

the noninverting gain amplifier shown in Figure 14.

200k⍀

4.7pF

47k⍀

25pF

Figure 14. Typical Noninverting Gain Amplifier

Notice that when the RDAC B terminal parasitic capacitance is

connected to the op amp noninverting node, it introduces a zero

for the 1/b

term with +20 dB/dec, whereas a typical op amp GBP

has –20 dB/dec characteristics. A large R2 and finite C1 can cause

this Zero’s frequency to fall well below the crossover frequency.

Hence the rate of closure becomes 40 dB/dec and the system has

0∞ phase margin at the crossover frequency. The output may ring

or oscillate if the input is a rectangular pulse or step function.

Similarly, it is also likely to ring when switching between two

gain values because this is equivalent to a step change at the input.

Depending on the op amp GBP, reducing the feedback resistor

may extend the Zero’s frequency far enough to overcome the prob-

lem. A better approach, however, is to include a compensation

capacitor C2 to cancel the effect caused by C1. Optimum compen-

sation occurs when R1  C1 = R2  C2. This is not an option

because of the variation of R2. As a result, one may use the relation-

ship above and scale C2 as if R2 is at its maximum value. Doing so

may overcompensate and compromise the performance slightly

when R2 is set at low values. However, it will avoid the ringing or

oscillation at the worst case. For critical applications, C2 should

be found empirically to suit the need. In general, C2 in the range

of a few pF to no more than a few tenths of pF is usually adequate

for the compensation.

Similarly, there are W and A terminal capacitances connected to

the output (not shown). Fortunately their effect at this node is less

significant, and the compensation can be avoided in most cases.

Programmable Voltage Reference

For voltage divider mode operation, Figure 15, it is common

to buffer the output of the digital potentiometer unless the load is

much larger than R

. Not only does the buffer serve the pur-

pose of impedance conversion, but it also allows a heavier load

to be driven.

REV. 0 –15–

AD5260/AD5262

VIN

GND

VOUT

AD1582

AD8601

3AW

AD5260

Figure 15. Programmable Voltage Reference

8-Bit Bipolar DAC

Figure 16 shows a low cost 8-bit bipolar DAC. It offers the same

number of adjustable steps but not the precision of conventional

DACs. The linearity and temperature coefficients, especially at low

values codes, are skewed by the effects of the digital potentiometer

wiper resistance. The output of this circuit is:

VDV

O REF

Áˆ

˜¥

256 1(4)

ⴚ5VREF

OP2177

A2 –5V

OP2177

+5V

–5V

+5V

+5VREF

VIN

GND

VOUT

TRIM

AD5260

ADR425

R R

Figure 16. 8-Bit Bipolar DAC

Bipolar Programmable Gain Amplifier

For applications that require bipolar gain, Figure 17 shows one

implementation. Digital potentiometer U1 sets the adjustment

range. The wiper voltage at W2 can therefore be programmed

between V

and –KV

at a given U2 setting. Configuring A2

the noninverting mode allows linear gain and attenuation. The

transfer function is:

DKK

Áˆ

˜¥¥+

()

Áˆ

256 1

(5)

where K is the ratio of R

WB1

WA1

set by U1.

–KVi

A1 B1

OP2177

VDD

VSS

VDD

VSS

OP2177

A2 B2

AD5262

Figure 17. Bipolar Programmable Gain Amplifier

Similar to the previous example, in the simpler (and much more

usual) case, where K = 1, a single digital pot AD5260, and U1

is replaced by a matched pair of resistors to apply V

and – V

the ends of the digital pot. The relationship becomes:

Áˆ

˜-

Áˆ

˜¥12

256 1

(6)

If R2 is large, a few picofarad compensation capacitors may be

needed to avoid any gain peaking.

Table VIII shows the result of adjusting D, with A2 configured as a

unity gain, a gain of 2, and a gain of 10. The result is a bipolar

amplifier with linearly programmable gain and 256-step resolution.

Table VIII. Result of Bipolar Gain Amplifier

DR1

= •, R2 = 0 R1

= R2 R2

= 9R1

0–1 –2 –10

64 –0.5 –1 –5

128 0 0 0

192 0.5 1 5

255 0.968 1.937 9.680

Programmable Voltage Source with Boosted Output

For applications that require high current adjustment such as a

laser diode driver or turnable laser, a boosted voltage source can

be considered (see Figure 18).

SIGNAL LO

R1 10k⍀P1 RBIAS

U1= AD5260

A1= AD8601, AD8605, AD8541

P1= FDP360P, NDS9430

N1= FDV301N, 2N7002

Figure 18. Programmable Boosted Voltage Source

In this circuit, the inverting input of the op amp forces the V

to be

equal to the wiper voltage set by the digital potentiometer. The

load current is then delivered by the supply via the P-Ch FET P1.

The N-Ch FET N

simplifies the op amp driving requirement.

A1 needs to be the rail-to-rail input type. Resistor R1 is needed to

prevent P1 from not turning off once it is on. The choice of R1 is a

balance between the power loss of this resistor and the output turn-

off time. N1 can be any general-purpose signal FET; on the other

hand, P1 is driven in the saturation state, and therefore its power

handling must be adequate to dissipate (V

– V

)  I

power. This

circuit can source a maximum of 100 mA at 5 V supply. Higher

current can be achieved with P1 in a larger package. Note, a single

N-Ch FET can replace P1, N1, and R1 altogether. However, the out-

put swing will be limited unless separate power supplies are used.

For precision application, a voltage reference such as ADR423,

ADR292, and AD1584 can be applied at the input of the digital

potentiometer.

Programmable 4-to-20 mA Current Source

A programmable 4-to-20 mA current source can be implemented

with the circuit shown in Figure 19. REF191 is a unique low

supply headroom and high current handling precision reference

REV. 0

–16–

AD5260/AD5262

that can deliver 20 mA at 2.048 V. The load current is simply the

voltage across terminals B-to-W of the digital pot divided by R

IVD

REF

=¥

(7)

–5V

OUT

OP1177

–

+5V

100⍀

102⍀

AD5260

1␮F

GND

REF191

SLEEP

ⴙ5V

2U1

60 TO (2.048 ⴙ V

)

–2.048V TO V

Figure 19. Programmable 4-to-20 mA Current Source

The circuit is simple, but be aware that dual-supply op amps are

ideal because the ground potential of REF191 can swing from

–2.048 V at zero scale to V

at full scale of the potentiometer

setting. Although the circuit works under single supply, the pro-

grammable resolution of the system will be reduced.

Programmable Bidirectional Current Source

For applications that require bidirectional current control or higher

voltage compliance, a Howland current pump can be a solution

(see Figure 20). If the resistors are matched, the load current is:

IRA RB R

RB V

()

221

(8)

–5V

+5V

AD8016

–15V

+15V

–15V

OP2177

AD5260

10pF

150k⍀

10pF

15k⍀

R2A

14.95k⍀R

500⍀

50⍀

+15V

Figure 20. Programmable Bidirectional Current Source

Programmable Low-Pass Filter

Digital potentiometer AD5262 can be used to construct a second

order Sallen Key Low-Pass Filter (see Figure 21). The design

equations are:

VSQS

(9)

wORR CC

1212 (10)

QRC R C

(11)

Users can first select some convenient values for the capacitors.

To achieve maximally flat bandwidth where Q = 0.707, let C1 be

twice the size of C2

and let R1 = R2. As a result, users can adjust

R1 and R2 to the same settings to achieve the desirable bandwidth.

AD8601

+2.5V

–2.5V

R2R1

ADJUSTED TO

SAME SETTINGS

Figure 21. Sallen Key Low-Pass Filter

Programmable Oscillator

In a classic Wien-bridge oscillator, Figure 22, the Wien network

(R, R’, C, C’) provides positive feedback, while R1 and R2

provide negative feedback. At the resonant frequency, f

, the

overall phase shift is zero, and the positive feedback causes the

circuit to oscillate. With R = R’, C = C’, and R2 = R2A//(R2B+

DIODE

), the oscillation frequency is:

RC fRC

or (12)

where R is equal to R

such that:

RDRAB

=256

256

–

(13)

At resonance, setting

12=

(14)

balances the bridge. In practice, R2/R1 should be set slightly larger

than 2 to ensure the oscillation can start. On the other hand, the

alternate turn-on of the diodes D1 and D2 ensures R2/R1 to be

smaller than 2 momentarily and therefore stabilizes the oscillation.

Once the frequency is set, the oscillation amplitude can be tuned

by R2B since:

32VIRBV

OD D

(15)

REV. 0 –17–

AD5260/AD5262

, I

, and V

are interdependent variables. With proper selection

of R2B, an equilibrium will be reached such that V

converges. R2B

can be in series with a discrete resistor to increase the amplitude,

but the total resistance cannot be too large to saturate the output.

In both circuits in Figures 21 and 22, the frequency tuning requires

that both RDACs be adjusted to the same settings. Since the two

channels will be adjusted one at a time, an intermediate state will

occur that may not be acceptable for certain applications. As a

result, different devices can also be used in daisy-chained mode so

that parts can be programmed to the same setting simultaneously.

+5V

OP1177 V

–5V

R2A

2.1k⍀D1

R2B

10k⍀

1k⍀

R1 = R1 = R2B = AD5262

D1 = D2 = 1N4148

AD5262

2.2nF R

10k⍀

2.2nF

FREQUENCY

ADJUSTMENT

10k⍀

AMPLITUDE

ADJUSTMENT

Figure 22. Programmable Oscillator with

Amplitude Control

Resistance Scaling

The AD5260/AD5262 offer 20 kW, 50 kW, and 200 kW nominal

resistance. For users who need lower resistance and still maintain the

numbers of step adjustment, they can parallel multiple devices. For

example, Figure 23 shows a simple scheme of paralleling both

channels of the AD5262. To adjust half of the resistance linearly

per step, users need to program both channels coherently with

the same settings.

B1 W2

VDD

Figure 23. Reduce Resistance by Half with Linear

Adjustment Characteristics

In voltage divider mode, a much lower resistance can be achieved

by paralleling a discrete resistor as shown in Figure 24. The equiva-

lent resistance becomes:

RDRR R

WB eq W_=§§

()

256 12 (16)

RDRR R

WA eq W_

Áˆ

˜§§

()

+1256 12

(17)

R2 R1

R2 << R1

Figure 24. Lowering the Nominal Resistance

Figures 23 and 24 show that the digital potentiometers change steps

linearly. On the other hand, log taper adjustment is usually pre-

ferred in applications like audio control. Figure 25 shows another

way of resistance scaling. In this circuit, the smaller the R2 with

respect to R

, the more the pseudo-log taper characteristic behaves.

Figure 25. Resistor Scaling with Log Adjustment

Characteristics

RDAC CIRCUIT SIMULATION MODEL

The internal parasitic capacitances and the external capacitive

loads dominate the ac characteristics of the RDACs. Configured

as a potentiometer divider, the –3 dB bandwidth of the AD5260

(20 kW resistor) measures 310 kHz at half scale. TPC 20 provides

the large signal BODE plot characteristics of the three available

resistor versions 20 kW, 50 kW, and 200 kW. A parasitic simulation

model is shown in Figure 26. Listing I provides a macro model

net list for the 20 kW RDAC.

55pF

25pF

RDAC

20k⍀

Figure 26. RDAC Circuit Simulation Model for RDAC = 20 k

Listing I. Macro Model Net List for RDAC

PARAM D=256, RDAC=20E3

SUBCKT DPOT (A,W,B)

CA A 0 25E-12

RWA A W {(1-D/256)*RDAC+60}

CW W 0 55E-12

RWB W B {D/256*RDAC+60}

CB B 0 25E-12

.ENDS DPOT

REV. 0

–18–

AD5260/AD5262

DIGITAL POTENTIOMETER FAMILY SELECTION GUIDE

Number Terminal Interface Nominal Resolution Power Supply

Part of VRs per Voltage Data Resistance (No. of Wiper Current

Number Package Range (V) Control (k⍀)Positions) (I

) (␮A) Packages Comments

AD5201 1±3, 5.5 3-Wire 10, 50 33 40 mSOIC-10 Full AC Specs, Dual

Supply, Power-On-

Reset, Low Cost

AD5220 15.5 UP/DOWN 10, 50, 100 128 40 PDIP, SO-8, No Rollover,

mSOIC-8 Power-On-Reset

AD7376 1±15, 28 3-Wire 10, 50, 100, 128 100 PDIP-14, Single 28 V or Dual

1000 SOL-16, ±15 V Supply Operation

TSSOP-14

AD5200 1±3, 5.5 3-Wire 10, 50 256 40 mSOIC-10 Full AC Specs, Dual

Supply, Power-On-Reset

AD8400 15.5 3-Wire 1, 10, 50, 100 256 5 SO-8 Full AC Specs

AD5260 1±5, 15 3-Wire 20, 50, 200 256 60 TSSOP-14 5 V to 15 V or ±5 V

Operation,

TC < 50 ppm/∞C

AD5241 1±3, 5.5 2-Wire 10, 100, 256 50 SO-14, I

C Compatible,

1000 TSSOP-14 TC < 50 ppm/∞C

AD5231 1±2.75, 5.5 3-Wire 10, 50, 100 1024 20 TSSOP-16 Nonvolatile Memory,

Direct Program, I/D,

±6 dB settability

AD5222 2±3, 5.5 UP/DOWN 10, 50, 100, 128 80 SO-14, No Rollover, Stereo,

1000 TSSOP-14 Power-On-Reset,

TC < 50 ppm/∞C

AD8402 25.5 3-Wire 1, 10, 50, 256 5 PDIP, SO-14, Full AC Specs, nA

100 TSSOP-14 Shutdown Current

AD5207 2±3, 5.5 3-Wire 10, 50, 100 256 40 TSSOP-14 Full AC Specs, Dual

Supply, Power-On-

Reset, SDO

AD5232 2±2.75, 5.5 3-Wire 10, 50, 100 256 20 TSSOP-16 Nonvolatile Memory,

Direct Program, I/D,

±6 dB Settability

AD5235

2±2.75, 5.5 3-Wire 25, 250 1024 20 TSSOP-16 Nonvolatile Memory,

Direct Program,

TC < 50 ppm/∞C

AD5242 2±3, 5.5 2-Wire 10, 100, 256 50 SO-16, I

C Compatible,

1000 TSSOP-16 TC < 50 ppm/∞C

AD5262 2±5, 15 3-Wire 20, 50, 200 256 60 TSSOP-16 5 V to 15 V or ±5 V

Operation,

TC < 50 ppm/∞C

AD5203 45.5 3-Wire 10, 100 64 5 PDIP, SOL-24, Full AC Specs, nA

TSSOP-24 Shutdown Current

AD5233 4±2.75, 5.5 3-Wire 10, 50, 100 64 20 TSSOP-24 Nonvolatile Memory,

Direct Program, I/D,

±6 dB Settability

AD5204 4±3, 5.5 3-Wire 10, 50, 100 256 60 PDIP, SOL-24, Full AC Specs, Dual

TSSOP-24 Supply, Power-On-Reset

AD8403 45.5 3-Wire 1, 10, 50, 100 256 5 PDIP, SOL-24, Full AC Specs, nA

TSSOP-24 Shutdown Current

AD5206 6±3, 5.5 3-Wire 10, 50, 100 256 60 PDIP, SOL-24, Full AC Specs, Dual

TSSOP-24 Supply, Power-On-Reset

For the most current information on digital potentiometers, check the website at: www.analog.com/DigitalPotentiometers

Future product, consult factory for latest status.

REV. 0 –19–

AD5260/AD5262

14-Lead TSSOP

(RU-14)

14 8

0.256 (6.50)

0.246 (6.25)

0.177 (4.50)

0.169 (4.30)

PIN 1

0.201 (5.10)

0.193 (4.90)

SEATING

PLANE

0.006 (0.15)

0.002 (0.05)

0.0118 (0.30)

0.0075 (0.19)

0.0256

(0.65)

BSC

0.0433 (1.10)

MAX

0.0079 (0.20)

0.0035 (0.090)

0.028 (0.70)

0.020 (0.50)

8ⴗ

0ⴗ

16-Lead TSSOP

(RU-16)

16 9

0.256 (6.50)

0.246 (6.25)

0.177 (4.50)

0.169 (4.30)

PIN 1

0.201 (5.10)

0.193 (4.90)

SEATING

PLANE

0.006 (0.15)

0.002 (0.05)

0.0118 (0.30)

0.0075 (0.19)

0.0256 (0.65)

BSC

0.0433 (1.10)

MAX

0.0079 (0.20)

0.0035 (0.090)

0.028 (0.70)

0.020 (0.50)

8ⴗ

0ⴗ

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

–20–

C02695–0–3/02(0)

PRINTED IN U.S.A.