AD8400AN10 Analog Devices, AD8400AN10 Datasheet - Page 12

AD8400AN10

Manufacturer Part Number

AD8400AN10

Description

1-/2-/4-Channel Digital Potentiometers

Manufacturer

Analog Devices

Datasheet

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AD8400/AD8402/AD8403

OPERATION

The AD8400/AD8402/AD8403 provide a single, dual and quad

channel, 256 position digitally controlled variable resistor (VR)

device. Changing the programmed VR settings is accomplished

by clocking in a 10-bit serial data word into the SDI (Serial

Data Input) pin. The format of this data word is two address

bits, MSB first, followed by eight data bits, MSB first. Table I

provides the serial register data word format. The AD8400/

AD8402/AD8403 has the following address assignments for the

ADDR decode, which determines the location of VR latch re-

ceiving the serial register data in Bits B7 through B0:

The single-channel AD8400 requires A1 = A0 = 0. The dual-

channel AD8402 requires A1 = 0. VR settings can be changed

one at a time in random sequence. The serial clock running at

10 MHz makes it possible to load all 4 VRs in under 4 s (10

shown in Figures 1a, 1b and 1c.

The AD8402/AD8403 resets to midscale by asserting the RS

pin, simplifying initial conditions at power up. Both parts have a

power shutdown SHDN pin that places the VR in a zero power

consumption state where terminals Ax are open circuited and

the wiper Wx is connected to Bx resulting in only leakage cur-

rents being consumed in the VR structure. In shutdown mode

the VR latch settings are maintained so that returning to opera-

tional mode from power shutdown, the VR settings return to

their previous resistance values. The digital interface is still ac-

tive in shutdown, except that SDO is deactivated. Code changes

in the registers can be made that will produce new wiper posi-

tions when the device is taken out of shutdown.

Figure 37. AD8402/AD8403 Equivalent VR (RDAC) Circuit

100 ns) for the AD8403. The exact timing requirements are

SHDN

VR# = A1

DECODER

LATCH

RDAC

2 + A0 + 1

= R

NOMINAL

/256

Equation 1

–12–

PROGRAMMING THE VARIABLE RESISTOR

Rheostat Operation

The nominal resistance of the VR (RDAC) between terminals A

and B are available with values of 1 k , 10 k , 50 k and 100 k .

The final digits of the part number determine the nominal resis-

tance value, e.g., 10 k = 10; 100 k = 100. The nominal resis-

tance (R

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

in the RDAC latch is decoded to select one of the 256 possible

settings. The wiper’s first connection starts at the B terminal for

data 00

tance of 50 . The second connection (10 k part) is the first

tap point located at 89

= 39

tap point representing 78 + 50 = 128

data value increase moves the wiper up the resistor ladder until

the last tap point is reached at 10011 . The wiper does not di-

rectly connect to the B terminal. See Figure 37 for a simplified

diagram of the equivalent RDAC circuit.

The AD8400 contains one RDAC, the AD8402 contains two

independent RDACs and the AD8403 contains four independent

RDACs. The general transfer equation that determines the digi-

tally programmed output resistance between Wx and Bx is:

where Dx is the data contained in the 8-bit RDAC# latch, and

For example, when V

following output resistance values will be set for the following

RDAC latch codes (applies to 10 k potentiometers):

(Dec)

255

128

Note in the zero-scale condition a finite wiper resistance of 50

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

tween W and B in this state to a maximum value of 5 mA to

avoid degradation or possible destruction of the internal switch

contact.

Like the mechanical potentiometer the RDAC replaces, it is to-

tally symmetrical. The resistance between the wiper W and ter-

minal A also produces a digitally controlled resistance R

When these terminals are used the B terminal should be tied to

the wiper. Setting the resistance value for R

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

RDAC latch is increased in value. The general transfer equation

for this operation is:

is the nominal end-to-end resistance.

+ 50 ] for data 01

. This B terminal connection has a wiper contact resis-

) of the VR has 256 contact points accessed by the

(Dx) = (256–Dx)/256

( )

10011

5050

(Dx) = (Dx)/256

= 0 V and A terminal is open circuit, the

Output State

Full Scale

Midscale (RS = 0 Condition)

1 LSB

Zero-Scale (Wiper Contact Resistance)

[= R

. The third connection is the next

(nominal resistance)/256 + R

+ R

for data 02

+ R

starts at a maxi-

. Each LSB

Equation 2

Equation 3

REV. B

AD8400AN10 Analog Devices, AD8400AN10 Datasheet - Page 12

AD8400AN10

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