AD7847BRR View Datasheet(PDF) - Analog Devices

Part Name

Description

Manufacturer

AD7847BRR

LC2MOS Complete, Dual 12-Bit MDACs

Analog Devices 

AD7837/AD7847

BIPOLAR OPERATION

(4-QUADRANT MULTIPLICATION)

Figure 16 shows the AD7837/AD7847 connected for bipolar

operation. The coding is offset binary as shown in Table IV.

When VIN is an ac signal, the circuit performs 4-quadrant multi-

plication. To maintain the gain error specifications, resistors R1,

R2 and R3 should be ratio matched to 0.01%. Note that on the

AD7847 the feedback resistor RFB is internally connected to

VOUT.

R1

20k⍀

VDD

R2

20k⍀

AD711

VOUT

AD7837

VDD

AD7847

VREFA

VIN

DAC A

RFBA *

VOUTA

R3

10k⍀

DGND AGNDA

*INTERNALLY

VSS

CONNECTED

ON AD7847

VSS

Figure 16. Bipolar Offset Binary Operation

Table IV. Bipolar Code Table

DAC Latch Contents

MSB

LSB

Analog Output, VOUT

1111 1111 1111

1000 0000 0001

1000 0000 0000

0111 1111 1111

0000 0000 0000

Note 1 LSB = V IN .

2048

+VIN ×

 2047 

 2048 

+V IN

×

 1

 2048 

0V

–V IN

×

 1

 2048 

–V IN

×

 2048 

 2048 

=

–V IN

APPLICATIONS

PROGRAMMABLE GAIN AMPLIFIER (PGA)

The dual DAC/amplifier combination along with access to RFB

make the AD7837 ideal as a programmable gain amplifier. In this

application, the DAC functions as a programmable resistor in the

amplifier feedback loop. This type of configuration is shown

in Figure 17 and is suitable for ac gain control. The circuit con-

sists of two PGAs in series. Use of a dual configuration provides

greater accuracy over a wider dynamic range than a single PGA

solution. The overall system gain is the product of the individual

gain stages. The effective gains for each stage are controlled by

the DAC codes. As the code decreases, the effective DAC

resistance increases, and so the gain also increases.

VIN

VOUT

RFBA

AGNDA

VREFB

DAC B

VOUTB

VREFA

DAC A

VOUTA

AD7837

RFBB

AGNDB

Figure 17. Dual PGA Circuit

The transfer function is given by

VOUT = REQA × REQB

VIN RFBA RFBB

(1)

where REQA, REQB are the effective DAC resistances controlled

by the digital input code:

REQ

=

212 RIN

N

(2)

where RIN is the DAC input resistance and is equal to RFB and

N = DAC input code in decimal.

The transfer function in (1) thus simplifies to

VOUT = 212 × 212

VIN N A NB

(3)

where NA = DAC A input code in decimal and NB = DAC B

input code in decimal.

NA, NB may be programmed between 1 and (212–1). The zero

code is not allowed as it results in an open loop amplifier

response. To minimize errors, the digital codes NA and NB

should be chosen to be equal to or as close as possible to each

other to achieve the required gain.

REV. C

–9–

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