7

®

DAC8043

AMPLIFIER OFFSET VOLTAGE

The output amplifier used with the DAC8043 should have

low input offset voltage to preserve the transfer function

linearity. The voltage output of the amplifier has an error

component which is the offset voltage of the op amp multi-

plied by the “noise gain” of the circuit. This “noise gain” is

ance. The nonlinearity occurs due to the output impedance

varying with code. If the 0 code case is excluded (where

“noise gain” variation between 4/3 and 2. In addition, the

differential nonlinearity is also likely to be experienced. The

nonlinearity seen at the amplifier output is

2V

Thus, to maintain good nonlinearity the op amp offset should

be much less than 1/2LSB.

UNIPOLAR CONFIGURATION

Figure 3 shows DAC8043 in a typical unipolar (two-quad-

rant) multiplying configuration. The analog output values

versus digital input code are listed in Table I. The operational

amplifiers used in this circuit can be single amplifiers such as

the OPA602, or a dual amplifier such as the OPA2107. C1

provides phase compensation to minimize settling time and

overshoot when using a high speed operational amplifier.

If an application requires the D/A to have zero gain error, the

circuit shown in Figure 4 may be used. Resistor R2 induces

a positive gain error greater than worst-case initial negative

gain error. Trim resistor R1 provides a variable negative gain

error and have sufficient trim range to correct for the worst-

case initial positive gain error plus the error produced by R2.

BIPOLAR CONFIGURATION

Figure 5 shows the DAC8043 in a typical bipolar (four-

quadrant) multiplying configuration. The analog output val-

ues versus digital input code are listed in Table II.

The operational amplifiers used in this circuit can be single

amplifiers such as the OPA602 or a dual amplifier such as

the OPA2107. C1 provides phase compensation to minimize

settling time and overshoot when using a high speed opera-

tional amplifier. The bipolar offset resistors R1–R2 should

be ratio-matched to 0.01% to ensure the specified gain error

performance.

DATA INPUT

ANALOG OUTPUT

MSB

↓↓ LSB

1111 1111 1111

1000 0000 0000

0000 0000 0001

0000 0000 0000

0 Volts

TABLE I. Unipolar Output Code.

DATA INPUT

ANALOG OUTPUT

MSB

↓↓ LSB

1111 1111 1111

+V

1000 0000 0001

+V

1000 0000 0000

0 Volts

0111 1111 1111

–V

0000 0000 0000

–V

TABLE II. Bipolar Output Code.

R

2

Ω

47

DAC

I

OUT

GND

R

FB

C

V

OUT

–

+

A1

V

DD

+5V

C

D

A1 OPA602 or 1/2 OPA2107.

+

1µF

V

IN

R

100

1

Ω

REF

V

DAC8043

FIGURE 4. Unipolar Configuration with Gain Trim.

FIGURE 3. Unipolar Configuration.

DAC

I

OUT

GND

R

FB

C

1

10pF

DAC8043

V

OUT

–

+

A1

V

REF

V

DD

+5V

C

D

A1 OPA602 or 1/2 OPA2107.

+

1µF

FIGURE 5. Bipolar Configuration.

R

3

10k

1

C

10pF

DAC

V

REF

V

DD

+5V

C

D

R

2

Ω

20k

V

OUT

A1

A1–A2, OPA602 or 1/2 OPA2107.

A2

–

+

Ω

R

1

Ω

20k

I

OUT

R

FB

–

+

GND

1µF

+

DAC8043