DAC908 Datasheet, PDF(12/23 Page) Burr-Brown (TI) – 8-Bit, 165MSPS DIGITAL-TO-ANALOG CONVERTER

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

DAC908 Datasheet, PDF (12/23 Pages) Burr-Brown (TI) – 8-Bit, 165MSPS DIGITAL-TO-ANALOG CONVERTER

◁

As shown in Figure 3, the transformerâs center tap must be

connected to ground to enable the necessary DC-current

flow for both outputs. Some applications may require a solid

termination, in which case a differential resistor, RDIFF, may

be inserted as shown. Note that this will reduce the available

signal power by approximately one half.

ADT1-1WT

(Mini-Circuits)

1:1

IOUT

DAC908

Optional

RDIFF

50â¦

IOUT

50â¦

FIGURE 3. Differential Output Configuration Using an RF

Transformer.

DIFFERENTIAL CONFIGURATION USING AN OP AMP

If the application requires a DC-coupled output, a difference

amplifier may be considered, as shown in Figure 4. Four

external resistors are needed to configure the voltage-feed-

back op amp OPA680 as a difference amplifier performing

the differential to single-ended conversion. Under the shown

configuration, the DAC908 generates a differential output

signal of 0.5Vp-p at the load resistors, RL. The resistor

values shown were selected to result in a symmetric 25â¦

loading for each of the current outputs since the input

impedance of the difference amplifier is in parallel to resis-

tors RL, and should be considered.

IOUT

DAC908

IOUT

200â¦

CDIFF

26.1â¦

200â¦

28.7â¦

402â¦

OPA680

â5V +5V

402â¦

VOUT

FIGURE 4. Difference Amplifier Provides Differential to

Single-Ended Conversion and DC-Coupling.

The OPA680 is configured for a gain of two. Therefore,

operating the DAC908 with a 20mA full-scale output will

produce a voltage output of Â±1V. This requires the amplifier

to operate off of a dual power supply (Â±5V). The tolerance

of the resistors typically sets the limit for the achievable

common-mode rejection. An improvement can be obtained

by fine tuning resistor R4.

This configuration typically delivers a lower level of ac

performance than the previously discussed transformer solu-

tion because the amplifier introduces another source of

distortion. Suitable amplifiers should be selected based on

their slew-rate, harmonic distortion, and output swing capa-

bilities. High-speed amplifiers like the OPA680 or OPA687

may be considered. The ac performance of this circuit may

be improved by adding a small capacitor, CDIFF, between the

outputs IOUT and IOUT, as shown in Figure 4. This will intro-

duce a real pole to create a low-pass filter in order to slew-

limit the DACs fast output signal steps, which otherwise

could drive the amplifier into slew-limitations or into an

overload condition; both would cause excessive distortion.

The difference amplifier can easily be modified to add a

level shift for applications requiring the single-ended output

voltage to be unipolar, i.e., swing between 0V and +2V.

DUAL TRANSIMPEDANCE OUTPUT CONFIGURATION

The circuit example of Figure 5 shows the signal output

currents connected into the summing junction of the

OPA2680, which is set up as a transimpedance stage, or

I-to-V converter. With this circuit, the DACâs output will be

kept at a virtual ground, minimizing the effects of output

impedance variations, and resulting in the best DC linearity

(INL). However, as mentioned previously, the amplifier

may be driven into slew-rate limitations, and produce un-

wanted distortion. This may occur especially at high DAC

update rates.

+5V

50â¦

1/2

OPA2680

DAC908

RF1

IOUT

CD1

CF1

IOUT

CD2

RF2

CF2

1/2

OPA2680

50â¦

â5V

âVOUT = IOUT â¢ RF

FIGURE 5. Dual, Voltage-Feedback Amplifier OPA2680

Forms Differential Transimpedance Amplifier.

DAC908

SBAS109B

▷