EVAL-ADUC831QSZ Datasheet, PDF(33/76 Page) Analog Devices – MicroConverter®, 12-Bit ADCs and DACs with Embedded 62 kBytes Flash MCU

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EVAL-ADUC831QSZ Datasheet, PDF (33/76 Pages) Analog Devices – MicroConverter®, 12-Bit ADCs and DACs with Embedded 62 kBytes Flash MCU

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Using the DAC

The on-chip DAC architecture consists of a resistor string DAC

followed by an output buffer amplifier, the functional equivalent

of which is illustrated in Figure 21. Details of the actual DAC

architecture can be found in U.S. Patent Number 5969657

(www.uspto.gov). Features of this architecture include inherent

guaranteed monotonicity and excellent differential linearity.

VDD

VDD â50mV

VDD â100mV

ADuC831

AVDD

VREF

ADuC831

OUTPUT

BUFFER

DAC0

HIGH Z

DISABLE

(FROM MCU)

Figure 21. Resistor String DAC Functional Equivalent

As illustrated in Figure 21, the reference source for each DAC is

user selectable in software. It can be either AVDD or VREF. In

0-to-AVDD mode, the DAC output transfer function spans from

0 V to the voltage at the AVDD pin. In 0-to-VREF mode, the

DAC output transfer function spans from 0 V to the internal

VREF, or if an external reference is applied, the voltage at the

VREF pin. The DAC output buffer amplifier features a true rail-

to-rail output stage implementation. This means that, unloaded,

each output is capable of swinging to within less than 100 mV of

both AVDD and ground. Moreover, the DACâs linearity specifi-

cation (when driving a 10 kâ¦ resistive load to ground) is

guaranteed through the full transfer function except codes 0 to

100, and, in 0-to-AVDD mode only, codes 3945 to 4095. Linear-

ity degradation near ground and VDD is caused by saturation of

the output amplifier, and a general representation of its effects

(neglecting offset and gain error) is illustrated in Figure 22. The

dotted line in Figure 22 indicates the ideal transfer function,

and the solid line represents what the transfer function might

look like with endpoint nonlinearities due to saturation of the

output amplifier. Note that Figure 22 represents a transfer

function in 0-to-VDD mode only. In 0-to-VREF mode (with VREF

< VDD) the lower nonlinearity would be similar, but the upper

portion of the transfer function would follow the âidealâ line

right to the end (VREF in this case, not VDD), showing no signs

of endpoint linearity errors.

100mV

50mV

0mV

000H

FFFH

Figure 22. Endpoint Nonlinearities Due to Amplifier

Saturation

The end point nonlinearities conceptually illustrated in Figure

22 get worse as a function of output loading. Most of the

ADuC831âs data sheet specifications assume a 10 kâ¦ resistive

load to ground at the DAC output. As the output is forced to

source or sink more current, the nonlinear regions at the top or

bottom (respectively) of Figure 22 become larger. With larger

current demands, this can significantly limit output voltage

swing. Figure 23 and Figure 24 illustrate this behavior. It

should be noted that the upper trace in each of these figures is

only valid for an output range selection of 0-to-AVDD. In 0-to-

VREF mode, DAC loading will not cause highside voltage drops

as long as the reference voltage remains below the upper trace in

the corresponding figure. For example, if AVDD = 3 V and VREF

= 2.5 V, the highside voltage will not be affected by loads less

than 5 mA. But somewhere around 7 mA the upper curve in

Figure 24 drops below 2.5 V (VREF) indicating that at these

higher currents the output will not be capable of reaching VREF.

DAC LOADED WITH 0FFFH

DAC LOADED WITH 0000H

SOURCE/SINK CURRENT â mA

Figure 23. Source and Sink Current Capability with

VREF = VDD = 5 V

REV. 0

â33â

▷