AD561 Analog Devices, AD561 Datasheet - Page 6

AD561

Manufacturer Part Number

AD561

Description

Low Cost 10-Bit Monolithic D/A Converter

Manufacturer

Analog Devices

Datasheet

1.AD561.pdf (8 pages)

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AD561

ratio such that it is unnecessary to use additional area for ladder

resistors. The current in Q

properly, but is not switched to the output; thus, full scale is

1023/1024

The switching cell of Q

current either to ground (BIT 1 low) or to the DAC output

(BIT 1 high). The entire switching cell carries the same current

whether the bit is on or off, minimizing thermal transients and

ground current errors. The logic threshold, which is generated

from the positive supply (see Digital Logic Interface), is applied

to one side of each cell.

DIGITAL LOGIC INTERFACE

All standard positive supply logic families interface easily with

the AD561. The digital code is positive true binary (all bits

high, Logic “1,” gives positive full scale output). The logic input

load factor (100 nA max at Logic “1,” –25 A max at Logic “0,”

3 pF capacitance), is less than one equivalent digital load for all

logic families, including unbuffered CMOS. The digital

threshold is set internally as a function of the positive supply, as

shown in Figure 6. For most applications, connecting V

positive logic supply will set the threshold at the proper level for

maximum noise immunity. For nonstandard applications, refer

to Figure 6 for threshold levels. Uncommitted bit input lines

Figure 5. Circuit Diagram Showing Reference, Control Amplifier, Switching Cell, R-2R Ladder, and Bit Arrangement

of AD561

Figure 6. Digital Threshold vs. Positive Supply

2 mA.

, Q

is added to the ladder to balance it

and Q

serves to steer the cell

to the

–6–

will assume a “1” state (similar to TTL), but they are high

impedance and subject to noise pickup. Unused digital inputs

should be directly connected to ground or V

SETTLING TIME

The high speed NPN current steering switching cell and

internally compensated reference amplifier of the AD561 are

specifically designed for fast settling operation. The typical

settling time to 0.05% (1/2 LSB) for the worst case transition

(major carry, 0111111111 to 1000000000) is less than 250 ns;

the lower order bits all settle in less than 200 ns. (Worst case

settling occurs when all bits are switched, especially the MSB.)

Full realization of this high speed performance requires strict

attention to detail by the user in all areas of application and

testing.

The settling time for the AD561 is specified in terms of the

current output, an inherently high speed DAC operating mode.

However, most DAC applications require a current-to-voltage

conversion at some point in the signal path, although an

unbuffered voltage level (not using an op amp) is suitable for

use in a successive-approximation A/D converter (see page 8),

or in many display applications. This form of conversion can

give very fast operation if proper design and layout is done. The

fastest voltage conversion is achieved by connecting a low value

resistor directly to the output, as shown in Figure 9. In this case,

the settling time is primarily determined by the cell switching

time and by the RC time constant of the AD561 output capaci-

tance of 25 picofarads (plus stray capacitance) combined with the

output resistor value. Settling to 0.05% of full scale (for a full-

scale transition) requires 7.6 time constants. This effect is

important for R > 1 k .

If an op amp must be used to provide a low impedance output

signal, some loss in settling time will be seen due to op amp

dynamics. The normal current-to-voltage converter op amp

circuits are shown in the applications circuits on page 5, using

the fast settling AD509. The circuits shown settle to 1/2 LSB

in 600 ns unipolar and 1.1 s bipolar. The DAC output

capacitance, which acts as a stray capacitance at the op amp

inverting input, must be compensated by a feedback capacitor,

as shown. The value should be carefully chosen for each

application and each op amp type.

, as desired.

REV. A

AD561 Analog Devices, AD561 Datasheet - Page 6

AD561

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