DAC16GS View Datasheet(PDF) - Analog Devices

Part Name

Description

Manufacturer

DAC16GS

16-Bit High Speed Current-Output DAC

Analog Devices 

DAC16

–15V

20k⍀

1.6k⍀

INPUT

200⍀

+15V

14

IN4735

13

M1

16

360⍀

360⍀

+5V

MC10124

T/ H

–5V

0.39␮F

TO PIN 2

SD5000

249⍀ 169⍀

–5V

Q1 Q2

169⍀

510⍀ –5V

–15V

249⍀

Q1, Q2 = MPS571

M1 – M4 = SD5000

200⍀

11 12

M2

9

100pF

6

8

M3

5

34

M4

1

AD841

OUTPUT

500pF

75⍀

Figure 27. A High Performance Deglitching Circuit

A discrete drive circuit is used to achieve the best performance

from the SD5000 quad DMOS switch. This switch-driving cell

is composed of MPS571 RF NPN transistors and an MC10124

TTL-to-ECL translator. Using this technique provides both

high speed and highly symmetrical drive signals for the SD5000

switches. The switches arc arranged in a single-pole, double-

throw (SPDT) configuration. The 500 pF “flyback” capacitor is

switched to the op amp summing junction during the hold mode

to keep switching transients from feeding to the output. This ca-

pacitor is grounded during sample mode to minimize its effect

on acquisition time.

Careful circuit layout of the high speed SHA section is almost as

important as the design itself. Double-sided printed circuit

board, a compact layout, and short critical signal paths all ensure

best performance.

Op Amp Selection

When selecting the amplifier to be used for the DAC16’s I–V

converter, there are two main application areas; those requiring

high accuracy, and those seeking high speed. In high accuracy

applications, three parameters are of prime importance: (1)

input offset voltage. VOS; (2) input bias current, –IB; and (3) off-

set voltage drift, TCVOS. In these applications where 16-bit

performance must be maintained with an external reference

at +5 V, an op amp’s input offset voltage must be less than 15 µV

(≈0.1 LSB) with a bias current less than 6 nA. The op amp

must also exhibit high open-loop gain to keep the offset voltage

below this limit over the specified full-scale output range. Thus,

for a maximum output of 5 V, the op amp’s open loop gain

must be greater than 1300 V/mV.

For low frequency, high accuracy applications, Table IV lists

selected compatible operational amplifiers available from Analog

Devices. These operational amplifiers satisfy all the above

requirements and in most all cases will not require offset voltage

nulling.

Table V. Precision Operational Amplifier the DAC16

Model

OP177

OP77

OP27

OP97

VOS

10 µV

25 µV

25 µV

25 µV

TCVOS

0.3 µV/°C

0.6 µV/°C

0.3 µV/°C

2 µV/°C

IB

2 nA

2.8 nA

80 nA

0.15 nA

AVOL

12000 V/mV

2000 V/mV

1500 V/mV

2000 V/mV

In high speed applications where resolution is more important

than absolute accuracy, operational amplifiers such as the

AD843 offer the requisite settling time. Although these amplifi-

ers are not specified for 16-bit performance, their settling times

are two to three times faster than the DAC16 and will introduce

negligible error to the overall circuit’s settling time. It is possible

to estimate the 16-bit settling time of an operational amplifier if

its 12-bit settling time is known. Assuming that the op amp can

be modeled by a single-pole response, then the ratio of the op

amp’s 16-bit settling time to its 12-bit settling can be expressed

as:

ts(16 − bit ) = 1.33

ts(12 − bit )

Since many operational amplifier data sheets provide charts

illustrating 0.01% settling time versus output voltage step size,

all that is required to estimate an op amp’s 16-bit settling time is

to multiply the 12-bit settling time for the required full-scale

voltage by 1.33. The circuit’s overall settling time can then be

approximated by the root-sum-square method:

tS = (tDAC )2 + (tOA )2

where

tDAC = DAC16’s specified full-scale settling time

tOA = Op amp full-scale settling time

As a design aid, Table VI illustrates a high speed operational

amplifier selector guide for devices compatible with the DAC16

for high speed applications. All these devices exhibit the requi-

site settling time, input offset voltage, and input bias current

consistent with maximum performance.

Table VI. High Speed Operational Amplifiers for the DAC16

Model tS to %

VOS

TCVOS IB

AVOL

OP467 200 ns –0.01 0.5 mV 3.5 µV/°C 0.5 µA 20 V/mV

AD817 70 ns –0.01 2 mV 10 µV/°C 6.6 µA 6 V/mV

AD829 90 ns –0.1 0.5 mV 0.3 µV/°C 7 µA 100 V/mV

AD841 110 ns –0.01 1 mV 35 µV/°C 5 µA 45 V/mV

AD843 135 ns –0.01 1 mV 12 µV/°C 0.001 µA 25 V/mV

AD845 350 ns –0.01 0.25 mV 5 µV/°C 0.001 µA 500 V/mV

AD847 120 ns –0.01 1 mV 15 µV/°C 5 µA 5.5 V/mV

REV. B

–11–

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