AD589UH AD [Analog Devices], AD589UH Datasheet - Page 11

AD589UH

Manufacturer Part Number

AD589UH

Description

LC2MOS 5 us 8-Bit ADC with Track/Hold

Manufacturer

AD [Analog Devices]

Datasheet

1.AD589UH.pdf (12 pages)

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REV. B

The effect the TC has on the system error is that it introduces a

full-scale error in the ADC. This, in turn, affects the total unad-

justed error specification. For example, using the AD589KH

with a 50 ppm/ C max TC the change in reference voltage from

25 C to 70 C will be from 1.23 V to 1.22724 V, a change of –

2.76 mV. This results in a change in the full-scale range of the

ADC of –5.52 mV, since the full-scale range on the AD7575 is

2 V

AD589 introduces an additional full-scale error of –0.57 LSBs

on top of the existing full-scale error specification for the ADC.

Since the total unadjusted error specification for the ADC

includes the full-scale error, there is also a corresponding in-

crease in the total unadjusted error of –0.57 LSBs. The change

in reference voltage at 0 C is –1.5 mV, resulting in a full-scale

change of –3 mV or –0.31 LSBs worth of full-scale error. Table I

shows the amount of additional total unadjusted error, which is

introduced by the temperature variation of the AD589, for

different grades and for different temperature ranges. This table

applies only to nonratiometric applications, because the tem-

perature variation of the reference does not affect the system

error in ratiometric applications as outlined earlier. It shows the

amount of error introduced over T

which the reference has been adjusted to the desired value at

25 C. The final or right-most column of the table gives the total

combined error for the AD589 and the top grade AD7575.

Figure 20. Typical AD589 Temperature Characteristics

REF

1.2355

1.2370

1.2365

1.2360

1.2350

1.2345

. Because the LSB size for the AD7575 is 9.61 mV, the

–50

–25

AD589

Grade

AD589JH

AD589KH

AD589LH

AD589MH

AD589SH

AD589TH

AD589UH

*Excluding resistor and offset drift.

Table I. AD589/AD7575 Error over Temperature (Nonratiometric Applications)

TEMPERATURE – C

MIN

Temperature

Range

0 C to +70 C

–55 C to +125 C

to T

MAX

for a system in

100

Full-Scale Error Introduced

by AD589 @ T

(Worst Case)

–1.15 LSB

–0.57 LSB

–0.29 LSB

–0.115 LSB

–2.56 LSB

–1.28 LSB

–0.64 LSB

125

–11–

Taking the 25 C measurement as the starting point, the

full-scale error introduced is always in the negative direction

whether the temperature goes to T

seen from the AD589 temperature characteristic shown in Fig-

ure 20. If the reference voltage is adjusted for 1.23 V at 45 C

(for the 0 C to +70 C range) and 75 C (for the –55 C to

+125 C range) the magnitude of the error introduced is reduced

since it is distributed in both the positive and negative direc-

tions. Alternatively, this can be achieved not by adjusting at

these temperatures, which would be impractical, but by adjust-

ing the reference to 1.231 V instead of 1.23 V (for the extended

temperature range) at 25 C. This has the required effect of

distributing the plot of Figure 20 more evenly about the desired

value.

An additional error source is the mismatch between the tem-

perature coefficients (TCs) of the 10 k and 1 k resistors in

the feedback loop of the TLC271. If these resistors have

tween both resistors is 100 ppm/ C. From +25 C to +125 C, this

introduces a worst case shift of 1.22 mV, which results in an addi-

tional full-scale error of 0.25 LSB. If

used, then the worst case error is 0.13 LSB. Over the 0 C to

+70 C range, the 50 ppm/ C resistors introduce an additional

full-scale error of 0.11 LSB. All these errors are worst case and

assume that the resistance values drift in opposite directions. In

practice, resistors of the same type, and from the same manufac-

turer, would drift in the same direction and hence the above

error would be considerably reduced. An additional error source

is the offset drift of the TLC271. This is significant only over

the –55 C to +125 C range and, even in this case, it contrib-

utes <0.1 LSB worth of full-scale error.

The error outlined in the right-hand column of Table I is a total

unadjusted error specification, excluding resistor and offset drift

(the effect of these can be controlled by the user). It consists of

errors from two error sources: a l LSB contribution from the

AD7575 (including full-scale, offset and relative accuracy er-

rors), and the remainder is a full-scale error introduced by the

AD589. It is important to note that the variation of the AD589

voltage only introduces a full-scale error; the relative accuracy

(or endpoint nonlinearity) of the system, with a top grade

AD7575, is still 1/2 LSB (i.e., 8-bits accurate).

50 ppm/ C absolute TCs, the worst case difference in drift be-

MAX

Combined Worst Case

AD589/AD7575

T.U.E. @ T

–2.15 LSB

–1.57 LSB

–1.29 LSB

–1.115 LSB

–3.56 LSB

–2.28 LSB

–1.64 LSB

MIN

MAX

25 ppm/ C resistors are

or T

MAX

. This can be

AD7575

AD589UH AD [Analog Devices], AD589UH Datasheet - Page 11

AD589UH

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