AD1582A データシートの表示（PDF） - Analog Devices

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AD1582A

2.5 V to 5.0 V Micropower, Precision Series Mode Voltage References

Analog Devices 

AD1582/AD1583/AD1584/AD1585

Data Sheet

OUTPUT VOLTAGE HYSTERESIS

High performance industrial equipment manufacturers can

require the AD1582/AD1583/AD1584/AD1585 to maintain a

consistent output voltage error at 25°C after the references are

operated over the full temperature range. All references exhibit

a characteristic known as output voltage hysteresis; however, the

AD1582/AD1583/AD1584/AD1585 are designed to minimize

this characteristic. This phenomenon can be quantified by mea-

suring the change in the +25°C output voltage after temperature

excursions from +125°C to +25°C and from −40°C to +25°C.

Figure 13 displays the distribution of the AD1582/AD1583/

AD1584/AD1585 output voltage hysteresis.

80

70

60

50

40

30

20

10

0

–700

–450

–200

50

300

550

ppm

Figure 13. Output Voltage Hysteresis Distribution

SUPPLY CURRENT VS. TEMPERATURE

The quiescent current for the AD1582/AD1583/AD1584/

AD1585 varies slightly over temperature and input supply range.

Figure 14 illustrates the typical performance for the

AD1582/AD1583/AD1584/AD1585 reference when varying

both temperature and supply voltage. As is evident from

Figure 14, the AD1582/AD1583/AD1584/AD1585 supply

current increases only 1.0 μA/V, making this device extremely

attractive for use in applications where there can be wide

variations in supply voltage and a need to minimize power

dissipation.

100

80

60

TA = +85°C

TA = +25°C

40

TA = –40°C

20

SUPPLY VOLTAGE

One of the ideal features of the AD1582/AD1583/AD1584/AD1585

is low supply voltage headroom. The parts can operate at supply

voltages as low as 200 mV above VOUT and up to 12 V. However,

if negative voltage is inadvertently applied to VIN with respect to

ground, or any negative transient >5 V is coupled to VIN, the

device can be damaged.

AC PERFORMANCE

To apply the AD1582/AD1583/AD1584/AD1585, it is important

to understand the effects of dynamic output impedance and

power supply rejection. In Figure 15, a voltage divider

is formed by the AD1582/AD1583/AD1584/ AD1585 output

impedance and by the external source impedance. Figure 16

shows the effect of varying the load capacitor on the reference

output. Power supply rejection ratio (PSRR) should be determined

when characterizing the ac performance of a series voltage

reference. Figure 17 shows a test circuit used to measure PSRR,

and Figure 18 demonstrates the ability of the AD1582/AD1583/

AD1584/AD1585 to attenuate line voltage ripple.

VLOAD DC

5V

10kΩ

2 × VOUT

×1

2kΩ

10kΩ

DUT

5µF

±2V

10kΩ

±100µA

1µF

Figure 15. Output Impedance Test Circuit

100

1µF CAP

10

AD1585

AD1582

1

0.1

10

100

1k

10k

100k

1M

FREQUENCY (Hz)

Figure 16. Output Impedance vs. Frequency

10V

10kΩ

±200mV 10kΩ

×1

5V ± 100mV

0.22µF

DUT

VOUT

0.22µF

0

3

4

5

6

7

8

9

10

11

VIN (V)

Figure 14. Typical Supply Current over Temperature

Figure 17. Ripple Rejection Test Circuit

Rev. J | Page 12 of 16

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