AD812ANZ Datasheet AD812ARZ, AD812ARZ-REEL7, AD812ANZ | P7-P9

20

0

020

15

5

10

10 15

SUPPLY VOLTAGE – 6Volts

COMMON-MODE VOLTAGE RANGE – 6Volts

Figure 4. Input Common-Mode Voltage Range vs. Supply

Voltage

20

0

020

15

5

10

10 15

SUPPLY VOLTAGE – 6Volts

OUTPUT VOLTAGE – V p-p

R

L

= 150V

NO LOAD

Figure 5. Output Voltage Swing vs. Supply Voltage

30

15

0

10 100 10k1k

10

5

20

25

LOAD RESISTANCE – V

OUTPUT VOLTAGE – Volts p-p

615V SUPPLY

65V SUPPLY

Figure 6. Output Voltage Swing vs. Load Resistance

16

4

10

6

8

14

12

140–40–60 120806040 100200–20

JUNCTION TEMPERATURE – 8C

TOTAL SUPPLY CURRENT – mA

V

S

= 615V

V

S

= 65V

Figure 7. Total Supply Current vs. Junction Temperature

10

5

8

6

7

9

16

20

141210

864

SUPPLY VOLTAGE – 6Volts

TOTAL SUPPLY CURRENT – mA

T

A

= +25 C

Figure 8. Total Supply Current vs. Supply Voltage

25

–25

–10

–20

–15

5

–5

0

10

15

20

–60

140–40 120100806040200–20

INPUT BIAS CURRENT – mA

JUNCTION TEMPERATURE – 8C

–I

B

, V

S

= 615V

+I

B

, V

S

= 65V, 615V

–I

B

, V

S

= 65V

Figure 9. Input Bias Current vs. Junction Temperature

AD812–Typical Performance Characteristics

REV. B

–6–

AD812

–7–

REV. B

4

–16

–10

–14

–12

–4

–8

–6

–2

0

2

140–40–60 120100806040200–20

INPUT OFFSET VOLTAGE – mV

JUNCTION TEMPERATURE – 8C

V

S

= 615V

V

S

= 65V

Figure 10. Input Offset Voltage vs. Junction Temperature

160

40

100

60

80

140

120

140–40–60 120806040 100200–20

JUNCTION TEMPERATURE – 8C

SHORT CIRCUIT CURRENT – mA

SINK

V

S

= 615V

SOURCE

Figure 11. Short Circuit Current vs. Junction Temperature

80

20

50

30

40

70

60

140–40–60 120806040 100200–20

JUNCTION TEMPERATURE – 8C

OUTPUT CURRENT – mA

V

S

= 615V

V

S

= 65V

Figure 12. Linear Output Current vs. Junction Temperature

70

20

50

30

40

60

20

50

1510

SUPPLY VOLTAGE – 6Volts

OUTPUT CURRENT – mA

Figure 13. Linear Output Current vs. Supply Voltage

100k 100M10M1M10k

0.01

1k

10

1

0.1

100

FREQUENCY – Hz

CLOSED-LOOP OUTPUT RESISTANCE – V

615V

S

65V

S

G = +2

Figure 14. Closed-Loop Output Resistance vs. Frequency

30

15

0

100k 1M 100M10M

10

5

20

25

FREQUENCY – Hz

OUTPUT VOLTAGE – V p-p

V

S

= 615V

V

S

= 65V

R

L

= 1kV

Figure 15. Large Signal Frequency Response

AD812

REV. B

–8–

100

10

1

10

100 100k10k1k

FREQUENCY – Hz

VOLTAGE NOISE – nV/ Hz

100

10

1

CURRENT NOISE – pA/ Hz

INVERTING INPUT

CURRENT NOISE

VOLTAGE NOISE

NONINVERTING INPUT

CURRENT NOISE

Figure 16. Input Current and Voltage Noise vs. Frequency

10k

100k 100M10M1M

FREQUENCY – Hz

90

60

50

70

80

20

10

30

40

COMMON-MODE REJECTION – dB

681V

V

OUT

V

IN

681V

V

S

= 615V

V

S

= 3V

Figure 17. Common-Mode Rejection vs. Frequency

FREQUENCY – Hz

POWER SUPPLY REJECTION – dB

80

40

0

10k

100k 100M10M1M

20

60

50

30

10

70

615V

61.5V

Figure 18. Power Supply Rejection vs. Frequency

10k 100k 100M10M1M

FREQUENCY – Hz

100

40

120

60

80

TRANSIMPEDANCE – dB

0

–45

–90

–135

–180

PHASE – Degrees

PHASE

GAIN

V

S

= 3V

V

S

= 615V

V

S

= 3V

V

S

= 615V

Figure 19. Open-Loop Transimpedance vs. Frequency

(Relative to 1

Ω

)

–30

FREQUENCY – Hz

HARMONIC DISTORTION – dBc

1k

–130

10k 100k 1M 10M 100M

–70

–50

–110

–90

G = +2

V

S

= 2V p-p

V

S

= 615V ; R

L

= 1kV

V

S

= 65V ; R

L

= 150V

V

S

= 65V

2

ND

HARMONIC

3

RD

HARMONIC

2

ND

3

RD

V

S

= 615V

Figure 20. Harmonic Distortion vs. Frequency

SETTLING TIME – ns

OUTPUT SWING FROM 6V TO 0

10

–10

60

–4

–8

–6

20

2

–2

0

4

6

8

4030 50

0.1%

GAIN = –1

V

S

= 615V

1%

0.025%

Figure 21. Output Swing and Error vs. Settling Time

AD812ANZ

AD812ANZ

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