05F6971_技术文档

Ultralow Input Bias Current

Operational Amplifier

a

AD549*

CONNECTION DIAGRAM

FEATURES

Ultralow Bias Current: 60 fA max (AD549L)

250 fA max (AD549J)

Input Bias Current Guaranteed Over Common-Mode

Voltage Range

Low Offset Voltage: 0.25 mV max (AD549K)

1.00 mV max (AD549J)

Low Offset Drift: 5 ␮V/؇C max (AD549K)

20 ␮V/؇C max (AD549J)

GUARD PIN, CONNECTED TO CASE

NC

OFFSET NULL

8

V+

1

7

5

AD549

INVERTING

2

6

OUTPUT

INPUT

3

Low Power: 700 ␮A max Supply Current

Low Input Voltage Noise: 4 ␮V p-p 0.1 Hz to 10 Hz

MIL-STD-883B Parts Available

OFFSET

NULL

4

NONINVERTING

INPUT

V–

10kΩ

APPLICATIONS

5

1

Electrometer Amplifiers

Photodiode Preamp

pH Electrode Buffer

–15V

4

V

TRIM

OS

NC = NO CONNECTION

Vacuum lon Gage Measurement

PRODUCT DESCRIPTION

The AD549 is available in four performance grades. The J, K,

and L versions are rated over the commercial temperature range

0°C to +70°C. The S grade is specified over the military tem-

perature range of –55°C to +125°C and is available processed to

MIL-STD-883B, Rev C. Extended reliability PLUS screening is

also available. Plus screening includes 168-hour burn-in, as

well as other environmental and physical tests derived from

MIL-STD-883B, Rev C.

The AD549 is a monolithic electrometer operational amplifier

with very low input bias current. Input offset voltage and input

offset voltage drift are laser trimmed for precision performance.

The AD549’s ultralow input current is achieved with “Topgate”

JFET technology, a process development exclusive to Analog

Devices. This technology allows the fabrication of extremely low

input current JFETs compatible with a standard junction-

isolated bipolar process. The 10¹⁵Ω common-mode impedance,

a result of the bootstrapped input stage, insures that the input

current is essentially independent of common-mode voltage.

PRODUCT HIGHLIGHTS

1. The AD549’s input currents are specified, 100% tested and

guaranteed after the device is warmed up. Input current is

guaranteed over the entire common-mode input voltage

range.

The AD549 is suited for applications requiring very low input

current and low input offset voltage. It excels as a preamp for a

wide variety of current output transducers such as photodiodes,

photomultiplier tubes, or oxygen sensors. The AD549 can also

be used as a precision integrator or low droop sample and hold.

The AD549 is pin compatible with standard FET and electrom-

eter op amps, allowing designers to upgrade the performance of

present systems at little additional cost.

2. The AD549’s input offset voltage and drift are laser trimmed

to 0.25 mV and 5 µV/°C (AD549K), 1 mV and 20 µV/°C

(AD549J).

3. A maximum quiescent supply current of 700 µA minimizes

heating effects on input current and offset voltage.

The AD549 is available in a TO-99 hermetic package. The case

is connected to Pin 8 so that the metal case can be independently

connected to a point at the same potential as the input termi-

nals, minimizing stray leakage to the case.

4. AC specifications include 1 MHz unity gain bandwidth and

3 V/µs slew rate. Settling time for a 10 V input step is 5 µs to

0.01%.

5. The AD549 is an improved replacement for the AD515,

OPA104, and 3528.

*Protected by Patent No. 4,639,683.

REV. A

Information furnished by Analog Devices is believed to be accurate and

reliable. However, no responsibility is assumed by Analog Devices for its

use, nor for any infringements of patents or other rights of third parties

which may result from its use. No license is granted by implication or

otherwise under any patent or patent rights of Analog Devices.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 617/329-4700

Fax: 617/326-8703

(@ +25؇C and V = +15 V dc, unless otherwise noted)

AD549–SPECIFICATIONS

S

Model

AD549J

Typ

AD549K

Typ

AD549L

Typ

AD549S

Typ

Min

Max

Min

Max

Min

Max

Min

Max

Units

INPUT BIAS CURRENT¹

Either Input, V_CM= 0 V

Either Input, V_CM= ±10 V

150

250

75

100

40

60

75

100

fA

Either Input at T_MAX

V_CM= 0 V

Offset Current

,

11

50

2.2

4.2

30

1.3

2.8

20

0.85

420

30

125

pA

fA

pA

Offset Current at T_MAX

INPUT OFFSET VOLTAGE²

Initial Offset

Offset at T_MAX

vs. Temperature

vs. Supply

0.5

1.0

1.9

20

100

0.15

0.25

0.4

5

32

0.3

0.5

0.9

10

32

0.3

0.5

2.0

15

32

50

mV

µV/°C

µV/V

10

32

15

2

5

10

32

15

10

15

10

15

vs. Supply, T_MINto T_MAX

Long-Term Offset Stability

µV/Month

INPUT VOLTAGE NOISE

f = 0.1 Hz to 10 Hz

f = 10 Hz

f = 100 Hz

f = 1 kHz

4

6

4

µV p-p

90

60

35

90

60

35

90

60

35

90

60

35

nV/√Hz

f = 10 kHz

INPUT CURRENT NOISE

f = 0.1 Hz to 10 Hz

f = 1 kHz

0.7

0.22

0.5

0.16

0.36

0.11

0.5

0.16

fA rms

fA/√Hz

INPUT IMPEDANCE

Differential

V

_DIFF= ±1

10¹³ʈ1

ΩʈpF

Common Mode

V_CM= ±10

10¹⁵ʈ0.8

OPEN-LOOP GAIN

V_O@ ±10 V, R_L= 10 k

300

1000

300

1000

300

1000

300

1000

V/mV

V

_O@ ±10 V, R_L= 10 k,

T_MINto T_MAX

V_O= ±10 V, R_L= 2 k

300

100

800

250

300

100

800

250

300

100

800

250

300

100

800

250

V/mV

V

_O= ±10 V, R_L= 2 k,

T_MINto T_MAX

80

200

80

200

80

200

25

150

V/mV

INPUT VOLTAGE RANGE

Differential³

Common-Mode Voltage

Common-Mode Rejection Ratio

V = +10 V, –10 V

±20

+10

±20

+10

±20

+10

±20

+10

V

–10

80

76

90

80

90

80

100

90

80

100

90

80

100

90

dB

T_MINto T_MAX

OUTPUT CHARACTERISTICS

Voltage @ R_L= 10 k,

T_MINto T_MAX

–12

+12

–12

+12

–12

+12

–12

+12

V

Voltage @ R_L= 2 k,

T_MINto T_MAX

Short Circuit Current

T_MINto T_MAX

–10

15

9

+10

35

–10

15

9

+10

35

–10

15

9

+10

35

–10

15

6

+10

35

V

mA

20

Load Capacitance Stability

G = +1

4000

pF

FREQUENCY RESPONSE

Unity Gain, Small Signal

Full Power Response

Slew Rate

Settling Time, 0.1%

0.01%

0.7

2

1.0

50

3

4.5

5

0.7

2

1.0

50

3

4.5

5

0.7

2

1.0

50

3

4.5

5

0.7

2

1.0

50

3

4.5

5

MHz

kHz

V/µs

µs

Overload Recovery,

50% Overdrive, G = –1

2

µs

–2–

REV. A

AD549

Model

AD549J

Typ

AD549K

Typ

AD549L

Typ

AD549S

Typ

Min

Max

Min

Max

Min

Max

Min

Max

Units

POWER SUPPLY

Rated Performance

Operating

±15

V

؎5

؎18

؎5

؎18

؎5

؎18

؎5

؎18

Quiescent Current

0.60

0.70

0.60

0.70

0.60

0.70

0.60

0.70

mA

TEMPERATURE RANGE

Operating, Rated Performance

Storage

0

–65

+70

+150

0

–65

+70

+150

0

–65

+70

+150

–55

–65

+125

+150

°C

PACKAGE OPTION

TO-99 (H-08A)

Chips

AD549JH

AD549JChips

AD549KH

AD549LH

AD549SH, AD549SH/883B

NOTES

¹Bias current specifications are guaranteed after 5 minutes of operation at T_A= +25°C. Bias current increases by a factor of 2.3 for every 10°C rise in temperature.

²Input offset voltage specifications are guaranteed after 5 minutes of operation at T_A= +25°C.

³Defined as max continuous voltage between the inputs such that neither input exceeds ±10 V from ground.

Specifications subject to change without notice.

All min and max specifications are guaranteed. Specifications in boldface are tested on all production units at final electrical test. Results from those tests are used to

calculate outgoing quality levels.

ABSOLUTE MAXIMUM RATINGS¹

METALIZATION PHOTOGRAPH

Dimensions shown in inches and (mm).

Contact factory for latest dimensions.

Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±18 V

Internal Power Dissipation . . . . . . . . . . . . . . . . . . . . . .500 mW

Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±18 V²

Output Short Circuit Duration . . . . . . . . . . . . . . . . . Indefinite

Differential Input Voltage . . . . . . . . . . . . . . . . . . +V_Sand –V_S

Storage Temperature Range (H) . . . . . . . . . .–65°C to +125°C

Operating Temperature Range

AD549J (K, L) . . . . . . . . . . . . . . . . . . . . . . . . 0°C to +70°C

AD549S . . . . . . . . . . . . . . . . . . . . . . . . . . –55°C to +125°C

Lead Temperature Range (Soldering 60 sec) . . . . . . . . +300°C

NOTES

¹Stresses above those listed under “Absolute Maximum Ratings” may cause

permanent damage to the device. This is a stress rating only and functional

operation of the device at these or any other conditions above those indicated in the

operational section of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods may affect device reliability.

²For supply voltages less than ±18 V, the absolute maximum input voltage is equal

to the supply voltage.

CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily

accumulate on the human body and test equipment and can discharge without detection.

Although the AD549 features proprietary ESD protection circuitry, permanent damage may

occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD

precautions are recommended to avoid performance degradation or loss of functionality.

WARNING!

ESD SENSITIVE DEVICE

REV. A

–3–

AD549–Typical Characteristics

20

15

10

5

20

15

10

5

30

25

20

15

10

5

+25°C

= 10k

+V

OUT

R

L

V

= ±15 VOLTS

S

+V

IN

–V

OUT

–V

IN

0

10

100

1k

10k

100k

0

5

10

15

20

0

5

10

15

20

LOAD RESISTANCE – Ω

SUPPLY VOLTAGE ± V

Figure 2. Output Voltage

Swing vs. Supply Voltage

Figure 3. Output Voltage

Swing vs. Load Resistance

Figure 1. Input Voltage Range

vs. Supply Voltage

3000

120

110

100

90

800

700

600

1000

300

100

500

400

80

70

–15

–10

0

+10

+15

0

5

10

15

20

0

5

10

15

20

INPUT COMMON-MODE VOLTAGE – V

SUPPLY VOLTAGE ± V

Figure 5. CMRR vs. Input

Common-Mode Voltage

Figure 6. Open-Loop Gain vs.

Supply Voltage

Figure 4. Quiescent Current

vs. Supply Voltage

30

25

3000

50

45

40

35

30

1000

20

15

300

100

10

5

25

20

0

–10

–5

0

5

10

–55 –25

5

35

65

95

125

0

1

2

3

4

5

6

7

COMMON-MODE VOLTAGE ± V

TEMPERATURE – °C

WARM-UP TIME – Minutes

Figure 9. Input Bias Current

vs. Common-Mode Voltage

Figure 7. Open-Loop Gain vs.

Temperature

Figure 8. Change in Offset

Voltage vs. Warm-Up Time

–4–

REV. A

AD549

50

45

40

35

30

160

140

100k

10k

1k

WHENEVER JOHNSON NOISE IS GREATER THAN

AMPLIFIER NOISE, AMPLIFIER NOISE CAN BE

CONSIDERED NEGLIGIBLE FOR THE APPLICATION

1kHz BANDWIDTH

120

100

RESISTOR

JOHNSON NOISE

100

10

80

60

40

20

10Hz

BANDWIDTH

1

AMPLIFIER GENERATED NOISE

25

20

0.1

10

100

1k

10k

100k 1M

10M

100M

1G

10G 100G

0

5

10

15

20

SOURCE RESISTANCE – Ω

FREQUENCY – Hz

POWER SUPPLY VOLTAGE ± V

Figure 12. Noise vs. Source

Resistance

Figure 10. Input Bias Current

vs. Supply Voltage

Figure 11. Input Voltage Noise

Spectral Density

100

80

60

40

20

0

100

40

35

30

25

20

15

10

80

60

40

20

0

80

60

40

20

0

–20

–40

–20

–40

5

0

–20

10

100

1k

10k

100k

1M

10

100

1k

10k

100k 1M

10M

10

100

1k

10k

100k 1M

10M

FREQUENCY – Hz

Figure 13. Open-Loop

Frequency Response

Figure 14. Large Signal

Frequency Response

Figure 15. CMRR vs. Frequency

10

5

120

100

80

10mV

5mV

1mV

+ SUPPLY

60

0

–5

40

10mV

5mV

– SUPPLY

20

1mV

0

–20

–10

0

1

2

3

4

5

10

100

1k

10k

100k 1M

10M

SETTLING TIME – µs

FREQUENCY – Hz

Figure 16. PSRR vs. Frequency

Figure 17. Output Voltage

Swing and Error vs.

Settling Time

REV. A

–5–

AD549

Figure 19. Unity Gain Follower

Large Signal Pulse Response

Figure 20. Unity Gain Follower

Small Signal Pulse Response

Figure 18. Unity Gain

Follower

Figure 23. Unity Gain Inverter

Small Signal Pulse Response

Figure 22. Unity Gain Inverter

Large Signal Pulse Response

Figure 21. Unity Gain Inverter

MINIMIZING INPUT CURRENT

However, heavy output loads can cause a significant increase

in chip temperature and a corresponding increase in input

current. Maintaining a minimum load resistance of 10 Ω is rec-

ommended. Input current versus additional power dissipation

due to output drive current is plotted in Figure 25.

The AD549 has been optimized for low input current and offset

voltage. Careful attention to how the amplifier is used will reduce

input currents in actual applications.

The amplifier operating temperature should be kept as low as pos-

sible to minimize input current. Like other JFET input amplifiers,

the AD549’s input current is sensitive to chip temperature, rising

by a factor of 2.3 for every 10°C rise. This is illustrated in Figure

24, a plot of AD549 input current versus ambient temperature.

6.0

5.0

BASED ON

TYPICAL I = 40fA

B

1nA

100pA

10pA

1pA

4.0

3.0

2.0

1.0

100fA

10fA

1fA

0

25

50

75 100 125 150 175 200

ADDITIONAL INTERNAL POWER DISSIPATION – mW

Figure 25. AD549 Input Bias Current vs.

Additional Power Dissipation

–55

–25

5

35

65

95

125

TEMPERATURE – °C

CIRCUIT BOARD NOTES

There are a number of physical phenomena that generate

spurious currents that degrade the accuracy of low current

measurements. Figure 26 is a schematic of an I-to-V converter

with these parasitic currents modeled.

Figure 24. AD549 Input Bias Current vs.

Ambient Temperature

On-chip power dissipation will raise chip operating temperature

causing an increase in input bias current. Due to the AD549’s

low quiescent supply current, chip temperature when the (un-

loaded) amplifier is operated with 15 V supplies, is less than 3°C

higher than ambient. The difference in input current is negligible.

Finite resistance from input lines to voltages on the board,

modeled by resistor R_P, results in parasitic leakage. Insulation

resistance of over 10¹⁵Ω must be maintained between the

amplifier’s signal and supply lines in order to capitalize on the

AD549’s low input currents. Standard PC board material

–6–

REV. A

AD549

mized. Input capacitance can substantially degrade signal band-

width and the stability of the I-to-V converter. The case of the

AD549 is connected to Pin 8 so that it can be bootstrapped

near the input potential. This minimizes pin leakage and input

common-mode capacitance due to the case. Guard schemes for

inverting and noninverting amplifier topologies are illustrated in

Figures 28 and 29.

does not have high enough insulation resistance. Therefore, the

AD549’s input leads should be connected to standoffs made of

insulating material with adequate volume resistivity (e.g.,

Teflon*). The surface of the insulator’s surface must be kept

clean in order to preserve surface resistivity. For Teflon, an ef-

fective cleaning procedure consists of swabbing the surface with

high-grade isopropyl alcohol, rinsing with deionized water, and

baking the board at 80°C for 10 minutes.

Figure 28. Inverting Amplifier with Guard

Figure 26. Sources of Parasitic Leakage Currents

In addition to high volume and surface resistivity, other proper-

ties are desirable in the insulating material chosen. Resistance to

water absorption is important since surface water films drasti-

cally reduce surface resistivity. The insulator chosen should also

exhibit minimal piezoelectric effects (charge emission due to

mechanical stress) and triboelectric effects (charge generated by

friction). Charge imbalances generated by these mechanisms can

appear as parasitic leakage currents. These effects are modeled

by variable capacitor C_Pin Figure 26. The table in Figure 27

lists various insulators and their properties.¹

Figure 29. Noninverting Amplifier with Guard

Other guidelines include keeping the circuit layout as compact

as possible and input lines short. Keeping the assembly rigid

and minimizing sources of vibration will reduce triboelectric and

piezoelectric effects. All precision high impedance circuitry re-

quires shielding against interference noise. Low noise coax or

triax cables should be used for remote connections to the input

signal lines.

Volume

Minimal

Resistance

Resistivity Triboelectric Piezoelectric to Water

Material

(⍀–CM)

Effects

Absorption

Teflon*

Kel-F**

10¹⁷–10¹⁸

10¹⁶–10¹⁸

10¹⁴–10¹⁸

10¹²–10¹⁸

10¹²–10¹⁴

10¹⁰–10¹⁷

10¹⁰–10¹⁵

10⁵–10¹²

W

M

W

G

W

M

G

M

W

G

OFFSET NULLING

Sapphire

Polyethylene

Polystyrene

Ceramic

Glass Epoxy

PVC

The AD549’s input offset voltage can be nulled by usingbalance

Pins 1 and 5, as shown in Figure 30. Nulling the input offset

voltage in this fashion will introduce an added input offset volt-

age drift component of 2.4 µV/°C per millivolt of nulled offset

(a maximum additional drift of 0.6 µV/°C for the AD549K,

1.2 µV/°C for the AD549L, 2.4 µV/°C for the AD549J).

G

M

G

Phenolic

W

G–Good with Regard to Property

M–Moderate with Regard to Property

W–Weak with Regard to Property

Figure 27. Insulating Materials and Characteristics

Guarding the input lines by completely surrounding them with a

metal conductor biased near the input lines’ potential has two

major benefits. First, parasitic leakage from the signal line is

reduced since the voltage between the input line and the guard

is very low. Second, stray capacitance at the input node is mini-

Figure 30. Standard Offset Null Circuit

¹Electronic Measurements, pp. 15–17, Keithley Instruments, Inc., Cleveland,

Ohio, 1977.

*Teflon is a registered trademark of E.I. DuPont Co.

**Kel-F is a registered trademark of 3-M Company.

The approach in Figure 31 can be used when the amplifier is

used as an inverter. This method introduces a small voltage

referenced to the power supplies in series with the amplifier’s

REV. A

–7–

AD549

positive input terminal. The amplifier’s input offset voltage drift

with temperature is not affected. However, variation of the

power supply voltages will cause offset shifts.

In an inverting configuration, the differential input capacitance

forms a pole in the circuit’s loop transmission. This can create

peaking in the ac response and possible instability. A feedback

capacitance can be used to stabilize the circuit. The inverter

pulse response with R_Fand R_Sequal to 1 MΩ appears in Figure

34. Figure 35 shows the response of the same circuit with a I pF

feedback capacitance. Typical differential input capacitance for

the AD549 is 1 pF.

COMMON-MODE INPUT VOLTAGE OVERLOAD

The rated common-mode input voltage range of the AD549 is

from 3 V less than the positive supply voltage to 5 V greater

than the negative supply voltage. Exceeding this range will de-

grade the amplifier’s CMRR. Driving the common-mode voltage

above the positive supply will cause the amplifier’s output to

saturate at the upper limit of output voltage. Recovery time is

typically 2 µs after the input has been returned to within the nor-

mal operating range. Driving the input common-mode voltage

within 1 V of the negative supply causes phase reversal of the

output signal. In this case, normal operation is typically resumed

within 0.5 µs of the input voltage returning within range.

Figure 31. Alternate Offset Null Circuit for Inverter

AC RESPONSE WITH HIGH VALUE SOURCE AND

FEEDBACK RESISTANCE

Source and feedback resistances greater than 100 kΩ will mag-

nify the effect of input capacitances (stray and inherent to the

AD549) on the ac behavior of the circuit. The effects of

common-mode and differential input capacitances should be

taken into account since the circuit’s bandwidth and stability

can be adversely affected.

Figure 34. Inverter Pulse Response with 1 MΩ Source and

Feedback Resistance

Figure 32. Follower Pulse Response from 1 MΩ Source

Resistance, Case Not Bootstrapped

Figure 35. Inverter Pulse Response with 1 MΩ Source and

Feedback Resistance, 1 pF Feedback Capacitance

DIFFERENTIAL INPUT VOLTAGE OVERLOAD

A plot of the AD549’s input currents versus differential input

voltage (defined as V_IN+ –V_IN–) appears in Figure 36. The input

current at either terminal stays below a few hundred femtoamps

until one input terminal is forced higher than 1 V to 1.5 V above

the other terminal. Under these conditions, the input current

limits at 30 µA.

Figure 33. Follower Pulse Response from 1 MΩ Source

Resistance, Case Bootstrapped

In a follower, the source resistance and input common-mode

capacitance form a pole that limits the bandwidth to 1/2 π R_SC_S.

Bootstrapping the metal case by connecting Pin 8 to the output

minimizes capacitance due to the package. Figures 32 and 33

show the follower pulse response from a 1 MΩ source resistance

with and without the package connected to the output. Typical

common-mode input capacitance for the AD549 is 0.8 pF.

–8–

REV. A

AD549

100µ

10µ

1µ

I

–

IN

I

+

IN

100n

10n

1n

100p

Figure 39. Input Voltage Clamp with Diodes

10p

1p

SAMPLE AND DIFFERENCE CIRCUIT TO MEASURE

ELECTROMETER LEAKAGE CURRENTS

100f

10f

There are a number of methods used to test electrometer leak-

age currents, including current integration and direct current to

voltage conversion. Regardless of the method used, board and

interconnect cleanliness, proper choice of insulating materials

(such as Teflon or Kel-F), correct guarding and shielding tech-

niques and care in physi-cal layout are essential to making accu-

rate leakage measurements.

–5 –4 –3 –2 –1

0

1

2

3

4

5

–

)

DIFFERENTIAL INPUT VOLTAGE – V (V

– V

IN

Figure 36. Input Current vs. Differential Input Voltage

INPUT PROTECTION

The AD549 safely handles any input voltage within the supply

voltage range. Subjecting the input terminals to voltages beyond

the power supply can destroy the device or cause shifts in input

current or offset voltage if the amplifier is not protected.

Figure 40 is a schematic of the sample and difference circuit. It

uses two AD549 electrometer amplifiers (A and B) as current-to

voltage converters with high value (10¹⁰Ω) sense resistors (RSa

and RSb). R1 and R2 provide for an overall circuit sensitivity of

10 fA/mV (10 pA full scale). C_Cand C_Fprovide noise suppres-

sion and loop compensation. C_Cshould be a low leakage poly-

styrene capacitor. An ultralow leakage Kel-F test socket is used

for contacting the device under test. Rigid Teflon coaxial cable

is used to make connections to all high impedance nodes. The

A protection scheme for the amplifier as an inverter is shown in

Figure 37. R_Pis chosen to limit the current through the invert-

ing input to 1 mA for expected transient (less than 1 second)

overvoltage conditions, or to 100 µA for a continuous overload.

Since R_Pis inside the feedback loop, and is much lower in value

than the amplifier’s input resistance, it does not affect the

inverter’s dc gain. However, the Johnson noise of the resistor

will add root sum of squares to the amplifier’s input noise.

Figure 37. Inverter with Input Current Limit

In the corresponding version of this scheme for a follower,

shown in Figure 38, R_Pand the capacitance at the positive input

terminal will produce a pole in the signal frequency response at

a f = 1/2 π RC. Again, the Johnson noise R_Pwill add to the

amplifier’s input voltage noise.

Figure 38. Follower with Input Current Limit

Figure 39 is a schematic of the AD549 as an inverter with an

input voltage clamp. Bootstrapping the clamp diodes at the in-

verting input minimizes the voltage across the clamps and keeps

the leakage due to the diodes low. Low leakage diodes, such as

the FD333’s should be used, and should be shielded from light

to keep photocurrents from being generated. Even with these

precautions, the diodes will measurably increase the input cur-

rent and capacitance.

Figure 40. Sample and Difference Circuit for Measuring

Electrometer Leakage Currents

REV. A

–9–

AD549

use of rigid coax affords immunity to error induced by mechani-

cal vibration and provides an outer conductor for shielding. The

entire circuit is enclosed in a grounded metal box.

The test apparatus is calibrated without a device under test

present. A five minute stabilization period after the power is

turned on is required. First, V_ERR1and V_ERR2are measured.

These voltages are the errors caused by offset voltages and leak-

age currents of the current to voltage converters.

V_ERR1= 10 (V_OSA – I_BA × RSa)

V_ERR2= 10 (V_OSB – I_BB × RSb)

Figure 42. Photodiode Preamp

DC Error Sources

Once measured, these errors are subtracted from the readings

taken with a device under test present. Amplifier B closes the

feedback loop to the device under test, in addition to providing

current to voltage conversion. The offset error of the device un-

der test appears as a common-mode signal and does not affect

the test measurement. As a result, only the leakage current of

the device under test is measured.

Input current, I_B, will contribute an output voltage error, V_E1,

proportional to the feedback resistance:

V_E1= I_B× R_F

The op amp’s input voltage offset will cause an error current

through the photodiode’s shunt resistance, R_S:

I = V_OS/R_S

V_A– V_ERR1= 10[RSa × I_B(+)]

V_X– V_ERR2= 10[RSb × I_B(–)]

The error current will result in an error voltage (V_E2) at the

amplifier’s output equal to:

Although a series of devices can be tested after only one calibra-

tion measurement, calibration should be updated periodically to

compensate for any thermal drift of the current to voltage con-

verters or changes in the ambient environment. Laboratory re-

sults have shown that repeatable measurements within 10 fA can

be realized when this apparatus is properly implemented. These

results are achieved in part by the design of the circuit, which

eliminates relays and other parasitic leakage paths in the high

impedance signal lines, and in part by the inherent cancellation

of errors through the calibration and measurement procedure.

V_E2= ( I + R_F/R_S) V_OS

Given typical values of photodiode shunt resistance (on the

order of 10⁹Ω), R_F/R_Scan easily be greater than one, especially

if a large feedback resistance is used. Also, R_F/R_Swill increase

with temperature, as photodiode shunt resistance typically drops

by a factor of two for every 10°C rise in temperature. An op

amp with low offset voltage and low drift must be used in order to

maintain accuracy. The AD549K offers guaranteed maximum 0.25

mV offset voltage, and 5 mV/°C drift for very sensitive applications.

Photodiode Preamp Noise

PHOTODIODE INTERFACE

Noise limits the signal resolution obtainable with the preamp.

The output voltage noise divided by the feedback resistance is

the minimum current signal that can be detected. This mini-

mum detectable current divided by the responsivity of the pho-

todiode represents the lowest light power that can be detected

by the preamp.

The AD549’s low input current and low input offset voltage

make it an excellent choice for very sensitive photodiode

preamps (Figure 41). The photodiode develops a signal current,

I_Sequal to:

I_S= R × P

where P is light power incident on the diode’s surface in Watts

and R is the photodiode responsivity in Amps/Watt. R_Fconverts

the signal current to an output voltage:

Noise sources associated with the photodiode, amplifier, and

feedback resistance are shown in Figure 43; Figure 44 is the

spectral density versus frequency plot of each of the noise

source’s contribution to the output voltage noise (circuit param-

eters in Figure 42 are assumed). Each noise source’s rms contri-

bution to the total output voltage noise is obtained by integrating

the square of its spectral density function over frequency. The rms

value of the output voltage noise is the square root of the sum of all

contributions. Minimizing the total area under these curves will op-

timize the preamplifier’s resolution for a given bandwidth.

V

_OUT= R_F× I_S

The photodiode preamp in Figure 41 can detect a signal current

of 26 fA rms at a bandwidth of 16 Hz, which assuming a photo-

diode responsivity of 0.5 A/W, translates to a 52 fW rms mini-

mum detectable power. The photodiode used has a high source

resistance and low junction capacitance. C_Fsets the signal band-

width with R_Fand also limits the “peak” in the noise gain that

multiplies the op amp’s input voltage noise contribution. A

single pole filter at the amplifier’s output limits the op amp’s out-

put voltage noise bandwidth to 26 Hz, a frequency comparable to

the signal bandwidth. This greatly improves the preamplifier’s

signal to noise ratio (in this case, by a factor of three).

Figure 41. Photodiode Preamp

DC error sources and an equivalent circuit for a small area

(0.2 mm square) photodiode are indicated in Figure 42.

–10–

REV. A

AD549

tracter section’s gain for positive and negative inputs matched

over temperature.

Frequency compensation is provided by R11, R12, and C1 and

C2. The bandwidth of the circuit is 300 kHz at input signals

greater than 50 µA, and decreases smoothly with decreasing

signal levels.

To trim the circuit, set the input currents to 10 µA and trim

A3’s offset using the amplifier’s trim potentiometer so the out-

put equals 0. Then set I1 to 1 µA and adjust the output to equal

1 V by trimming R10. Additional offset trims on the amplifiers

A1 and A2 can be used to increase the voltage input accuracy

and dynamic range.

Figure 43. Photodiode Preamp Noise Sources

The very low input current of the AD549 makes this circuit use-

ful over a very wide range of signal currents. The total input

current (which determines the low level accuracy of the circuit)

is the sum of the amplifier input current, the leakage across the

compensating capacitor (negligible if polystyrene or Teflon ca-

pacitor is used), and the collector to collector, and collector to

base leakages of one side of the dual log transistors. The magni-

tude of these last two leakages depend on the amplifier’s input

offset voltage and are typically less than 10 fA with 1 mV offsets.

The low level accuracy is limited primarily by the amplifier’s in-

put current, only 60 fA maximum when the AD549L is used.

Figure 44. Photodiode Preamp Noise Sources’ Spectral

Density vs. Frequency

Log Ratio Amplifier

Logarithmic ratio circuits are useful for processing signals with

wide dynamic range. The AD549L’s 60 fA maximum input cur-

rent makes it possible to build a log ratio amplifier with 1% log

conformance for input current ranging from 10 pA to 1 mA, a

dynamic range of 160 dB.

The log ratio amplifier in Figure 45 provides an output voltage

proportional to the log base 10 of the ratio of the input currents

I1 and I2. Resistors R1 and R2 are provided for voltage inputs.

Since NPN devices are used in the feedback loop of the front-

end amplifiers that provide the log transfer function, the output

is valid only for positive input voltages and input currents. The

input currents set the collector currents IC1 and IC2 of a

matched pair of log transistors Q1 and Q2 to develop voltages

VA and VB:

VA, B = – (kT/q) ln IC/IES

where IES is the transistors’ saturation current.

The difference of VA and VB is taken by the subtractor section

to obtain:

Figure 45. Log Ratio Amplifier

VC = (kT/q) ln (IC2/IC1)

The effects of the emitter resistance of Q1 and Q2 can degrade

the circuit’s accuracy at input currents above 100 µA. The net-

works composed of R13, D1, R16, and R14, D2, R17 compen-

sate for these errors, so that this circuit has less than 1% log

conformance error at 1 mA input currents. The correct value

for R13 and R14 depends on the type of log transistors used.

49.9 kΩ resistors were chosen for use with LM394 transistors.

Smaller resistance values will be needed for smaller log

transistors.

VC is scaled up by the ratio of (R9 + R10)/R8, which is equal to

approximately 16 at room temperature, resulting in the output

voltage:

V

_OUT= 1 × log (IC2/IC1) V.

R8 is a resistor with a positive 3500 ppm/°C temperature coeffi-

cient to provide the necessary temperature compensation. The

parallel combination of R15 and R7 is provided to keep the sub

REV. A

–11–

AD549

TEMPERATURE COMPENSATED pH PROBE

AMPLIFIER

The pH probe output is ideally zero volts at a pH of 7 indepen-

dent of temperature. The slope of the probe’s transfer function,

though predictable, is temperature dependent (–54.2 mV/pH at

0 and –74.04 mV/pH at 100°C). By using an AD590 tempera-

ture sensor and an AD535 analog divider, an accurate tempera-

ture compensation network can be added to the basic pH probe

amplifier. The table in Figure 47 shows voltages at various points

and illustrates the compensation. The AD549 is set for a nonin-

verting gain of 13.51. The output of the AD590 circuitry (point

C) will be equal to 10 V at 100°C and decrease by 26.8 mV/°C.

The output of the AD535 analog divider (point D) will be a

temperature compensated output voltage centered at zero volts

for a pH of 7, and having a transfer function of –1.00 V/pH

unit. The output range spans from –7.00 V (pH = 14) to +7.00 V

(pH = 0).

A pH probe can be modeled as a mV-level voltage source with a

series source resistance dependent upon the electrode’s compo-

sition and configuration. The glass bulb resistance of a typical

pH electrode pair falls between 10⁶and 10⁹Ω. It is therefore

important to select an amplifier with low enough input currents

such that the voltage drop produced by the amplifier’s input

bias current and the electrode resistance does not become an

appreciable percentage of a pH unit.

The circuit in Figure 46 illustrates the use of the AD549 as a

pH probe amplifier. As with other electrometer applications, the

use of guarding, shielding, Teflon standoffs, etc., is a must in

order to capitalize on the AD549’s low input current. If an

AD549L (60 fA max input current) is used, the error contrib-

uted by input current will be held below 60 µV for pH electrode

source impedances up to 10⁹Ω. Input offset voltage (which can

be trimmed) will be below 0.5 mV.

PROBE

A

B

C

D

TEMP

(PROBE OUTPUT)

(A

؋

13.51) (590 OUTPUT)

(10 B/C)

0

54.20 mV

59.16 mV

61.54 mV

66.10 mV

0.732 V

0.799 V

0.831 V

0.893 V

7.32 V

7.99 V

8.31 V

8.93 V

1.00 V

25؇C

37؇C

60؇C

100؇C

74.04 mV

1.000 V

10.00 V

1.00 V

Figure 47. Table Illustrating Temperature Compensation

Figure 46. Temperature Compensated pH Probe Amplifier

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

TO-99 (H) Package

0.370 (9.40)

0.335 (8.50)

0.2

(5.1)

TYP

0.335 (8.50)

0.305 (7.75)

0.040

(1.0)

MAX

3

45° EQUALLY

SPACED

0.185 (4.70)

0.165 (4.19)

2

8

4

6

1

5

REFFERENCE

PLANE

SEATING

PLANE

7

INSULATION

0.05 (1.27) MAX

0.500

(12.70)

MIN

0.034 (0.86)

0.028 (0.41)

0.045 (1.1)

8 LEADS

0.019 (0.48)

0.016 (0.41)

0.020 (0.51)

DIA

BOTTOM VIEW

–12–

REV. A


型号：	05F6971
厂家：	ETC
描述：	IC-ELECTROMETER AMPLIFIER IC-静电计放大器\n 放大器
文件：	总12页 (文件大小：420K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

05F6971 [ETC]

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