AD AD542SH

a
FEATURES
Ultralow Drift: 1 mV/8C (AD547L)
Low Offset Voltage: 0.25 mV (AD547L)
Low Input Bias Currents: 25 pA max
Low Quiescent Current: 1.5 mA
Low Noise: 2 mV p-p
High Open Loop Gain: 110 dB
High Slew Rate: 13 V/ms
Fast Settling to 60.01%: 3 ms
Low Total Harmonic Distortion: 0.0025%
Available in Hermetic Metal Can and Die Form
MIL-STD-883B Versions Available
Dual Versions Available: AD642, AD644, AD647
High Performance,
BiFET Operational Amplifiers
AD542/AD544/AD547
CONNECTION DIAGRAM
TAB
8
NULL
INVERTING
INPUT
1
2
NONINVERTING
INPUT
+V
7
6
3
5
OUTPUT
NULL
4
–V
NOTE: PIN 4 CONNECTED TO CASE
PRODUCT DESCRIPTION
PRODUCT HIGHLIGHTS
The BiFET series of precision, monolithic FET-input op amps
are fabricated with the most advanced BiFET and laser trimming technologies. The AD542, AD544, AD547 series offers
bias currents significantly lower than currently available BiFET
devices, 25 pA max, warmed up.
1. Improved bipolar and JFET processing results in the lowest
bias current available in a monolithic FET op amp.
In addition, the offset voltage is laser trimmed to less than
0.25 mV on the AD547L, which is achieved by utilizing Analog
Devices’ exclusive laser wafer trimming (LWT) process. When
combined with the AD547’s low offset drift (1 µV/°C), these
features offer the user performance superior to existing BiFET
op amps at low BiFET pricing.
The AD542 or AD547 is recommended for any operational amplifier application requiring excellent dc performance at low to
moderate cost. Precision instrument front ends requiring accurate amplification of millivolt level signals from megohm source
impedances will benefit from the device’s excellent combination
of low offset voltage and drift, low bias current and low 1/f
noise. High common-mode rejection (80 dB, min on the “K”
and “L” grades) and high open-loop gain, even under heavy
loading, ensures better than “12-bit” linearity in high impedance buffer applications.
2. Analog Devices, unlike some manufacturers, specifies each
device for the maximum bias current at either input in the
warmed-up condition, thus assuring the user that the device
will meet its published specifications in actual use.
3. Advanced laser wafer trimming techniques reduce offset voltage drift to 1 µV/°C max and offset voltage to only 0.25 mV
max on the AD547L.
4. Low voltage noise (2 µV p-p) and low offset voltage drift enhance performance as a precision op amp.
5. High slew rate (13 V/µs) and fast settling time to 0.01% (3 µs)
make the AD544 ideal for D/A, A/D, sample-hold circuits
and high speed integrators.
6. Low harmonic distortion (0.0025%) make the AD544 an
ideal choice in audio applications.
7. Bare die are available for use in hybrid circuit applications.
The AD544 is recommended for any op amp applications requiring excellent ac and dc performance at low cost. The
2 MHz bandwidth and low offset of the AD544 make it the first
choice as an output amplifier for current output D/A converters,
such as the AD7541, 12-bit CMOS DAC.
Devices in this series are available in four grades: the “J,” “K,”
and “L” grades are specified over the 0°C to +70°C temperature
range and the “S” grade over the –55°C to +125°C operating
temperature range. All devices are offered in the hermetically
sealed, TO-99 metal can package.
REV. B
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
AD542/AD544/AD547–SPECIFICATIONS ( V = 615 V @ T = +258C unless otherwise noted)
S
Parameter
Min
AD542
Typ
Max
Min
AD544
Typ
A
Max
Min
AD547
Typ
Max
Units
1
OPEN-LOOP GAIN
VOUT = ± 10 V, RL = 2 kΩ
J Grade
K, L, S Grades
TA = TMIN to TMAX
J Grade
S Grade
K, L Grades
OUTPUT CHARACTERISTICS
RL = 2 kΩ
TA = TMIN to TMAX
RL = 10 kΩ
TA = TMIN to TMAX
Short Circuit Current
FREQUENCY RESPONSE
Unity Gain, Small Signal
Full Power Response
Slew Rate, Unity Gain
Total Harmonic Distortion
100
250
30
50
100
250
V/mV
V/mV
100
100
250
20
20
40
100
100
250
V/mV
V/mV
V/mV
± 10
± 12
± 10
± 12
± 10
± 12
V
± 12
± 13
25
± 12
± 13
25
± 12
± 13
25
V
mA
1.0
50
3.0
MHz
kHz
V/µs
%
2.0
1.0
50
3.0
INPUT OFFSET VOLTAGE2
J Grade
K Grade
L Grade
S Grade
vs. Temperature3
J Grade
K Grade
L Grade
S Grade
vs. Supply, TA = TMIN to TMAX
J Grade
K, L, S Grades
8.0
2.0
200
13.0
0.0025
2.0
2.0
1.0
0.5
1.0
2.0
1.0
0.5
1.0
1.0
0.5
0.25
0.5
mV
mV
mV
mV
20
10
5
15
20
10
5
15
5
2
1
5
µV/°C
µV/°C
µV/°C
µV/°C
200
100
200
100
200
100
µV/V
µV/V
INPUT BIAS CURRENT4
Either Input
J Grade
K, L, S Grades
Input Offset Current
J Grade
K, L, S Grades
10
50
25
10
50
25
10
50
25
pA
pA
5
2
15
15
5
2
15
15
5
2
15
15
pA
pA
INPUT IMPEDANCE
Differential
Common Mode
1012i6
1012i3
INPUT VOLTAGE5
Differential
Common Mode
Common-Mode Rejection
VIN = ± 10 V
J Grade
K, L, S Grades
± 10
76
80
± 20
± 12
1012i6
1012i3
± 10
76
80
–2–
± 20
± 12
± 10
76
80
1012i6
1012i3
ΩipF
ΩipF
± 20
± 12
V
V
dB
dB
REV. B
AD542/AD544/AD547
Parameter
Min
POWER SUPPLY
Rated Performance
Operating
Quiescent Current
±5
AD542
Typ
Max
± 15
± 18
1.1
VOLTAGE NOISE
0.1 Hz to 10 Hz
J Grade
K, L, S Grades
10 Hz
100 Hz
1 kHz
10 kHz
Min
±5
TRANSISTOR COUNT
± 18
AD547
Typ
Max
Min
± 15
±5
1.1
2.5
2.0
2.0
35
22
18
16
0 to +70
–55 to +125
–65 to +150
29
± 15
1.8
1.5
2.0
2.0
70
45
30
25
TEMPERATURE RANGE
Operating, Rated Performance
J, K, L Grades
S Grade
Storage
AD544
Typ
Max
1.5
2.0
4.0
70
45
30
25
0 to +70
–55 to +125
–65 to +150
29
± 18
0 to +70
–55 to +125
–65 to +150
Units
V
V
mA
µV p-p
µV p-p
nV/√Hz
nV/√Hz
nV/√Hz
nV/√Hz
°C
°C
°C
29
NOTES
1
Open-Loop Gain is specified with V OS both nulled and unnulled.
2
Input Offset Voltage specifications are guaranteed after 5 minutes of operation at T A = +25°C.
3
Input Offset Voltage Drift is specified with the offset voltage unnulled. Nulling will induce an additional 3 µV/°C/mV of nulled offset.
4
Bias Current specifications are guaranteed at either input after 5 minutes of operation at T A = +25°C. For higher temperatures, the current doubles every 10°C.
5
Defined as the maximum safe voltage between inputs, such that neither exceeds ± 10 V from ground.
Specifications subject to change without notice.
Specifications shown in boldface are tested on all production units at final electrical test. Results from those tests are used to calculate outgoing quality levels.
All min and max specifications are guaranteed, although only those shown in boldface are tested on all production units.
ORDERING GUIDE
Model
Initial
Offset
Voltage
Offset
Voltage
Drift
Settling Time
to 60.012% for
a 10 V Step
Package
Description
AD542JCHIPS
AD542JH
AD542KH
AD542LH
AD542SH
AD542SH/883B
AD544JH
AD544KH
AD544LH
AD544SH
AD544SH/883B
AD547JH
AD547KH
AD547LH
AD547SCHIPS
AD547SH/883B
2.0 mV
2.0 mV
1.0 mV
0.5 mV
1.0 mV
1.0 mV
2.0 mV
1.0 mV
0.5 mV
1.0 mV
1.0 mV
1.0 mV
0.5 mV
0.25 mV
0.5 mV
0.5 mV
20 µV/°C
20 µV/°C
10 µV/°C
5 µV/°C
15 µV/°C
15 µV/°C
20 µV/°C
10 µV/°C
5 µV/°C
15 µV/°C
15 µV/°C
5 µV/°C
2 µV/°C
1 µV/°C
5 µV/°C
5 µV/°C
5 µs
5 µs
5 µs
5 µs
5 µs
5 µs
3 µs
3 µs
3 µs
3 µs
3 µs
5 µs
5 µs
5 µs
5 µs
5 µs
Bare Die
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
8-Pin Hermetic Metal Can
Bare Die
8-Pin Hermetic Metal Can
REV. B
–3–
Package
Option
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
H-08A
AD542/AD544/AD547–Typical Characteristics
Figure 1. Input Voltage Range vs.
Supply Voltage
Figure 4. Input Bias Current vs.
Supply Voltage
Figure 7. Change in Offset Voltage
vs. Warm-Up Time
Figure 2. Output Voltage Swing vs.
Supply Voltage
Figure 5. Input Bias Current vs.
Temperature
Figure 8. Open Loop Gain vs.
Temperature
–4–
Figure 3. Output Voltage Swing vs.
Load Resistance
Figure 6. Input Bias Current vs.
CMV
Figure 9. Open Loop Frequency
Response
REV. B
AD542/AD544/AD547
Figure 10. Open Loop Voltage
Gain vs. Supply Voltage
Figure 13. Quiescent Current vs.
Supply Voltage
Figure 16. AD544 Total Harmonic
Distortion vs. Frequency
REV. B
Figure 11. Power Supply Rejection
vs. Frequency
Figure 14. Large Signal Frequency
Response
Figure 17. Input Noise Voltage
Spectral Density
–5–
Figure 12. Common-Mode Rejection
Ratio vs. Frequency
Figure 15. AD544 Output Swing and
Error vs. Settling Time
Figure 18. Total RMS Noise vs.
Source Resistance
AD542/AD544/AD547
a. Unity Gain Follower
b. Follower with Gain = 10
Figure 20. Standard Null Circuit
Figure 19. THD Test Circuits
Figure 21a. Unity Gain Follower
Pulse Response (Large Signal)
Figure 21b. Unity Gain Follower
Pulse Response (Small Signal)
Figure 21c. Unity Gain Follower–
AD542/AD547
Figure 22a. Unity Gain Inverter
AD542/AD547
Figure 22b. Unity Gain Inverter
Pulse Response (Large Signal)
Figure 22c. Unity Gain Inverter
Pulse Response (Small Signal)
–6–
REV. B
AD542/AD544/AD547
Figure 23a. Unity Gain Follower
Pulse Response (Large Signal)
Figure 23b. Unity Gain Follower
Pulse Response (Small Signal)
Figure 23c. Unity Gain Follower
Figure 24a. Unity Gain Inverter
Figure 24b. Unity Gain Inverter
Pulse Response (Large Signal)
Figure 24c. Unity Gain Inverter
Pulse Response (Small Signal)
Figure 25. Settling Time Test Circuit
Figure 27. Circuit for Driving a Large Capacitance Load
The upper trace of the oscilloscope photograph of Figure 26
shows the settling characteristic of the AD544. The lower trace
represents the input to Figure 27. The AD544 has been designed
for fast settling to 0.01%, however, feedback components, circuit layout and circuit design must be carefully considered to
obtain optimum settling time.
The circuit in Figure 27 employs a 100 Ω isolation resistor
which enables the amplifier to drive capacitance loads exceeding
500 pF; the resistor effectively isolates the high frequency feedback from the load and stabilizes the circuit. Low frequency
feedback is returned to the amplifier summing junction via the
low-pass filter formed by the 100 Ω series resistor and the load
capacitance, CL.
Figure 28. Transient Response RL = 2 kΩ
CL = 500 pF–AD544
Figure 26. Settling Characteristic Detail–AD544
REV. B
–7–
AD542/AD544/AD547
BiFET Application Hints
APPLICATION NOTES
The BiFET series was designed for high performance op amp
applications that require true dc precision. To capitalize on all
of the performance available from the BiFETs there are some
practical error sources that should be considered.
The bias currents of JFET input amplifiers double with every
10°C increase in chip temperature. Therefore, minimizing the
junction temperature of the chip will result in extending the
performance limits of the device.
1. Heat dissipation due to power consumption is the main
contributor to self-heating and can be minimized by reducing
the power supplies to the lowest level allowed by the
application.
current-to-voltage converting amplifier. This possibility necessitates some form of input protection. Many electrometer type
devices, especially CMOS designs, can require elaborate Zener
protection schemes which often compromise overall performance. The BiFET series requires input protection only if the
source is not current-limited, and as such is similar to many
JFET-input designs. The failure mode would be overheating
from excess current rather than voltage breakdown. If the
source is not current-limited, all that is required is a resistor in
series with the affected input terminal so that the maximum
overload current is 1.0 mA (for example, 100 kΩ for a 100 volt
overload). This simple scheme will cause no significant reduction in performance and give complete overload protection. Figure 30 shows proper connections.
2. The effects of output loading should be carefully considered.
Greater power dissipation increases bias currents and decreases open loop gain.
GUARDING
The low input bias current (25 pA) and low noise characteristics
of the high performance BiFET op amp make it suitable for
electrometer applications such as photo diode preamplifiers and
picoampere current-to-voltage converters. The use of guarding
techniques in printed circuit board layout and construction is
critical for achieving the ultimate in low leakage performance
available from these amplifiers. The input guarding scheme
shown in Figure 29 will minimize leakage as much as possible;
the guard ring is connected to a low impedance potential at the
same level as the inputs. High impedance signal lines should not
be extended for any unnecessary length on a printed circuit.
Figure 29. Board Layout for Guarding Inputs
Figure 30. Input Protection
D/A CONVERTER APPLICATIONS
The BiFET series of operational amplifiers can be used with
CMOS DACs to perform both 2-quadrant and 4-quadrant
operation. The output impedance of a CMOS DAC varies with
the digital word, thus changing the noise gain of the amplifier
circuit. The effect will cause a nonlinearity the magnitude of
which is dependent on the offset voltage of the amplifier. The
BiFET series with trimmed offset will minimize this effect. Additionally, the Schottky protection diodes recommended for use
with many older CMOS DACs are not required when using one
of the BiFET series amplifiers.
Figure 31a shows the AD547 and AD7541 configured for unipolar binary (2-quadrant multiplication) operation. With a dc
reference voltage or current (positive or negative polarity) applied at pin 17, the circuit operates as a unipolar converter.
With an ac reference voltage or current, the circuit provides
2-quadrant multiplication (digitally controlled attenuation).
INPUT PROTECTION
The BiFET series is guaranteed for a maximum safe input
potential equal to the power supply potential. The input stage
design also allows differential input voltages of up to ± 1 volt
while maintaining the full differential input resistance of 1012 Ω.
This makes the BiFET series suitable for comparator situations
employing a direct connection to high impedance source.
Many instrumentation situations, such as flame detectors in gas
chromatographs, involve measurement of low level currents
from high-voltage sources. In such applications, a sensor fault
condition may apply a very high potential to the input of the
Figure 31a. AD547 Used as DAC Output Amplifier
–8–
REV. B
AD542/AD544/AD547
The oscilloscope photo of Figure 31b shows the output of the
circuit of Figure 31a. The upper trace represents the reference
input, and the bottom trace shows the output voltage for a
digital input of all ones on the DAC (Gain 1–2–n). The 47 pF
capacitor across the feedback resistor compensates for the DAC
output capacitance, and the 150 pF load capacitor serves to
minimize output glitches.
USING THE AD547 IN LOG AMPLIFIER APPLICATIONS
Log amplifiers or log ratio amplifiers are useful in applications
requiring compression of wide-range analog input data, linearization of transducers having exponential outputs, and analog
computing, ranging from simple translation of natural relationships in log form (e.g., computing absorbance as the log-ratio of
input currents), to the use of logarithms in facilitating analog
computation of terms involving arbitrary exponents and
multi-term products and ratios.
The picoamp level input current and low offset voltage of the
AD547 make it suitable for wide dynamic range log amplifiers.
Figure 33 is a schematic of a log ratio circuit employing the
AD547 that can achieve less than 1% conformance error over 5
decades of current input, 1 nA to 100 µA. For voltage inputs,
the dynamic range is typically 50 mV to 10 V for 1% error,
limited on the low end by the amplifiers’ input offset voltage.
Figure 31b. Voltage Output DAC Settling Characteristic
Figure 32a illustrates the 10-bit digital-to-analog converter,
AD7533, connected for bipolar operation. Since the digital
input can accept bipolar numbers and VREF can accept a bipolar
analog input, the circuit can perform a 4-quadrant multiplying
function.
Figure 33. Log-Ratio Amplifier
Figure 32a. AD544 Used as DAC Output Amplifiers
The photos exhibit the response to a step input at VREF. Figure
32b is the large signal response and Figure 32c is the small signal response. C1 phase compensation (15 pF) is required for
stability when using high speed amplifiers. C1 is used to cancel
the pole formed by the DAC internal feedback resistance and
the output capacitance of the DAC.
The conversion between current (or voltage) input and log output is accomplished by the base emitter junctions of the dual
transistor Q1. Assuming Q1 has β > 100, which is the case for
the specified transistor, the base-emitter voltage on side 1 is to a
close approximation:
V BE
A
= kT/q ln I1/I S1
This circuit is arranged to take the difference of the VBE’s of
Q1A and Q1B, thus producing an output voltage proportional
to the log of the ratio of the inputs:
VOUT = – K (VBE A – V BE B) = –
KkT
(ln I1 /I S1 – ln I 2 /I S2 )
q
V OUT = −K kT /q ln I1 / I 2
Figure 32b. Large Signal
Response
REV. B
Figure 32c. Small Signal
Response
The scaling constant, K is set by R1 and RTC to about 16, to
produce 1 V change in output voltage per decade difference in
input signals. RTC is a special resistor with a +3500 ppm/°C
temperature coefficient, which makes K inversely proportional
to temperature, compensating for the “T” in kT/q. The logratio transfer characteristic is therefore independent of
temperature.
–9–
AD542/AD544/AD547
This particular log ratio circuit is free from the dynamic problems that plague many other log circuits. The –3 dB bandwidth
is 50 kHz over the top 3 decades, 100 nA to 100 µA, and decreases smoothly at lower input levels. This circuit needs no additional frequency compensation for stable operation from
input current sources, such as photodiodes, that may have 100
pF of shunt capacitance. For larger input capacitances a 20 pF
integration capacitor around each amplifier will provide a
smoother frequency response.
Figure 34. Differentiator
Figure 37. Capacitance
Multiplier
This log ratio amplifier can be readily adjusted for optimum
accuracy by following this simple procedure. First, apply V1 =
V2 = –10.00 V and adjust “Balance” for VOUT = 0.00 V. Next
apply V1 = –10.00 V, V2 = –1.00 V and adjust gain for VOUT =
+1.00 V. Repeat this procedure until gain and balance readings
are within 2 mV of ideal values.
Figure 35. Low Drift Integrator and
Low Leakage Guarded Reset
Figure 38. Long Interval
Timer–1,000 Seconds
–10–
Figure 36. Wien-Bridge
Oscillator–fO = 10 kHz
Figure 39. Positive Peak Detector
REV. B
AD542/AD544/AD547
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
TO-99 (H-08A)
REV. B
–11–
–12–
PRINTED IN U.S.A.
C826c–2–11/91