AD549 Analog Devices, AD549 Datasheet - Page 10

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AD549

Manufacturer Part Number
AD549
Description
Ultralow Input-Bias Current Operational Amplifier
Manufacturer
Analog Devices
Datasheet

Specifications of AD549

-3db Bandwidth
1MHz
Slew Rate
3V/µs
Vos
500µV
Ib
150fA
# Opamps Per Pkg
1
Input Noise (nv/rthz)
35nV/rtHz
Vcc-vee
10V to 36V
Isy Per Amplifier
700µA
Packages
TO-X

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AD549
FUNCTIONAL DESCRIPTION
MINIMIZING INPUT CURRENT
The AD549 is optimized for low input current and offset
voltage. Careful attention to how the amplifier is used reduces
input currents in actual applications.
Keep the amplifier operating temperature as low as possible to
minimize input current. Like other JFET input amplifiers, the
AD549 input current is sensitive to chip temperature, rising by
a factor of 2.3 for every 10°C. Figure 25 is a plot of the AD549
input current vs. ambient temperature.
On-chip power dissipation raises the chip operating tempera-
ture, causing an increase in input bias current. Due to the low
quiescent supply current of the AD549, the chip temperature
is less than 3°C higher than its ambient temperature when the
(unloaded) amplifier is operating with 15 V supplies. The
difference in the input current is negligible.
However, heavy output loads can cause a significant increase in
chip temperature and a corresponding increase in the input
current. Maintaining a minimum load resistance of 10 Ω is
recommended. Input current vs. additional power dissipation
due to output drive current is plotted in Figure 26.
100pA
100fA
10pA
Figure 26. Input Bias Current vs. Additional Power Dissipation
10fA
1nA
1pA
1fA
6
5
4
3
2
1
Figure 25. Input Bias Current vs. Ambient Temperature
–55
0
ADDITIONAL INTERNAL POWER DISSIPATION (mW)
25
–25
50
5
TEMPERATURE (°C)
75
BASED ON
TYPICAL I
100
35
B
125
= 40fA
65
150
95
175
200
125
Rev. H | Page 10 of 20
CIRCUIT BOARD NOTES
A number of physical phenomena generate spurious currents
that degrade the accuracy of low current measurements. Figure 27
is a schematic of a current to voltage (I-to-V) converter with
these parasitic currents modeled.
Finite resistance from input lines to voltages on the board,
modeled by Resistor R
resistance of more than 10
the amplifier signal and supply lines to capitalize on the low
input currents of the AD549. Standard PCB material does not
have high enough insulation resistance; therefore, connect the
input leads of the AD549 to standoffs made of insulating
material with adequate volume resistivity (that is, Teflon®). The
surface of the insulator must be kept clean to preserve surface
resistivity. For Teflon, an effective 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.
In addition to high volume and surface resistivity, other proper-
ties are desirable in the insulating material chosen. Resistance
to water absorption is important because surface water films
drastically 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
Table 3 lists various insulators and their properties.
Guarding the input lines by completely surrounding them with
a metal conductor biased near the potential of the input lines
has two major benefits. First, parasitic leakage from the signal
line is reduced because the voltage between the input line and
the guard is very low. Second, stray capacitance at the input
node is minimized. Input capacitance can substantially degrade
signal bandwidth and the stability of the I-to-V converter.
1
Electronic Measurements, pp. 15–17, Keithley Instruments, Inc., Cleveland,
Ohio, 1977.
Figure 27. Sources of Parasitic Leakage Currents
V
R
S
P
f
S
P
, results in parasitic leakage. Insulation
C
15
P
Ω must be maintained between
2
3
I
I'
AD549
=
R
V
P
+
8
dC
dT
C
R
P
F
F
V +
6
dV
dT
C
P
V
P
OUT
in Figure 27.
+
1

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