ad743jnz Analog Devices, Inc., ad743jnz Datasheet - Page 7

ad743jnz

Manufacturer Part Number

ad743jnz

Description

Ultralow Noise Bifet Op Amp

Manufacturer

Analog Devices, Inc.

Datasheet

1.AD743JNZ.pdf (12 pages)

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OP AMP PERFORMANCE: JFET VS. BIPOLAR

The AD743 is the first monolithic JFET op amp to offer the low

input voltage noise of an industry-standard bipolar op amp without

its inherent input current errors. This is demonstrated in Figure 2,

which compares input voltage noise versus input source resis-

tance of the OP27 and AD743 op amps. From this figure, it is

clear that at high source impedance the low current noise of the

AD743 also provides lower total noise. It is also important to

note that with the AD743 this noise reduction extends all the

way down to low source impedances. The lower dc current errors

of the AD743 also reduce errors due to offset and drift at high

source impedances (Figure 3).

DESIGNING CIRCUITS FOR LOW NOISE

An op amp’s input voltage noise performance is typically divided

into two regions: flatband and low frequency noise. The AD743

offers excellent performance with respect to both. The figure of

2.9 nV/√Hz @ 10 kHz is excellent for a JFET input amplifier. The

0.1 Hz to 10 Hz noise is typically 0.38 µV p-p. The user should

pay careful attention to several design details in order to optimize

REV. E

Figure 2. Total Input Noise Spectral Density @ 1 kHz

vs. Source Resistance

Figure 3. Input Offset Voltage vs. Source Resistance

100

0.1

1000

100

AD743 AND RESISTOR

OP27 AND RESISTOR

SOURCE

RESISTOR NOISE ONLY

SOURCE RESISTANCE ( )

10k

(– – –)

10k

OP27 AND

RESISTOR

100k

( — )

AD743 AND

RESISTOR

(

OP27

)

AD743

10M

–7–

low frequency noise performance. Random air currents can gen-

erate varying thermocouple voltages that appear as low frequency

noise; therefore, sensitive circuitry should be well shielded from

air flow. Keeping absolute chip temperature low also reduces low

frequency noise in two ways. First, the low frequency noise is

strongly dependent on the ambient temperature and increases

above +25°C. Second, since the gradient of temperature from the

IC package to ambient is greater, the noise generated by random

air currents, as previously mentioned, will be larger in magnitude.

Chip temperature can be reduced both by operation at reduced

supply voltages and by the use of a suitable clip-on heat sink,

if possible.

Low frequency current noise can be computed from the magni-

tude of the dc bias current

and increases below approximately 100 Hz with a 1/f power spectral

density. For the AD743, the typical value of current noise is

6.9 fA/√Hz at 1 kHz. Using the formula

to compute the Johnson noise of a resistor, expressed as a current,

one can see that the current noise of the AD743 is equivalent to

that of a 3.45

At high frequencies, the current noise of a FET increases pro-

portionately to frequency. This noise is due to the “real” part of

the gate input impedance, which decreases with frequency. This

noise component usually is not important, since the voltage noise

of the amplifier impressed upon its input capacitance is an appar-

ent current noise of approximately the same magnitude.

In any FET input amplifier, the current noise of the internal

bias circuitry can be coupled externally via the gate-to-source

capacitances and appears as input current noise. This noise is

totally correlated at the inputs, so source impedance match-

ing will tend to cancel out its effect. Both input resistance and

input capacitance should be balanced whenever dealing with

source capacitances of less than 300 pF in value.

LOW NOISE CHARGE AMPLIFIERS

As stated, the AD743 provides both low voltage and low current

noise. This combination makes this device particularly suitable

in applications requiring very high charge sensitivity, such as

capacitive accelerometers and hydrophones. When dealing with

a high source capacitance, it is useful to consider the total input

charge uncertainty as a measure of system noise.

Charge (Q) is related to voltage and current by the simply stated

fundamental relationships

As shown, voltage, current, and charge noise can all be directly

related. The change in open circuit voltage (∆V) on a capacitor

will equal the combination of the change in charge (∆Q/C) and

the change in capacitance with a built in charge (Q/∆C).

Ω source resistance.

Q CV

˜ I

= 4

= 2

and

kT R f

∆

AD743

ad743jnz Analog Devices, Inc., ad743jnz Datasheet - Page 7

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