OP471_15 Datasheet, PDF(10/16 Page) Analog Devices – High Speed, Low Noise Quad Operational Amplifier

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OP471_15 Datasheet, PDF (10/16 Pages) Analog Devices – High Speed, Low Noise Quad Operational Amplifier

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OP471

Noise Measurement - Current Noise Density

The test circuit shown in Figure 10 can be used to measure current

noise density. The formula relating the voltage output to current

noise density is:

in =

( ÃÃÃ

e nOUT

ËÂ¯Ë

40nV /

where:

G = gain of 10,000

RS = 100 kW source resistance

Capacative Load Driving and Power Supply Considerations

The OP471 is unity-gain stable and is capable of driving large

capacitive loads without oscillating. Nonetheless, good supply

bypassing is highly recommended. Proper supply bypassing

reduces problems caused by supply line noise and improves the

capacitive load driving capability of the OP471.

1.24kâ

5â

100kâ

OP471

DUT

OP27E

8.06kâ

en OUT TO

SPECTRUM ANALYZER

200â

GAIN = 10,000

VS = Ø15V

Figure 10. Current Noise Density Test Circuit

V+

10â®F

0.1â®F

VIN

100â*

200pF

50â

OP471

10â®F

0.1â®F

VOUT

1000pF

*SEE TEXT

Vâ

PLACE SUPPLY DECOUPLING

CAPACITORS AT OP471

Figure 11. Driving Large Capacitive Loads

In the standard feedback amplifier, the op ampâs output resistance

combines with the load capacitance to form a lowpass filter that

adds phase shift in the feedback network and reduces stability. A

simple circuit to eliminate this effect is shown in Figure 11. The

added components, C1 and R3, decouple the amplifier from the

load capacitance and provide additional stability. The values of

C1 and R3 shown in Figure 11 are for load capacitances of up

to 1,000 pF when used with the OP471.

In applications where the OP471âs inverting or noninverting inputs

are driven by a low source impedance (under 100 W) or connected

to ground, if V+ is applied before Vâ, or when Vâ is disconnected,

excessive parasitic currents will flow.

Most applications use dual tracking supplies and with the device

supply pins properly bypassed, power-up will not present a

problem. A source resistance of at least 100 W in series with all

inputs (Figure 11) will limit the parasitic currents to a safe level

if Vâ is disconnected. It should be noted that any source resistance,

even 100 W, adds noise to the circuit. Where noise is required to

be kept at a minimum, a germanium or Schottky diode can be

used to clamp the Vâ pin and eliminate the parasitic current

flow instead of using series limiting resistors. For most applica-

tions, only one diode clamp is required per board or system.

OP471

8V/â®s

Figure 12. Pulsed Operation

Unity-Gain Buffer Applications

When Rf Â£ 100 W and the input is driven with a fast, large signal

pulse (>1 V), the output waveform will look as shown in Figure 12.

During the fast feedthrough-like portion of the output, the input

protection diodes effectively short the output to the input, and a

current, limited only by the output short-circuit protection, will

be drawn by the signal generator. With Rf â¥ 500 W, the output

is capable of handling the current requirements (IL Â£ 20 mA at

10 V); the amplifier will stay in its active mode and a smooth

transition will occur.

When Rf > 3 kW, a pole created by Rf and the amplifierâs input

capacitance (2.6 pF) creates additional phase shift and reduces

phase margin. A small capacitor (20 pF to 50 pF) in parallel with

Rf helps eliminate this problem.

APPLICATIONS

Low Noise Amplifier

A simple method of reducing amplifier noise by paralleling

amplifiers is shown in Figure 13. Amplifier noise, depicted in

Figure 14, is around 5 nV/Ã·Hz @ 1 kHz (R.T.I.). Gain for each

paralleled amplifier and the entire circuit is 100. The 200 W

resistors limit circulating currents and provide an effective output

resistance of 50 W. The amplifier is stable with a 10 nF capacitive

load and can supply up to 30 mA of output drive.

â10â

REV. A

▷