OPA1662 Datasheet, PDF(14/29 Page) Texas Instruments – Low-Power, Low Noise and Distortion, Bipolar-Input AUDIO OPERATIONAL AMPLIFIERS

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OPA1662 Datasheet, PDF (14/29 Pages) Texas Instruments – Low-Power, Low Noise and Distortion, Bipolar-Input AUDIO OPERATIONAL AMPLIFIERS

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OPA1662

OPA1664

SBOS489 â DECEMBER 2011

INPUT PROTECTION

The input terminals of the OPA1662 and OPA1664

are protected from excessive differential voltage with

back-to-back diodes, as Figure 44 illustrates. In most

circuit applications, the input protection circuitry has

no consequence. However, in low-gain or G = +1

circuits, fast ramping input signals can forward bias

these diodes because the output of the amplifier

cannot respond rapidly enough to the input ramp. If

the input signal is fast enough to create this forward

bias condition, the input signal current must be limited

to 10 mA or less. If the input signal current is not

inherently limited, an input series resistor (RI) and/or

a feedback resistor (RF) can be used to limit the

signal input current. This resistor degrades the

low-noise performance of the OPA166x and is

examined in the following Noise Performance section.

Figure 44 shows an example configuration when both

current-limiting input and feeback resistors are used.

Input

OPA166x

Output

Figure 44. Pulsed Operation

NOISE PERFORMANCE

Figure 45 shows the total circuit noise for varying

source impedances with the op amp in a unity-gain

configuration (no feedback resistor network, and

therefore no additional noise contributions).

The OPA166x (GBW = 22 MHz, G = +1) is shown

with total circuit noise calculated. The op amp itself

contributes both a voltage noise component and a

current noise component. The voltage noise is

commonly modeled as a time-varying component of

the offset voltage. The current noise is modeled as

the time-varying component of the input bias current

and reacts with the source resistance to create a

voltage component of noise. Therefore, the lowest

noise op amp for a given application depends on the

source impedance. For low source impedance,

current noise is negligible, and voltage noise

generally dominates. The low voltage noise of the

OPA166x series op amps makes them a better

choice for low source impedances of less than 1 kâ¦.

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The equation in Figure 45 shows the calculation of

the total circuit noise, with these parameters:

â¢ en = Voltage noise

â¢ in = Current noise

â¢ RS = Source impedance

â¢ k = Boltzmannâs constant = 1.38 Ã 10â23 J/K

â¢ T = Temperature in Kelvins (K)

10k

100

Eo2 = en2 + (inRS)2 + 4KTRS

OPA166x

OPA165x

100

Resistor Noise

10k

100k

Source Resistance (W)

G003

Figure 45. Noise Performance of the OPA166x in

Unity-Gain Buffer Configuration

BASIC NOISE CALCULATIONS

Design of low-noise op amp circuits requires careful

consideration of a variety of possible noise

contributors: noise from the signal source, noise

generated in the op amp, and noise from the

feedback network resistors. The total noise of the

circuit is the root-sum-square combination of all noise

components.

The resistive portion of the source impedance

produces thermal noise proportional to the square

root of the resistance. Figure 45 plots this equation.

The source impedance is usually fixed; consequently,

select the op amp and the feedback resistors to

minimize the respective contributions to the total

noise.

Figure 46 illustrates both inverting and noninverting

op amp circuit configurations with gain. In circuit

configurations with gain, the feedback network

resistors also contribute noise. The current noise of

the op amp reacts with the feedback resistors to

create additional noise components. The feedback

resistor values can generally be chosen to make

these noise sources negligible. The equations for

total noise are shown for both configurations.

Product Folder Link(s): OPA1662 OPA1664

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