OPA1632 Datasheet, PDF(7/12 Page) Texas Instruments – High-Perfomance, Fully-Differential AUDIO OP AMP

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OPA1632 Datasheet, PDF (7/12 Pages) Texas Instruments – High-Perfomance, Fully-Differential AUDIO OP AMP

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OPA1632

www.ti.com

FULLY-DIFFERENTIAL AMPLIFIERS

Differential signal processing offers a number of

performance advantages in high-speed analog signal

processing systems, including immunity to external

common-mode noise, suppression of even-order

nonlinearities, and increased dynamic range. Fully-dif-

ferential amplifiers not only serve as the primary means

of providing gain to a differential signal chain, but also

provide a monolithic solution for converting single-en-

ded signals into differential signals allowing for easy,

high-performance processing.

A standard configuration for the device is shown in

Figure 2. The functionality of a fully differential amplifier

can be imagined as two inverting amplifiers that share

a common noninverting terminal (though the voltage is

not necessarily fixed). For more information on the

basic theory of operation for fully differential amplifiers,

refer to the Texas Instruments application note

SLOA054, Fully Differential Amplifiers, available for

download from the TI web site (www.ti.com).

VIN+

VINâ

+15V

VOCM

â15V

Digital

AIN

Output

AIN

VREF

Figure 2. Typical ADC Circuit

SHUTDOWN FUNCTION

The shutdown (enable) function of the OPA1632 is

referenced to the negative supply of the operational

amplifier. A valid logic low (< 0.8V above negative

supply) applied to the enable pin (pin 7) disables the

amplifier output. Voltages applied to pin 7 that are

greater than 2V above the negative supply place the

amplifier output in an active state, and the device is

enabled. If pin 7 is left disconnected, an internal pull-up

resistor enables the device. Turn-on and turn-off times

are approximately 2Âµs each.

SBOS286 â DECEMBER 2003

Quiescent current is reduced to approximately 0.85mA

when the amplifier is disabled. When disabled, the

output stage is not in a high-impedance state. Thus, the

shutdown function cannot be used to create a

multiplexed switching function in series with multiple

amplifiers.

OUTPUT COMMON-MODE VOLTAGE

The output common-mode voltage pin sets the DC

output voltage of the OPA1632. A voltage applied to the

VOCM pin from a low-impedance source can be used to

directly set the output common-mode voltage. For a

VOCM voltage at mid-supply, make no connection to the

VOCM pin.

Depending on the intended application, a decoupling

capacitor is recommended on the VOCM node to filter

any high-frequency noise that could couple into the

signal path through the VOCM circuitry. A 0.1ÂµF or 1ÂµF

capacitor is generally adequate.

Output common-mode voltage causes additional

current to flow in the feedback resistor network. Since

this current is supplied by the output stage of the

amplifier, this creates additional power dissipation. For

commonly-used feedback resistance values, this

current is easily supplied by the amplifier. The additional

internal power dissipation created by this current may

be significant in some applications and may dictate use

of the MSOP PowerPAD package to effectively control

self-heating.

PowerPAD DESIGN CONSIDERATIONS

The OPA1632 is available in a thermally-enhanced

PowerPAD family of packages. These packages are

constructed using a downset leadframe upon which the

die is mounted (see Figure 3[a] and Figure 3[b]). This

arrangement results in the lead frame being exposed as

a thermal pad on the underside of the package (see

Figure 3[c]). Because this thermal pad has direct

thermal contact with the die, excellent thermal

performance can be achieved by providing a good

thermal path away from the thermal pad.

DIE

(a) Side View

DIE

(b) End View

Thermal

Pad

Figure 3. Views of the Thermally-Enhanced Package.

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