THS4524-EP_17 Datasheet, PDF(24/48 Page) Texas Instruments – VERY LOW POWER, NEGATIVE RAIL INPUT, RAIL-TO-RAIL OUTPUT, FULLY DIFFERENTIAL AMPLIFIER

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THS4524-EP_17 Datasheet, PDF (24/48 Pages) Texas Instruments – VERY LOW POWER, NEGATIVE RAIL INPUT, RAIL-TO-RAIL OUTPUT, FULLY DIFFERENTIAL AMPLIFIER

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THS4524-EP

SBOS609A â JUNE 2012 â REVISED AUGUST 2013

www.ti.com

TEST CIRCUITS

Overview

The THS4524 is tested with the test circuits shown in

this section; all circuits are built using the available

THS4524 evaluation module (EVM). For simplicity,

power-supply decoupling is not shown; see the layout

in the Applications section for recommendations.

Depending on the test conditions, component values

change in accordance with Table 1 and Table 2, or

as otherwise noted. In some cases the signal

generators used are ac-coupled and in others they

dc-coupled 50-â¦ sources. To balance the amplifier

when ac-coupled, a 0.22-Î¼F capacitor and 49.9-â¦

resistor to ground are inserted across RIT on the

alternate input; when dc-coupled, only the 49.9-â¦

resistor to ground is added across RIT. A split power

supply is used to ease the interface to common test

equipment, but the amplifier can be operated in a

single-supply configuration as described in the

Applications section with no impact on performance.

Also, for most of the tests, except as noted, the

devices are tested with single-ended inputs and a

transformer on the output to convert the differential

output to single-ended because common lab test

equipment has single-ended inputs and outputs.

Similar or better performance can be expected with

differential inputs and outputs.

As a result of the voltage divider on the output formed

by the load component values, the amplifier output is

attenuated. The Atten column in Table 2 shows the

attenuation expected from the resistor divider. When

using a transformer at the output (as shown in

Figure 55), the signal sees slightly more loss because

of transformer and line loss; these numbers are

approximate.

Table 1. Gain Component Values for

Single-Ended Input(1)

Gain

1 V/V

2 V/V

5 V/V

10 V/V

1 kâ¦

487 â¦

187 â¦

86.6 â¦

RIT

52.3 â¦

53.6 â¦

59.0 â¦

69.8 â¦

â¦ input termination.

Table 2. Load Component Values For 1:1

Differential to Single-Ended Output Transformer(1)

100 â¦

200 â¦

499 â¦

1 kâ¦

24.9 â¦

86.6 â¦

237 â¦

487 â¦

ROT

Open

69.8 â¦

56.2 â¦

52.3 â¦

Atten

6 dB

16.8 dB

25.5 dB

31.8 dB

1. Total load includes 50-â¦ termination by the test

equipment. Components are chosen to achieve

load and 50-â¦ line termination through a 1:1

transformer.

Frequency Response

The circuit shown in Figure 54 is used to measure the

frequency response of the circuit.

An HP network analyzer is used as the signal source

and the measurement device. The output impedance

of the HP network analyzer is is dc-coupled and is

50 â¦. RIT and RG are chosen to impedance-match to

50 â¦ and maintain the proper gain. To balance the

amplifier, a 49.9-â¦ resistor to ground is inserted

across RIT on the alternate input.

The output is probed using a Tektronix high-

impedance differential probe across the 953-â¦

resistor and referred to the amplifier output by adding

back the 0.42-dB because of the voltage divider on

the output.

VIN+

From

50-W

Source

Calibrated

Differential

Probe

Across

RIT

Open

Installed to

Balance

Amplifier

49.9 W

RIT

0.22 mF

RIT RG

1 kW

VS+

THS452x

VOCM

VS-

1 kW

24.9 W

953 W

Measure with

Differential

Probe

Across ROT

Open

0.22 mF

1. Gain setting includes 50-â¦ source impedance.

Components are chosen to achieve gain and 50-

Figure 54. Frequency Response Test Circuit

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