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ManualsBrandsTEXAS INSTRUMENTS ManualsLinear ICsLinear IC - Amplifier - Video buffering Rail-to-rail 150 MHz TSSOP 20

DAC/

Encoder

3.3V

LPF

Sync

TIP

Clamp

DC+

250mV

DC+250mV

MUTE

1of3Channels

Bypass

2:1

1kW

250 W

AC -

BIAS

I2C-SDA I2C-SCL

9/16/

35MHz

Out

2.2pF

75 W

750 W

1kW

75 W

Video

Out

Sin-X/X

Compensation

With6-dBGain

In A

ADC/

Video

Decoder

3.3V

LPF

Sync

TIP

Clamp

DC+

250mV

MUTE

Bypass

2:1

1kW

250 W

AC -

BIAS

InB

InputB

Input A

1of3Channels

I2C-

SDA

I2C-

SCL

9/16/

35MHz

Out

Gain

Adjust

Cable

Equalization

Circuit

0.1 Fm

75 W

750 W

15pF

10pF

75 W

THS7353

SLOS484B –NOVEMBER 2005–REVISED AUGUST 2012

www.ti.com

A benefit of the externally configured gain control is it allows for frequency gain manipulation. There are two main

reasons to do this.

• The first reason is to account for skin-effect losses in cables. Skin-effect accounts for the high-frequency

current flow at the edges of a conductor. This results in an increase of resistance as frequency increases.

This high frequency resistance is proportional to the square-root of the frequency.

• For very short cable lengths, the skin effect can be generally ignored - especially for SD frequencies. But, if

the cable length is greater than 10-meters for G'B'R' or HD signals, this effect can start to cause losses in

high frequency signal amplitude. This would generally appear as a loss in sharpness on a video monitor.

One way to counter-act, or equalize, the skin-effect loss is to increase the gain of the amplifier at the same rate

of attenuation. The difficult problem with equalization is that skin effect is a function of the square-root of the

frequency. Hence, adding a simple RC zero network does not accurately equalize the loss. But, if combinations

of RC zeroes spread throughout the frequency spectrum are used, such as the one shown in Figure 66, then a

close approximation to skin-effect losses can be equalized out of the system. The amount of equalization is

dependant on the length of the cable and the type of cable used. So, fixing the equalization to account for a long

length of cable causes significant peaking issues when a short cable is used.

Figure 66. Skin-Effect Loss Compensation (Equalization) Input Buffer Configuration Example

Similar to skin-effect compensation, the other advantage of having control of the amplifier gain is for Sin-X/X

compensation. DACs have a roll-off at high-frequencies approximating a Sin-X/X loss. This is dependant on the

DAC, the sampling frequency, and the desired frequency of interest. Due to the numerous numbers of DACs and

video encoders available, the Sin-X/X compensation must be adjusted depending on the system. An example of

a dc-coupled Sin-X/X compensation circuit with a 6-dB gain is shown in Figure 67.

Figure 67. Sin-X/X Compensation with 6-dB Gain Output Buffer Configuration Example