THS7365 Datasheet, PDF(41/53 Page) Texas Instruments – 6-Channel Video Amplifier with 3-SD and 3-HD Sixth-Order Filters and 6-dB Gain

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THS7365

www.ti.com.................................................................................................................................................................................................. SBOS467 â MARCH 2009

The THS7365 SD filters have a nominal corner

(â3 dB) frequency at 9.5MHz and a â1-dB passband

typically at 8.2MHz. This 9.5-MHz filter is ideal for SD

NTSC, PAL, and SECAM composite video (CVBS)

signals. It is also useful for S-Video signals (YâCâ),

480i/576i Yâ/PâB/PâR, YâUâVâ, broadcast GâBâRâ signals,

and computer R'G'B' video signals. The 9.5-MHz,

â3-dB corner frequency was designed to achieve 54

dB of attenuation at 27 MHzâa common sampling

frequency between the DAC/ADC second and third

Nyquist zones found in many video systems. This

consideration is important because any signal that

appears around this frequency can also appear in the

baseband as a result of aliasing effects of an ADC

found in a receiver.

The THS7365 HD filters have a nominal corner

(â3 dB) frequency at 36MHz and a â1-dB passband

typically at 32MHz. This 36-MHz filter is ideal for HD

720p, 1080i, up to 1080p30 Yâ/PâB/PâR, broadcast

GâBâRâ signals, and computer RâGâBâ video signals up

to XGA. The 36-MHz, â3-dB corner frequency was

designed to achieve 42 dB of attenuation at 74.25

MHzâa common sampling frequency between the

DAC/ADC second and third Nyquist zones found in

many video systems.

Keep in mind that images do not stop at the DAC

sampling frequency, fS (for example, 27 MHz for

traditional SD DACs); they continue around the

sampling frequencies of 2x fS, 3x fS, 4x fS, and so on

(that is, 54-MHz, 81-MHz, 108-MHz, etc.). Because of

these multiple images, an ADC can fold down into the

baseband signal, meaning that the low-pass filter

must also eliminate these higher-order images. The

THS7365 filters are Butterworth filters and, as such,

do not bounce at higher frequencies, thus maintaining

good attenuation performance.

The filter frequencies were chosen to account for

process variations in the THS7365. To ensure the

required video frequencies are effectively passed, the

filter corner frequency must be high enough to allow

component variations. The other consideration is that

the attenuation must be large enough to ensure the

anti-aliasing/reconstruction filtering is sufficient to

meet the system demands. Thus, the selection of the

filter frequencies was not arbitrarily selected and is a

good compromise that should meet the demands of

most systems.

One of the features of the THS7365 is that these

filters can be bypassed. Bypassing the SD filters

results in an amplifier with 130-MHz bandwidth and

100-V/Âµs slew rate. This configuration can be helpful

when diagnosing potential system issues or when

simply wishing to pass higher frequency signals

through the system.

Bypassing the HD filters results in a amplifier

supporting 250-MHz bandwidth and 500-V/Âµs slew

rate. This configuration supports 1080p60 signals and

also computer R'G'B' signals up to UWXGA

resolution.

BENEFITS OVER PASSIVE FILTERING

Two key benefits of using an integrated filter system,

such as the THS7365, over a passive system are

PCB area and filter variations. The small TSSOP-20

package for six video channels is much smaller over

a passive RLC network, especially a six-pole passive

network. Additionally, consider that inductors have at

best Â±10% tolerances (normally, Â±15% to Â±20% is

common) and capacitors typically have Â±10%

tolerances. Using a Monte Carlo analysis shows that

the filter corner frequency (â3 dB), flatness (â1 dB), Q

factor (or peaking), and channel-to-channel delay

have wide variations. These variances can lead to

potential performance and quality issues in

mass-production environments. The THS7365 solves

most of these problems with the corner frequency

being essentially the only variable.

Another concern about passive filters is the use of

inductors. Inductors are magnetic components, and

are therefore susceptible to electromagnetic

coupling/interference (EMC/EMI). Some common

coupling can occur because of other video channels

nearby using inductors for filtering, or it can come

from nearby switched-mode power supplies. Some

other forms of coupling could be from outside sources

with strong EMI radiation and can cause failure in

EMC testing such as required for CE compliance.

One concern about an active filter in an integrated

circuit is the variation of the filter characteristics when

the ambient temperature and the subsequent die

temperature changes. To minimize temperature

effects, the THS7365 uses low-temperature

coefficient resistors and high-quality, low-temperature

coefficient capacitors found in the BiCom3X process.

These filters have been specified by design to

account for process variations and temperature

variations to maintain proper filter characteristics.

This approach maintains a low channel-to-channel

time delay that is required for proper video signal

performance.

Product Folder Link(s): THS7365

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