ISL59532_07 INTERSIL [Intersil Corporation], ISL59532_07 Datasheet - Page 21

ISL59532_07

Manufacturer Part Number

ISL59532_07

Description

32x32 Video Crosspoint

Manufacturer

INTERSIL [Intersil Corporation]

Datasheet

1.ISL59532_07.pdf (24 pages)

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For this reason, the ISL59532 must be in DC-coupled

mode (Clamp Disabled) to be compatible with s-video

and component video signals.

Bandwidth Considerations

Wide frequency response (high bandwidth) in a video

system means better video resolution. Four sets of

frequency response curves are shown in Figure 47.

Depending on the switch configurations, and the routing (the

path from the input to the output), bandwidth can vary

between 100MHz and 350MHz. A short discussion of the

trade-offs — including matrix configuration, output buffer

gain selection, channel selection, and loading — follows.

In multiplexer mode, one input typically drives one output

channel, while in broadcast mode, one input drives all 32

outputs. As the number of outputs driven increases, the

parasitic loading on that input increases. Broadcast Mode is

the worst-case, where the capacitance of all 32 channels

loads one input, reducing the overall bandwidth. In addition,

due to internal device compensation, an output buffer gain of

x2 has higher bandwidth than a gain of x1. Therefore, the

highest bandwidth configuration is multiplexer mode (with

each input mapped to only one output) and an output buffer

gain of x2.

The relative locations of the input and output channels also

have significant impact on the device bandwidth (due to the

layout of the ISL59530 silicon). When the input and output

channels are further away, there are additional parasitics as

a result of the additional routing, resulting in lower

bandwidth.

The bandwidth does not change significantly with resistive

loading as shown in the typical performance curves.

However several of the curves demonstrate that frequency

response is sensitive to capacitance loading. This is most

significant when laying out the PCB. If the PCB trace length

between the output of the crosspoint switch and the back-

termination resistor is not minimized, the additional parasitic

capacitance will result in some peaking and eventually a

reduction in overall bandwidth.

FIGURE 47. FREQUENCY RESPONSE FOR VARIOUS MODES

-10

-2

-4

-6

-8

BROADCAST,

= 1

FREQUENCY (MHz)

BROADCAST,

= 2

100

MUX, A

= 2

1000

= 1

ISL59532

Linear Operating Region

In addition to bandwidth optimization, to get the best linearity

the ISL59532 should be configured to operate in its most

linear operating region. Figure 48 shows the differential gain

curve. The ISL59532 is a single supply 5V design with its

most linear region between 0.1 and 2V. This range is fine for

most video signals whose nominal signal amplitude is 1V.

The most negative input level (the sync tip for composite

video) should be maintained at 0.3V or above for best

operation.

In a DC-coupled application, it is the system designer’s

responsibility to ensure that the video signal is always in the

optimum range.

When AC coupling, the ISL59532’s Clamp (also called “DC

restore”) function automatically and continuously adjusts the

DC level so that the most negative portion of the video is

always equal to V

A discussion of the benefits of the DC restoration function

begins by understanding the Clamp circuit shown in

Figure 49. The incoming video signal is typically terminated

into 75Ω, then AC coupled through C

connected to the base of the buffer’s diff pair. These

components form the video path.

The Clamp function consists of Q

current sources, and the 3 switches controlled by the Clamp

Enable signal. The V

diode drops (Q

the cathode of D

keeping the IN

greater than V

high impedance. This is how the clamp function forces the

lowest portion of the video signal (the sync tip) to always be

equal to or greater than V

To make sure that the sync tip is always equal to (not equal

to or greater than) V

current from C

lower voltage than the previous sync tip, causing Q

to turn on at each sync tip and raise the voltage to V

2µA pulldown with a 0.1uF capacitor and a 15kHz HSYNC

frequency results in 1.3mV of “droop” across every line, or

FIGURE 48. DIFFERENTIAL GAIN RESPONSE

REF

. This causes each sync tip to be slightly

voltage at V

and D

REF

, Q

goes below V

REF

and D

) to the base of Q

, i

voltage is level-shifted up two

REF

is constantly sinking ~2µA of

REF

are off and the IN

REF

. If the voltage at IN

, D

, Q

, at which point it is

, Q

and D

. If the voltage at

, D

, the two

will turn on,

February 7, 2007

node is

REF

and D

FN7432.5

. The

ISL59532_07 INTERSIL [Intersil Corporation], ISL59532_07 Datasheet - Page 21

ISL59532_07

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