ISL59534 Datasheet, PDF(20/22 Page) Intersil Corporation

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ISL59534 Datasheet, PDF (20/22 Pages) Intersil Corporation – 32x16 Video Crosspoint

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ISL59534

0.2% of the video signal. Because 1.3mV is only 0.2% of a

0.7V video signal, this droop is imperceptible to the human

eye.

SS12

~0.4V

VREF

C2 (110ÂµA)

0.1ÂµF

VIDEOIN

INx

0.1ÂµF

INPUT

BUFFER

CLAMP

ENABLE

FIGURE 49. DC RESTORE BLOCK DIAGRAM

This is how the video is âDC-restoredâ after being AC

coupled into the ISL59534. The sync tip voltage will be equal

to VREF on the right side of C1, regardless of the DC level of

the video on the left side of C1. Due to various sources of

offset in the actual clamp function, the actual sync tip level is

typically about 75mV higher than VREF (for VREF = 0.4V).

FIGURE 50. DC RESTORE VIDEO WAVEFORMS

It is important to choose the correct value for CIN. Too small

a value will generate too much droop, and the image will be

visibly darker on the right than on the left. A CIN value that is

too large may cause the clamp to fail to converge. The droop

rate (dV/dt) is i1/CIN volts/second. In general, the droop

voltage should be limited to <1 IRE over a period of one line

of video; so for 1 IRE = 7mV, IB = 10ÂµA maximum, and an

NTSC waveform we will set CIN > 10ÂµA*60Âµs/7mV =

0.086ÂµF. Figure 50 shows the result of CIN = 0.1ÂµF

delivering acceptable droop and CIN = 0.001ÂµF producing

excessive droop.

When the clamp function is disabled in the CONTROL

ICLAMP current sinks/sources are disabled and the input

passes through the DC Restore block unaffected. In this

application VREF may be tied to GND.

Overlay Operation

The ISL59534 features an overlay feature, that allows an

external video signal or DC level to be inserted in place of

that output channelâs video. When the OVERN signal is

taken high, the output signal on the OUTN pin is replaced

with the signal on the VOVERN pin.

There are several ways the overlay feature can be used.

Toggling the OVERN signal at the frame rate or slower will

replace the video frame(s) on the OUTN pin with the video

supplied on the VOVERN pin.

Another option (for OSD displays, for example), is to put a

DC level on the VOVERN line and toggle the OVERN signal

at the pixel rate to create a monocolor image âoverlaidâ on

channel Nâs output signal.

Finally, by enabling the OVERN signal for some portion of

each line over a certain amount of lines, a picture-in-picture

function can be constructed.

Itâs important to note that the overlay inputs do not have the

DC Restore function previously described - the overlay

signal is DC coupled into the output. It is the system

designerâs responsibility to ensure that the video levels are

in the ISL59534âs linear region and matching the output

channelâs offset and amplitude. One easy way to do this is to

run the video to be overlaid through one of the ISL59534âs

unused channels and then into the VOVERN input.

The OVERN pins all have weak pulldowns, so if they are

unused, they can either be left unconnected or tied to GND.

Power Dissipation and Thermal Resistance

With a large number of switches, it is possible to exceed the

+150Â°C absolute maximum junction temperature under

certain load current conditions. Therefore, it is important to

calculate the maximum junction temperature for an

application to determine if load conditions or package types

need to be modified to assure operation of the crosspoint

switch in a safe operating area.

The maximum power dissipation allowed in a package is

determined according to:

PDMAX = T----J---M-----A----X-Î----â-J---A-T----A---M-----A----X--

(EQ. 1)

FN6249.5

February 7, 2007

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