ISL76322_15 Datasheet, PDF(11/14 Page) Intersil Corporation – 16-Bit Long-Reach Video Automotive Grade SERDES

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ISL76322_15 Datasheet, PDF (11/14 Pages) Intersil Corporation – 16-Bit Long-Reach Video Automotive Grade SERDES

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ISL76322

may require the deserializer to be manually reset. A 10ms delay

after the 1.8V supply is powered up guarantees normal

operation.

Power Supply Bypassing and Layout

The serializer and deserializer functions rely on the stable

functioning of PLLs locked to local reference sources or locked to

an incoming signal. It is important that the various supplies

(VDD_P, VDD_AN, VDD_CDR, VDD_TX) be well bypassed over a

wide range of frequencies, from below the typical loop bandwidth

of the PLL to approaching the signal bit rate of the serial data. A

combination of different values of capacitors from 1000pF to

5ÂµF or more with low ESR characteristics is generally required.

The parallel LVCMOS VDD_IO supply is inherently less sensitive,

but since the RGB and SYNC/DATAEN signals can all swing on the

same clock edge, the current in these pins, and the

corresponding GND pins, can undergo substantial current flow

changes. Once again, a combination of different values of

capacitors over a wide range, with low ESR characteristics, is

desirable.

A set of arrangements of this type is shown in Figure 5, where

each supply is bypassed with a ferrite-bead-based choke, and a

range of capacitors. A âchokeâ is preferable to an âinductorâ in

this application, since a high-Q inductor will be likely to cause one

or more resonances with the shunt capacitors, potentially

causing problems at or near those frequencies, while a âlossyâ

choke will reflect a high impedance over a wide frequency range.

The higher value capacitor, in particular, needs to be chosen

carefully, with special care regarding its ESR. Very good results

can be obtained with multilayer ceramic capacitors (available

from many suppliers) and generally in small outlines (such as the

1210 outline suggested in the schematic shown in Figure 5),

which provide good bypass capabilities down to a few mâ¦ at

1MHz to 2MHz. Other capacitor technologies may also be

suitable (perhaps niobium oxide), but âclassicâ electrolytic

capacitors frequently have ESR values of above 1â¦, that nullify

any decoupling effect above the 1kHz to 10kHz frequency range.

Capacitors of 0.1ÂµF offer low impedance in the 10MHz to 20MHz

region, and 1000pF capacitors in the 100MHz to 200MHz region.

In general, one of the lower value capacitors should be used at

each supply pin on the IC. Figure 5 shows the grounding of the

various capacitors to the pin corresponding to the supply pin.

Although all the ground supplies are tied together, the PCB layout

should be arranged to emulate this arrangement (at least for the

smaller value (high frequency) capacitors), as much as possible.

120Î©

10ÂµF

0.1ÂµF

10ÂµF

0.1ÂµF

10ÂµF

0.1ÂµF

120Î©

10ÂµF

0.1ÂµF

120Î©

10ÂµF

0.1ÂµF

10ÂµF

0.1ÂµF

FIGURE 5. POWER SUPPLY BYPASSING

I2C Interface

The I2C interface allows access to internal registers used to

configure the SERDES and to obtain status information. A

serializer must be assigned a different address than its

deserializer counterpart if the side channel is used. The upper 5

bits are permanently set to 011 11 and the lower 2 bits

determined by pins as follows:

1 I2CA1 I2CA0 R/W

Thus, 4 SERDES can reside on the same bus. By convention,

when all address pins are tied low, the device address is referred

to as 0x78.

SCL and SDA are open drain to allow multiple devices to share

the bus. If not used, SCL and SDA should be tied to VDD_IO.

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May 6, 2015

FN7611.3

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