HDMP-1022 Datasheet, PDF(26/40 Page) Agilent(Hewlett-Packard) – Low Cost Gigabit Rate Transmit/Receive Chip Set with TTL I/Os

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HDMP-1022 Datasheet, PDF (26/40 Pages) Agilent(Hewlett-Packard) – Low Cost Gigabit Rate Transmit/Receive Chip Set with TTL I/Os

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HDMP-1024 (Rx)

Detectable Error States

M20SEL Not Asserted (16 bit mode)

xxxxxxx

xxxxxxx

xxxxxxx

xxxxxxx

xxxxxxx

xxxxxxx

D-Field

xx

xx

0x

11

xx

xx

xxxxxxx

xxxxxxx

xxxxxxx

xxxxxxx

xxxxxxx

xxxxxxx

HDMP-1024 (Rx)

Detectable Error States

M20SEL Asserted (20 bit mode)

xxxxxxxxx

xxxxxxxxx

xxxxxxxxx

xxxxxxxxx

xxxxxxxxx

xxxxxxxxx

D-Field

xx

xx

0x

11

xx

xx

xxxxxxxxx

xxxxxxxxx

xxxxxxxxx

xxxxxxxxx

xxxxxxxxx

xxxxxxxxx

C-Field

x00x

x11x

1100

1100

1010

0101

C-Field

x00x

x11x

1100

1100

1010

0101

Tx Operation Principles

The HDMP-1022 (Tx) is imple-

mented in a high performance

silicon bipolar process. The Tx

performs the following functions

for link operation:

â¢ Phase lock to frame rate clock

â¢ Clock multiplication

â¢ Frame encoding

â¢ Multiplexing

In normal operation, the Tx phase

locks to a user supplied frame

rate clock and multiplies the

frequency to produce the high

speed serial clock. When locked,

the Tx indicates that it is locked

by asserting the LOCKED output.

When the ED input is asserted,

the Tx asserts the RFD signal

indicating that it is now ready to

transmit data or control frames.

The Tx can accept either 16 or 17

bit wide parallel data and produce

a 20 bit frame. It also can accept

20 or 21 bit data and produce a

24 bit frame. Similarly, either 14

bit or 18 bit control words can be

transmitted in a 20 bit or 24 bit

frame respectively.

Tx Encoding

A simplified block diagram of the

transmitter is shown in Figure 4.

The PLL/Clock Generator locks

onto the incoming frame rate (or

one-half frame rate) clock and

multiplies it up to the serial clock

rate. It also generates all the

internal clock signals required by

the Tx chip.

The data inputs, D0-D19, as well

as the control signals; ED, FF,

DAV*, CAV*, and FLAG are

latched in on the rising edge of an

internally generated frame rate

clock. The data field is then

encoded depending on the state

of the control signals. At the same

time, the coding field is

generated. At this point, the entire

frame has been constructed in

parallel form and its sign is

determined. This frame sign is

compared with the accumulated

sign of previously transmitted bits

to decide whether to invert the

frame. If the sign of the current

frame is the same as the sign of

the previously transmitted bits,

then the frame is inverted. If the

signs are opposite, the frame is

not inverted. No inversion is

641

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