SI5600 Datasheet, PDF(13/28 Page) List of Unclassifed Manufacturers – SiPHY-TM OC-192/STM-64 SONET/SDH TRANSCEIVER

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SI5600 Datasheet, PDF (13/28 Pages) List of Unclassifed Manufacturers – SiPHY-TM OC-192/STM-64 SONET/SDH TRANSCEIVER

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Si5600

Phase Offset

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0.30

Phase Offset is the sampling offset in degrees from the

center of the data eye, VPHASE is the voltage applied to

the PHASEADJ pin, and VREF is reference voltage

output on the VREF pin. A positive phase offset will

adjust the sampling point to lead the default sampling

point in the center of the data eye, and a negative phase

offset will adjust the sampling point to lag the default

sampling point.

Data recovery using a sampling phase offset is disabled

by tieing the PHASEADJ input to the supply (VDD). This

forces a phase offset of 0Â° to be used for data recovery.

Lock Detect

The Si5600 provides lock-detect circuitry that indicates

whether the PLL has achieved frequency lock with the

incoming data. This circuit compares the frequency of a

divided down version of the recovered clock with the

frequency of the supplied reference clock (REFCLK). If

the recovered clock frequency deviates from that of the

reference clock by the amount specified in Table 5 on

page 9, the PLL is declared out of lock, and the loss-of-

lock (RXLOL) pin is asserted. In this state, the PLL will

try to reacquire lock with the incoming data stream.

During reacquisition, the recovered clock frequency

(RXCLK1 and RXCLK2) will drift over a Â±1000 ppm

range relative to the supplied reference clock. The

RXLOL output will remain asserted until the recovered

clock frequency is within the REFCLK frequency by the

amount specified in Table 5 on page 9.

Lock-to-Reference

In applications where it is desirable to maintain a stable

output clock during an alarm condition like loss-of-

signal, the lock-to-reference input (LTR) can be used to

force a stable output clock. When LTR is asserted, the

CDR is prevented from acquiring the data signal and the

CDR will lock the RXCLKOUT1 and RXCLKOUT2

outputs to the provided REFCLK. In typical applications,

the LOS output would be tied to the LTR input to force a

stable output clock.

Deserialization

The Si5600 uses a 1:16 demultiplexer to deserialize the

high speed input. The deserialized data is output on a

16-bit parallel data bus RXDOUT[15:0] synchronous

with the rising edge of RXCLK1. This clock output is

derived by dividing down the recovered clock by a factor

of 16.

Serial Input to Parallel Output Relationship

The Si5600 provides the capability to select the order in

which the received serial data is mapped to the parallel

output bus RXDOUT[15:0]. The mapping of the receive

bits to the output data word is controlled by the

RXMSBSEL input. If RXMSBSEL is tied low, the first bit

received is output on RXDOUT0 and the following bits

are output in order on RXDOUT1 through RXDOUT15.

If RXMSBSEL is tied high, the first bit received is output

on RXDOUT15, and the following bits are output in

order on RXDOUT14 through RXDOUT0.

Auxiliary Clock Output

To support the widest range of system timing

configurations, a second clock output is provided on

RXCLK2. This output can be configured to provide a

clock that is a 1/16th or 1/64th submultiple of the high

speed recovered clock. The divide factor used to

generate RXCLK2 is controlled via the RXCLKDIV2

input as described in "Pin Descriptions: Si5600â" on

page 19. In applications which do not use RXCLK2, this

output can be powered down by forcing the

RSCLK2DSBL input high.

Data Squelch

During some system error conditions, such as LOS, it

may be desirable to force the receive data output to 0 in

order to avoid propagation of erroneous data into the

downstream electronics. In these applications, the

Si5600 provides a data squelching control input,

RXSQLCH. When this input is active low, the data on

RXDOUT will be forced to 0. Data squelch is disabled if

the device is operating in diagnostic loopback mode

(DLBK = 0).

Transmitter

The transmitter consists of a low jitter, clock multiplier

unit (CMU) with a 16:1 serializer. The CMU uses a

phase-locked loop (PLL) architecture based on Silicon

Laboratoriesâ proprietary DSPLLâ¢ technology. This

technology is used to generate ultra-low jitter clock and

data outputs that provide significant margin to the

SONET/SDH specifications. The DSPLL architecture

also utilizes a digitally implemented loop filter that

eliminates the need for external loop filter components.

As a result, sensitive noise coupling nodes that typically

cause degraded jitter performance in crowded PCB

environments are removed.

The DSPLLâ¢ also reduces the complexity and

performance requirements of reference clock

distribution strategies for OC-192/STM-64 optical port

cards. This is possible because the DSPLL provides

selectable wideband and narrowband loop filter settings

that allow the user to set the jitter attenuation

characteristics of the CMU to accommodate reference

clock sources that have a high jitter content. Unlike

Preliminary Rev. 0.31

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