VSC7128QS 查看數據表(PDF) - Vitesse Semiconductor
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VSC7128QS
Vitesse Semiconductor
VSC7128QS Datasheet PDF : 10 Pages
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VITESSE
SEMICONDUCTOR CORPORATION
Hex Port Bypass Circuit / Dual Repeater
for 1.0625 Gb/s FC-AL Disk Arrays
Advance Product Information
VSC7128
Functional Description
A Port Bypass Circuit contains a differential 2:1 mux operating at 1.0625 Gb/s. The input to the PBC is
always passed to the LSOx output of the PBC to let the disk drive monitor loop activity. The mux selects either
the disk drive’s input, LSIx, or the input from the previous PBC as determined by the SELx input which is nor-
mally connected directly to the disk drives EN_BYP output. When SELx is HIGH, the mux selects the disk
drive input, LSIx. When SELx is LOW, the mux bypasses the disk drive input and passes the output of the pre-
vious PBC to the output of the PBC. Two extra muxes help route serial signals. MUX7 passes either the output
of PBC6 (bypass mode) or the output of CRU2 (normal mode) to MUX8/OUT1 depending whether SEL7 is
LOW or HIGH. MUX8 passes either the output of CRU1 or the output of MUX7 to PBC1 depending on
whether SEL8 is HIGH or LOW.
A TTL reference clock, REFCLK, is used by the internal Clock Multiplier Unit (CMU) to generate a baud
rate clock at 1.0625 Gb/s. If RFSEL is HIGH, the CMU multiplies REFCLK (nominally 106.25MHz) by a
factor of 10. If RFSEL is LOW, the CMU multiplies REFCLK (nominally 53.125MHz) by a factor of 20. The
user must ensure that RFSEL is properly set in order to match the frequency of REFCLK.
Two fully integrated Clock Recovery Units (CRUs) are provided to improve signal quality and determine
whether the input to the repeater is a valid Fibre Channel signal. Each repeater consists of a Clock Recovery
Unit (CRU) and a digital Signal Detect Unit (SDU). The CRU locks onto the incoming signal, generates a
recovered clock (at 1.0625 GHz) and uses this clock to resynchronize the incoming signal. The recovered data
has improved signal quality due to amplification and jitter attenuation. Recovered data is retimed to the recov-
ered clock, not to REFCLK. The design of the CRU eliminates the need for any Lock-to-Reference signal since,
in the absence of data, the CRU locks onto REFCLK automatically thereby eliminating the need for any exter-
nal control circuitry.
The Signal Detect Units (SDUs) tests the output of the CRUs for valid Fibre Channel data by detecting run
length errors (more than 5 consecutive 1's or 0's) and the absence of a seven bit pattern found in the K28.5 char-
acter of either disparity (‘0000101’ or ‘1111010’). This K28.5 pattern should occur multiple times between
frames. The maximum length of a Fibre Channel frame is 2148 bytes (or 21,480 encoded bits) and the SDU
divides time into ~31 microsecond time intervals (2^15 bit times). At the end of each interval, any run length or
K28.5 errors which occurred during the interval are stored internally for use by the state machine which drives
the SDU output, FAILx-.
The FAILSEL input controls both SDUs and the FAILx- outputs provide the status of each SDU. FAILSEL
selects two different modes generated by the SDU; Single Frame (LOW) or Multiple Frame (HIGH) Error
Mode. In Single Frame Error Mode, any error condition that occurs within an interval causes FAILx- to be
asserted LOW immediately after that interval. FAILx- remains asserted until immediately after an error-free
interval occurs. In Multiple Frame Error Mode, FAILx- is asserted after four consecutive intervals containing
errors and remains asserted until four consecutive error-free intervals occur. The intent of the Multiple Frame
Error Mode is to allow FAIL1- or FAIL2- to be directly connected to the mux controls, SEL8 or SEL7, in order
to configure the part to isolate IN1 or IN2 whenever valid data is not present. Single Frame Error Mode allows
the user to develop their own algorithm for monitoring data and controlling MUX8 or MUX7.
Page 2
© VITESSE SEMICONDUCTOR CORPORATION
741 Calle Plano, Camarillo, CA 93012 • 805/388-3700 • FAX: 805/987-5896
G52177-0, Rev. 2.3
8/31/98
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