VITESSE VSC8117QP2, VSC8117QP1, VSC8117QP Datasheet

VITESSE

SEMICONDUCTOR CORPORATION

Data Sheet

SC8117

ATM/SONET/SDH 622/155 Mb/s Transceiver Mux/Demux

with Integrated Clock Generation and Clock Recovery

Features

• Operates at Either STS-3/STM-1 (155.52Mb/s)

or STS-12/STM-4 (622.08Mb/s) Data Rates

• Compatible with Industry ATM UNI Devices

• On Chip Clock Generation of the

622.08MHz High Speed Clock (Mux)

or

• On Chip Clock Recovery of the

622.08MHz High Speed Clock (Demux)

• 8 Bit Parallel TTL Interface

• SONET/SDH Frame Recovery

• Loss of Signal (LOS) Input & LOS Detection

155.52MHz

155.52MHz or

• +3.3V/5V programmable PECL Serial Interface

• Provides Equipment, Facilities and Split Loop­back Modes as well as Loop Timing Mode

• Provides TTL and PECL reference clock inputs

• Meets Bellcore, ITU and ANSI Specifications for
Jitter Performance

• Low Power - 1.0 Watts Typical

• 64 PQFP Package

General Description

The VSC8117 is an ATM/SONET/SDH compatible transceiver integrating an on-chip Clock Multiplication
Unit (PLL) for the high speed clock as well as a clock and data recovery unit (CRU) with 8 bit serial-to-parallel
and parallel-to-serial data conversion. The PLL clock is used for serialization in the transmit direction (Mux).
The recovered clock is used for deserializatio n in the receive direction (Demux). Th e demultiplexer contains
SONET/SDH frame detection and recovery. The device provides facility loopback, equipment loopba ck, and
loop timing modes. The part is packaged in a 64-pin PQFP with integrated heat spreader for optimum thermal
performance and reduced cost. The VSC81 17 provides an integrated solution for ATM physical layers and
SONET/SDH systems applications.

Functional Description

The VSC8117 is designed to provide a SONET/SDH compliant interface between the high spee d optical
networks and the lower speed User Network Interface devices such as the PM5355 S/UNI-622. The VSC8117
converts 8 bit parallel data at 77.76Mb/s or 19.44Mb/s to a serial bit str eam at 622.08Mb/s or 15 5.52Mb/s
respectively. The device also provides a Facility Loopback function which loops the received high speed data
and clock (optionally recovered on-chip) directly to the high speed trans mit outpu ts. A Cloc k Multiplier Unit
(CMU) is integrated into the transmit circuit to generate the high speed clock for the serial output data stream
from input reference fr equenci es of 19. 44 or 7 7.76 MHz. Th e CMU can be byp assed with th e reco v ered clo ck in
loop timing mode thus synchronizing the entire part to a single clock. The block diagram on page 2 shows the
major functional blocks associated with the VSC8117.

The receiv e sect io n pr ovides the serial-to-par al l el conversion , conver t in g the 155.52Mb/s or 622.08Mb /s bit
stream to an 8 bit parallel o utput at 19 .44Mb/s or 77.76Mb /s respectively. A Clock Reco v ery Unit (CRU) is inte­grated into the receive circuit to recover the high speed clock from the received serial data stream. The receive
section provides an Equipment Loopback function which will loop the low speed transmit data and clock back
through the receive section to the 8 bit parallel data bus and clock outputs. The VSC8117 also provides the

option of selecting between either its internal CRU’s recovered clock and data signals or optics containing a

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VITESSE SEMICONDUCTOR CORPORATION

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VITESSE

SEMICONDUCTOR CORPORATION

ATM/SONET/SDH 622/155 Mb/s Transceiver Mux/Demux
with Integrated Clock Generation and Clock Recovery

Data Sheet

VSC8117

CRU clock and data signals. (In this mode the VSC8117 operates just like the VSC8111 and VSC8116). The
receive section al so contains a SONET/ SDH frame detector circuit which is used to pro vide frame plus es during
the A1, A2 boundary in the serial to parallel converter. This only occurs when OOF is high. Both internal and
external LOS functions ar e supp or te d. The high speed serial signals can be made PECL compatibl e or LVPECL
compatible by setting the proper voltage on the V

supply pins

DDP

VSC8117 Block Diagram

EQULOOP

DSBLCRU

RXDATAIN+/-

CRUEQLP

RXCLKIN+/-

FRAMER

DQ

0
1

REC-CLK

1
0

0
1

1
0

REC-DATA

CRU

losdet

0
1

0
1

1:8

DEMUX

Divide-by-8

DQ

8

OOF
FP

RXOUT[7:0]

RXLSCKOUT

LOSPECL

LOSDETEN_

CRUREFCLK

CRUREFSEL

TXDATAOUT+/-

FACLOOP

0
1

1
0

DQ

1
0

1
0

CMU

MUX

Divide-by-8

8:1

QD

8

STS12

REFCLKP+/­REFCLK

CMUFREQSEL

LOOPTIM0

TXIN[7:0]

TXLSCKOUT

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VITESSE SEMICONDUCTOR CORPORATION

G52221-0, Rev 4.1

VITESSE

SEMICONDUCTOR CORPORATION

Data Sheet

SC8117

Transmit Section

Byte-wide data is presented to TXIN[7:0] and is clocked into the part on the rising edge of TXLSCKOUT.
TXLSCKOUT also latches TXIN[7:0] into the part as shown in Figure 1. The data is then serialized (MSB lead­ing) and presented at the TXD ATA OUT+/- pins. The seria l outp ut stream is synchron ized t o the CMU generated
clock which is a phase locked and frequency scaled version of the input reference clock. External control inputs
CMUFREQSEL and STS-12 select the multiply ratio of the CMU for either STS-3 (155MbS) or STS-12
(622Mb/s) transmission (see Table 10). A divide-by-8 version of the CMU clock (TXLSCKOUT) should be
used to synchronize the transmit interface of the UNI device to the transmit input registers on the VSC8117.

Figure 1: Data and Clock Transmit Block Diagram

TXDATAOUT+

TXDATAOUT-

ATM/SONET/SDH 622/155 Mb/s Transceiver Mux/Demux

with Integrated Clock Generation and Clock Recovery

VSC8117 PM5355

DQDQ

TXIN[7:0]

TXLSCKIN

DQ

REFCLK

Receive Section

High speed Non-Return to Zero (NRZ) serial data at 155Mb/s or 622Mb/s are received by the RXDATAIN
inputs. The CRU recovers the high speed clock from the serial data input. The serial data is converted to byte­wide parallel data and presented on RXOUT[7:0] pins. A divide-by-8 version of the high-speed clock
(RXLSCKOUT) should be used to synch r onize t he byte-serial RXOUT[7:0] data with the receive portion of the
UNI device. The on-chip CRU is by-passed by setting the DSBLCRU input high. In this mode, the serial input
data and corresponding clock are received by the RXDATAIN and RXCLKIN inputs respectively. RXDATAIN
is clocked in on the rising edge of RXCLKIN+. See Figure 2.

The receive section also includes frame detection a nd recovery circuitry which detec ts the SONET/SDH
frame, aligns the received serial data on byte boundaries, and initiates a frame pulse on FP coincident with the
byte aligned data. The frame recovery is initiated when OOF is held high which must occur at lea s t 4 byte clock
cycles before the A1A2 boundary. The OOF input control is a level-sensitive signal, and th e VSC8117 will con­tinually perform frame detection and recovery as long as this pin is held high even if 1 or more frames has been
detected. Frame detection and recovery occurs when a series of three A1 bytes followed by three A2 bytes has
been detected. The paralle l outp ut data on R XOUT[7:0] wil l be b yt e alig ned startin g on the thi rd A2 b yte. Wh en
a frame is detected, a single byte clock pe riod long pulse is g enerated o n FP which i s synchronize d with the
byte-aligned third A2 byte on RXOUT[7:0]. The frame detector sends a FP pulse only if OOF is high.

Divide-by-8CMU

TXLSCKOUT

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VITESSE SEMICONDUCTOR CORPORATION

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VITESSE

SEMICONDUCTOR CORPORATION

ATM/SONET/SDH 622/155 Mb/s Transceiver Mux/Demux
with Integrated Clock Generation and Clock Recovery

Data Sheet

VSC8117

Loss of Signal

The VSC8117 features Loss of Signal (LOS) detection. Loss of Signal is declared if the incoming serial
data stream has no transition continuously for more than 128 bits. During an LOS condition, the VSC 8117
forces the receive data low which is an indication for an y do wnstre am equipment that an optical interfac e fail ure
has occurred. The receive section continues to be clocked by the CRU as it is now locked to the CRUREFCLK
unless DSBLCRU is active or CRUREFSEL is inactive in which case it will be clocked by the C MU. This LOS
condition will be removed when the part detects more than 16 transitions in a 128 bit time window. This LOS
detection feature can be disabled by applying a high level to the LOSDETEN_ input. The VSC8117 also has a
PECL input LOSPECL to force the part into a Loss of Signal stat e. Most optics have a PECL outpu t usually

called “SD” or “FLA G” indi catin g a lack of or presence of optica l po wer. Depending on the optics manufacturer
this signal is either active high or active low. The LOSPECL input on the VSC8117 is active low.

Figure 2: Data and Clock Receive Block Diagram

PM5355

LOSPECL

LOSDETEN_

VSC8117

DQ

DQ

RXOUT[7:0]

DQ

DSBLCRU

RXDATAIN+/-

RXCLKIN+/-

CRU

1
0

0

0

1

1

CMU

Divide-by-8

DQ

FP

RXLSCKOUT

DQ

Facility Loopback

The Facility Loopback function is controlled by the FACLOOP signal. When the FACLOOP signal is set
high, the Facility Loopback mode is activated and the high speed serial receive data (RXDATAIN) is presented
to the high speed transmit output (TXDATAOUT). See Figure 3. In Facility Loopback mode the high speed
receive data (RXDATAIN) is also converted to parallel data and presented to the low speed receive data output
pins (RXOUT[7:0]). The receive clock (RXCLKIN) or the recovered clock is also divided down and presented
to the low speed clock output (RXLSCKOUT).

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741 Calle Plano, Camarillo, CA 93012 • 805/388-3700 • FAX: 805/987-5896 1/8/00

VITESSE SEMICONDUCTOR CORPORATION

G52221-0, Rev 4.1

VITESSE

SEMICONDUCTOR CORPORATION

Data Sheet

SC8117

ATM/SONET/SDH 622/155 Mb/s Transceiver Mux/Demux

with Integrated Clock Generation and Clock Recovery

Figure 3: Facility Loopback Data Path

RXDATAIN

RXCLKIN

TXDATAOUT

FACLOOP

Recovered

Clock

CRU

Q

0
1

Q

1

D

0

1
0

1:8
Serial to
Parallel

Divide-by-8

Parallel to
Serial

PLL

D

Q

Q

D

RXOUT[7:0]

RXLSCKOUT

TXIN[7:0]8:1

D

Equipment Loopback

The Equipment Loopback function is controlled by the EQULOOP signal. When the EQULOOP signal is
set high, the Equipment Loopback mode is activated and the high speed transmit data generated from the paral­lel to serial conversion of the low speed data (TXIN[7:0]) is selected and converted back to parallel data in the
receiver section and presented to the low speed parallel o utputs (RXOUT[7:0]). S ee Figure 4. The inte rnally
generated 155/622MHz clock i s used t o g enerate t he low speed receive clock output (RXLSCKOUT). In Equip­ment Loopback mode the transmit data (TXIN[7:0]) is serialized by the on-chip CMU and presente d at the hi gh
speed output (TXDATAOUT).

CRU Equipment Loopback

Exactly the same as equipment loopback, the point where the transmit data is looped back is moved all the
way back to the high speed I/O. When the CRUEQLP signal is set high, transmit data is looped back to the

CRU, replacing RXDATAIN±

Figure 4: Equipment Loopback Data Path

D

RXDATAIN

EQULOOP

TXDATAOUT

G52221-0, Rev. 4.1 

Q

0
1

Q

D

VITESSE SEMICONDUCTOR CORPORATION

1:8
Serial to
Parallel

8

÷

8:1
Parallel to
Serial

PLL ÷ 8

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D

Q

Q

D

RXOUT[7:0]

RXLSCKOUT

TXIN[7:0]

TXLSCKOUT

Page 5

VITESSE

SEMICONDUCTOR CORPORATION

ATM/SONET/SDH 622/155 Mb/s Transceiver Mux/Demux
with Integrated Clock Generation and Clock Recovery

Data Sheet

VSC8117

Split Loopback

Equipment and facility loopback modes can be enabled simultaneously. In this case, high-speed serial data

received (RXDATAIN) is mux’d through to the high-speed serial output (TXDATAOUT). The low-speed trans­mit byte wide bus(TXIN[7:0]) and (TXLSCKIN) are mux’d into the low-speed byte wide receive output bus
(RXOUT[7:0]) and (RXLSCKOUT). See Figure 5.

Figure 5: Split Loopback Datapath

D

RXDATAIN

RXCLKIN

DSBLCRU

TXDATAOUT

Recovered

Clock

CRU

Q

0
1

Q

D

PLL

1:8
Serial to
Parallel

8:1
Parallel to
Serial

÷8

D

Q

Q

D

RXOUT[7:0]

RXLSCKOUT

TXIN[7:0]

TXLSCKIN

Loop Timing

LOOPTIM0 mode bypasses the CMU when the LOOPTIM0 input is asserted high. In this mode the CMU
is bypassed by using the receive clock (RXCLKIN), and the entire part is synchronously clocked from a single
external source.

Clock Synthesis

The VSC8117 uses an integrated phase-locked loop (PLL) for c lock synthesis of the 622MHz hig h speed
clock used for serialization in the transmitter section. The PLL is comprised of a phase-frequency detector
(PFD), an integrating operation amplifier and a voltage controlled oscillator (VCO) configured in classic feed­back system. The PFD compares the selected divided down version of the 622MHz VCO (pin CMUFREQSEL
selects the divide-by ratios of 8 or 32, see Table 10) and the reference clock. The integrator provides a transfer
function between input phase error and ou tput voltage control. The V CO portion of the PLL is a voltage con­trolled ring-oscillator with a center frequency of 622MHz.

The reactive elements of the integrator are located off-chip and are connected to the feedback loop of the
amplifier through the CP1, CP2, CN1 and CN2 p ins. The configuration of thes e external surface moun ted
capacitors is shown in Figure 6. Table 1 shows the recommended external capacitor values for the configurable
reference frequencies.

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G52221-0, Rev 4.1

VITESSE

SEMICONDUCTOR CORPORATION

Data Sheet

SC8117

Good analog design practices should be applied to the board design for these external components. Tightly
controlled analog ground and power planes should be provided for the PLL portion of the circuitry. The dedi­cated PLL power (VDDA) and ground (VSSA) pins should have quiet supply planes to minimize jitter genera­tion within the clock synthesis uni t. This is accomp lished by eithe r using a ferrite be ad or a C-L-C choke (
filter) on the (VDDA) power pins. Note: Vitesse recommends a (π filter) C-L-C choke over using a ferrite bead.
All ground planes should be tied together using multiple vias.

Reference Clocks

To improve jitter performance and to provide flexibility, an additional differential PECL reference clock

input is provided. This reference clock is internally XNOR’d with a TTL reference clock input to generate the
reference for the CMU. Vitesse reco mmends u s ing t he di fferential PECL i nput and tieing the unused TTL r efer ­ence clock low. If the TTL reference clock is used the positive side of the differential PECL reference clock
“REFCLKP+” should be tied to ground. “REFCLKP+/-” are internally biased with on-chip resistors to 1.65(for

3.3V case) volts, see figure 13 for schematic of internal biasing of differential I/O’s.

The CRU has the option of either using the CMU’s reference clock or its own independent reference clock
“CRUREFCLK”. This is accomp lished wit h the control signal “CRUREFSEL”. The “CR UREFCLK” should be
used if the system is being o perated in e ither a regeneration or looptiming m ode. In e ither of the se modes the
quality of the “CRUREFCLK” is not a concern, thus it can be driven by a simple 77.76MHz crystal, the key is
its’ independent of the CMU’s reference clock.

ATM/SONET/SDH 622/155 Mb/s Transceiver Mux/Demux

with Integrated Clock Generation and Clock Recovery

π

Table 1: Recommended External Capacitor Values

Reference

Frequency

[MHz]

19.44 32 0.1 0.1 X7R 0603/0805 +/-10%

77.76 8 0.1 0.1 X7R 0603/0805 +/-10%

Divide Ratio CP CN Type Size Tol.

Figure 6: External Integrator Capacitor

CP = 0.1 µF

CP1

+

-

CN1 CN2

CP2

CN = 0.1 µF

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