CY7C9689A TAXI™-compatible HOTLink® Transceiver Datasheet.pdf

CY7C9689A
TAXI™-compatible HOTLink® Transceiver
Features
■
Second-generation HOTLink® technology
■
AMD™ AM7968/7969 TAXIchip™-compatible
■
8-bit 4B/5B or 10-bit 5B/6B NRZI encoded data transport
■
10-bit or 12-bit NRZI pre-encoded (bypass) data transport
■
Synchronous TTL parallel interface
■
Embedded/bypassable 256-character Transmit and Receive
FIFOs
■
50- to 200-MBaud serial signaling rate
■
Internal phase-locked loops (PLLs) with no external PLL
components
■
Dual differential PECL-compatible serial inputs and outputs
■
Compatible with fiber-optic modules and copper cables
■
Built-in self-test (BIST) for link testing
■
Link Quality Indicator
■
Single +5.0 V ±10%supply
■
100-pin TQFP
■
Pb-free package option available
Functional Description
The CY7C9689A HOTLink Transceiver is a point-to-point
communications building block allowing the transfer of data
over high-speed serial links (optical fiber, balanced, and
unbalanced copper transmission lines) at speeds ranging
between 50 and 200 MBaud. The transmit section accepts
parallel data of selectable widths and converts it to serial data,
while the receiver section accepts serial data and converts it
to parallel data of selectable widths. Figure 1 illustrates typical
connections between two independent host systems and
corresponding CY7C9689A parts. The CY7C9689A provides
enhanced technology, increased functionality, a higher level of
integration, higher data rates, and lower power dissipation
over the AMD AM7968/7969 TAXIchip products.
The transmit section of the CY7C9689A HOTLink can be
configured to accept either 8- or 10-bit data characters on each
clock cycle, and stores the parallel data into an internal
Cypress Semiconductor Corporation
Document Number: 38-02020 Rev. *H
•
synchronous Transmit FIFO. Data is read from the Transmit
FIFO and is encoded using embedded 4B/5B or 5B/6B
encoders to improve its serial transmission characteristics.
These encoded characters are then serialized, converted to
NRZI, and output from two PECL-compatible differential
transmission line drivers at a bit-rate of either 10 or 20 times
the input reference clock in 8-bit (or 10-bit bypass) mode, or
12 or 24 times the reference clock in 10-bit (or 12-bit bypass)
mode.
The receive section of the CY7C9689A HOTLink accepts a
serial bit-stream from one of two PECL compatible differential
line receivers and, using a completely integrated PLL clock
synchronizer, recovers the timing information necessary for
data reconstruction. The recovered bit stream is converted
from NRZI to NRZ, deserialized, framed into characters,
4B/5B or 5B/6B decoded, and checked for transmission
errors. The recovered 8- or 10-bit decoded characters are then
written to an internal Receive FIFO, and presented to the
destination host system.
The integrated 4B/5B and 5B/6B encoder/decoder may be
bypassed (disabled) for systems that present externally
encoded or scrambled data at the parallel interface. With the
encoder bypassed, the pre-encoded parallel data stream is
converted to and from a serial NRZI stream. The embedded
FIFOs may also be bypassed (disabled) to create a
reference-locked serial transmission link. For those systems
requiring even greater FIFO storage capability, external FIFOs
may be directly coupled to the CY7C9689A through the
parallel interface without the need for additional glue-logic.
The TTL parallel I/O interface may be configured as either a
FIFO (configurable for depth expansion through external
FIFOs) or as a pipeline register extender. The FIFO
configurations are optimized for transport of time-independent
(asynchronous) 8- or 10-bit character-oriented data across a
link. A Built-In Self-Test (BIST) pattern generator and checker
allows for testing of the high-speed serial data paths in both
the transmit and receive sections, and across the
interconnecting links.
HOTLink devices are ideal for a variety of applications where
parallel interfaces can be replaced with high-speed,
point-to-point serial links. Some applications include
interconnecting workstations, backplanes, servers, mass
storage, and video transmission equipment.
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised November 17, 2014
CY7C9689A
Contents
TAXI HOTLink Transceiver Logic Block Diagram ....... 3
Pin Configuration ............................................................. 4
Pin Descriptions ............................................................... 5
CY7C9689A HOTLink Operation ................................... 14
Overview ................................................................... 14
Transmit Data Path ................................................... 14
Receive Data Interface .............................................. 14
Oscillator Speed Selection ........................................ 14
CY7C9689A TAXI HOTLink Transceiver
Block Diagram Description ............................................ 15
Transmit FIFO ........................................................... 16
Encoder Block ........................................................... 16
Transmit Shifter ......................................................... 17
Routing Matrix ........................................................... 17
Serial Line Drivers ..................................................... 17
Transmit PLL Clock Multiplier .................................... 17
Transmit Control State Machine ................................ 18
Serial Line Receivers ................................................ 18
Signal Detect ............................................................. 18
Clock/Data Recovery ................................................. 18
Clock Divider ............................................................. 19
Deserializer/Framer ................................................... 19
Decoder Block ........................................................... 19
Receive Control State Machine ................................. 19
Receive FIFO ............................................................ 21
Receive Input Register .............................................. 21
Receive Output Register ........................................... 21
Maximum Ratings ........................................................... 23
Operating Range ....................................................... 23
CY7C9689A DC Electrical Characteristics ................... 23
AC Test Loads and Waveforms ..................................... 24
Capacitance[16] .............................................................. 24
CY7C9689A Transmitter TTL
Switching Characteristics, FIFO Enabled .................... 25
CY7C9689A Receiver TTL
Switching Characteristics, FIFO Enabled .................... 26
CY7C9689A Transmitter TTL
Switching Characteristics, FIFO Bypassed ................. 26
CY7C9689A Receiver TTL
Switching Characteristics, FIFO Bypassed ................. 27
CY7C9689A REFCLK Input
Switching Characteristics .............................................. 28
CY7C9689A Receiver
Switching Characteristics .............................................. 28
CY7C9689A Transmitter
Switching Characteristics .............................................. 29
CY7C9689A HOTLink Transmitter
Switching Waveforms .................................................... 29
Document Number: 38-02020 Rev. *H
CY7C9689A HOTLink Receiver
Switching Waveforms .................................................... 35
Output Enable Timing .............................................. 36
Functional Description ................................................... 38
CY7C9689A TAXI HOTLink Transmit-Path
Operating Mode Descriptions ....................................... 39
Synchronous Encoded .............................................. 39
Synchronous Pre-encoded ........................................ 39
Asynchronous Encoded ............................................ 39
CY7C9689A TAXI HOTLink Receive-Path
Operating Mode Descriptions ....................................... 39
Synchronous Decoded .............................................. 39
Synchronous Undecoded .......................................... 40
Asynchronous Decoded ............................................ 40
Asynchronous Undecoded ........................................ 40
BIST Operation and Reporting ...................................... 40
BIST Enable Inputs ................................................... 41
BIST Transmit Path ................................................... 41
BIST Receive Path .................................................... 42
BIST Three-state Control .......................................... 42
Bus Interfacing ............................................................... 42
Shared Bus Interface Concept .................................. 43
Device Selection ........................................................ 43
Address Match and FIFO Flag Access ...................... 43
Device Selection ........................................................ 44
Transmit Data Selection ............................................ 44
Receive Data Selection ............................................. 45
FIFO Reset Address Match ....................................... 47
FIFO Reset Sequence ............................................... 48
Transmit FIFO Reset Sequence ................................ 48
Receive FIFO Reset Sequence ................................. 51
Printed Circuit Board Layout Suggestions ................. 52
Ordering Information ...................................................... 53
Ordering Code Definitions ......................................... 53
Package Diagram ............................................................ 53
Acronyms ........................................................................ 54
Document Conventions ................................................. 54
Units of Measure ....................................................... 54
Document History Page ................................................. 55
Sales, Solutions, and Legal Information ...................... 56
Worldwide Sales and Design Support ....................... 56
Products .................................................................... 56
PSoC® Solutions ...................................................... 56
Cypress Developer Community ................................. 56
Technical Support ..................................................... 56
Page 2 of 56
CY7C9689A
Figure 1. HOTLink System Connections
TAXI HOTLink Transceiver Logic Block Diagram
TX
STATUS
TXDATA/TXCMD CONTROL
TXCLK
MODE
REFCLK
10
RX
STATUS
RXDATA/RXCMD
RXCLK
13
8
13
3
4
Mode
Control
Output Register
MUX
MUX
Output Register
Input Register
Flags
Mode
Receive
FIFO
Flags
Transmit
FIFO
CONTROL
CE
TXEN
RXEN
TXHALT
TXRST
RXRST
RFEN
TXBISTEN
RXBISTEN
RESET
Transmit
PLL Clock
Multiplier
MUX
Pipeline Register
MUX
Pipeline Register
Receive
Control
State
Machine
BIST LFSR
4B/5B, 5B/6B Encoder
Transmit
Control
State
Machine
MUX
Serial Shifter
Bit Clock
MODE
RANGESEL
SPDSEL
RXMODE[1:0]
FIFOBYP
EXTFIFO
ENCBYP
BYTE8/10
TEST
BIST LFSR
4B/5B, 5B/6B Decoder
Deserializer
Framer
Receive
Clock/Data
Recovery
Clock
Divider
Bit Clock
RXSTATUS
LFI
RXEMPTY
RXHALF
RXFULL
TX STATUS
TXEMPTY
TXHALF
TXFULL
Routing Matrix
Signal
Validation
DLB
OUTA
INA
OUTB
CURSETB
CURSETA
Document Number: 38-02020 Rev. *H
INB
A/B
CARDET
Page 3 of 56
CY7C9689A
VSSA
RXBISTEN
VSSA
CURSETB
VDDA
OUTB+
VSSA
OUTB–
VSSA
INB–
VDDA
INB+
VDDA
OUTA+
OUTA–
VSSA
VSSA
INA–
VDDA
INA+
VDDA
VDDA
CURSETA
VSSA
CARDET
Pin Configuration
TEST
1
100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76
75
A/B
2
74
RANGESEL
LFI
3
73
RFEN
VSS
4
72
TXFULL
DLB
5
71
CE
VLTN
6
70
TXHALF
TXBISTEN
7
69
RXEN
RXCLK
8
68
TXCLK
TXHALT
9
67
RXRST
RXFULL
10
66
VSS
VSS
11
65
RXSC/D
REFCLK
12
64
VDD
VSS
13
63
VSS
VDD
14
62
VDD
VSS
15
61
RXDATA[0]
TXRST
16
60
TXEMPTY
VDD
17
59
RXDATA[1]
TXEN
18
58
TXCMD[1]
RXHALF
19
57
VSS
TXSC/D
20
56
TXCMD[0]
RXEMPTY
21
55
VDD
TXDATA[0]
22
54
TXDATA[9]/TXCMD[2]
RXDATA[11]/RXCMD[1]
23
53
RXDATA[2]
RXMODE[1]
24
52
VSS
RXMODE[0]
25
51
26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50
Document Number: 38-02020 Rev. *H
Transmit
Data
Receive
FIFO
Status
System Host
EXTFIFO
BYTE8/10
Transmit
FIFO
RXDATA[3]
RXDATA[4]
Encoder
4B/5B, 5B/6B
RXDATA[5]
Serializer
TXDATA[7]
RXDATA[6]
TXDATA[6]
RXDATA[7]
TXDATA[5]
VSS
TXDATA[8]/TXCMD[3]
Decoder
4B/5B, 5B/6B
Serial Link
RESET
Control
CY7C9689A
Deserializer
Framer
Serializer
Encoder
4B/5B, 5B/6B
Data
Transmit
VSS
Serial Link
CY7C9689A
Status
VSS
TXDATA[4]
VDD
TXDATA[3]
RXDATA[8]/RXCMD[3]
TXDATA[2]
TXDATA[1]
RXDATA[9]/RXCMD[2]
RXDATA[10]/RXCMD[0]
FIFOBYP
Framer
Deserializer
ENCBYP
Decoder
4B/5B, 5B/6B
Control
FIFO
Transmit
System Host
Data
Receive
FIFO
Receive
VSS
CY7C9689A
SPDSEL
Receive
Data
Page 4 of 56
CY7C9689A
(
Pin Descriptions
Pin
Name
I/O Characteristics
Signal Description
Transmit Path Signals
68
TXCLK
TTL clock input
Internal Pull-up
Transmit FIFO Clock.
Used to sample all Transmit FIFO and related interface signals.
44, 42, TXDATA[7:0]
40, 36,
34, 32,
30, 22
TTL input, sampled on Parallel Transmit DATA Input.
TXCLK or REFCLK When selected (CE = LOW and TXEN = asserted), information on these inputs is
processed as DATA when TXSC/D is LOW and ignored otherwise. When the
Internal Pull-up
encoder is bypassed (ENCBYP is LOW), TXDATA[7:0] functions as the least significant eight bits of the 10- or 12-bit pre-encoded transmit character.
When the Transmit FIFO is enabled (FIFOBYP is HIGH), these inputs are sampled
on the rising edge of TXCLK. When the Transmit FIFO is bypassed (FIFOBYP is
LOW) these inputs are captured on the rising edge of REFCLK.
54, 46 TXDATA[9:8]/
TXCMD[2:3]
TTL input, sampled on Parallel Transmit DATA or COMMAND Input.
TXCLK or REFCLK When selected, BYTE8/10 is HIGH, and the encoder is enabled (ENCBYP is
HIGH), information on these inputs are processed as TXCMD[2:3] if TXSC/D is
Internal Pull-up
HIGH and ignored otherwise.
When selected, BYTE8/10 is LOW, and the encoder is enabled (ENCBYP is
HIGH), information on these inputs are processed as TXDATA[9:8] if TXSC/D is
LOW and ignored otherwise.
When the encoder is bypassed (ENCBYP is LOW), TXDATA[9:8] functions as the
9th and 10th bits of the 10- or 12-bit pre-encoded transmit character.
When the Transmit FIFO is enabled (FIFOBYP is HIGH), these inputs are sampled
on the rising edge of TXCLK. When the Transmit FIFO is bypassed (FIFOBYP is
LOW), these inputs are captured on the rising edge of REFCLK.
58, 56 TXCMD[1:0]
TTL input, sampled on Parallel Transmit COMMAND Input.
TXCLK or REFCLK When selected and the encoder is enabled (ENCBYP is HIGH), information on
Internal Pull-up
these inputs is processed as a COMMAND when TXSC/D is HIGH and ignored
otherwise.
When BYTE8/10 is HIGH and the encoder is bypassed (ENCBYP is LOW), the
TXCMD[1:0] inputs are ignored.
When BYTE8/10 is LOW and when the encoder is bypassed (ENCBYP is LOW),
the TXCMD[1:0] inputs function as the 11th and 12th (MSB) bits of the 12-bit
pre-encoded transmit character.
When the Transmit FIFO is enabled (FIFOBYP is HIGH), these inputs are sampled
on the rising edge of TXCLK. When the Transmit FIFO is bypassed (FIFOBYP is
LOW), these inputs are sampled on the rising edge of REFCLK.
20
TTL input, sampled on COMMAND or DATA input selector.
TXCLK or REFCLK When selected, BYTE8/10 is HIGH, and the encoder is enabled (ENCBYP is
Internal Pull-up
HIGH), this input selects if the DATA or COMMAND inputs are processed. If
TXSC/D is HIGH, the value on TXCMD[3:0] is captured as one of sixteen possible
COMMANDs, and the data on the TXDATA[7:0] bits are ignored. If TXSC/D is
LOW, the information on TXDATA[7:0] is captured as one of 256 possible 8-bit
DATA values, and the information on the TXCMD[3:0] bus is ignored.
When BYTE8/10 is LOW and the encoder is enabled (ENCBYP is HIGH) this input
selects if the DATA or COMMAND inputs are processed. If TXSC/D is HIGH, the
information on TXCMD[1:0] is captured as one of four possible COMMANDs, and
the information on the TXDATA[9:0] bits are ignored. If TXSC/D is LOW, the information on TXDATA[9:0] is captured as one of 1024 possible 10-bit DATA values,
and the information on the TXCMD[1:0] bus is ignored.
When the encoder is bypassed (ENCBYP is LOW) TXSC/D is ignored
TXSC/D
Document Number: 38-02020 Rev. *H
Page 5 of 56
CY7C9689A
Pin Descriptions
Pin
Name
(continued)
I/O Characteristics
Signal Description
18
TXEN
TTL input, sampled on Transmit Enable.
TXCLK or REFCLK TXEN is sampled on the rising edge of the TXCLK or REFCLK input and enables
parallel data bus write operations (when selected). The device is selected when
Internal Pull-up
TXEN is asserted during a clock cycle immediately following one in which CE is
sampled LOW.
Depending on the level on EXTFIFO, the asserted state for TXEN can be active
HIGH or active LOW. If EXTFIFO is LOW, then TXEN is active LOW and data is
captured on the same clock cycle where TXEN is sampled LOW. If EXTFIFO is
HIGH, then TXEN is active HIGH and data is captured on the clock cycle following
any clock edge when TXEN is sampled HIGH.
7
TXBISTEN
TTL input,
asynchronous
Internal Pull-up
16
TXRST
TTL input, sampled on Reset Transmit FIFO.
TXCLK
When the Transmit FIFO is enabled (FIFOBYP is HIGH), TXEN is deasserted, CE
Internal Pull-up
is asserted (LOW), and TXRST is sampled LOW by TXCLK for seven cycles, the
Transmit FIFO begins its internal reset process. The Transmit FIFO TXFULL flag
is asserted and the host interface counter and address pointer are zeroed. This
reset propagates to the serial transmit side, any remaining counters and pointers.
The TXFULL flag is asserted until both sides of the Transmit FIFO have reset.
While TXRST remains asserted, the Transmit FIFO remains in reset and the
TXFULL output remains asserted.
When the Transmit FIFO is bypassed (FIFOBYP is LOW), TXRST is ignored.
9
TXHALT
TTL input, sampled on Transmitter Halt Control Input.
When TXHALT is asserted LOW, transmission of data is suspended and the
TXCLK
Internal Pull-up
HOTLink TAXI transmits SYNC characters. When TXHALT is deasserted HIGH,
normal data processing proceeds.
If the Transmit FIFO is enabled (FIFOBYP is HIGH), the interface is allowed to
continue loading data into the Transmit FIFO while TXHALT is asserted.
72
TXFULL
Three-state TTL output, Transmit FIFO Full Status Flag.
changes following
When the Transmit FIFO is enabled (FIFOBYP is HIGH) and its flags are driven
TXCLK or REFCLK (CE is LOW), TXFULL is asserted when four or fewer characters can be written to
the HOTLink Transmit FIFO. If a Transmit FIFO reset has been initiated (TXRST
was sampled asserted for a minimum of seven TXCLK cycles), TXFULL is
asserted to enforce the full/unavailable status of the Transmit FIFO during reset.
When the Transmit FIFO is bypassed (FIFOBYP is LOW), the TXFULL output
changes after the rising edge of REFCLK. TXFULL is asserted when the transmitter is BUSY (not accepting a new data or command characters) and deasserted
when new characters can be accepted.
When the Transmit FIFO is bypassed and RANGESEL is HIGH or SPDSEL is
LOW, TXFULL toggles at the character rate to provide a character rate reference
control-indication since REFCLK is operating at twice of the data rate.
The asserted state of this output (HIGH or LOW) is determined by the state of the
EXTFIFO input. When EXTFIFO is LOW, TXFULL is active LOW. When EXTFIFO
is HIGH, TXFULL is active HIGH.
Document Number: 38-02020 Rev. *H
Transmitter BIST Enable.
When TXBISTEN is LOW, the transmitter generates a 511-character repeating
sequence that can be used to validate link integrity. This 4B/5B BIST sequence is
generated regardless of the state of other configuration inputs. The transmitter
returns to normal operation when TXBISTEN is HIGH. All Transmit FIFO read
operations are suspended when BIST is active.
Page 6 of 56
CY7C9689A
Pin Descriptions
Pin
Name
(continued)
I/O Characteristics
Signal Description
70
TXHALF
Three-state TTL output, Transmit FIFO Half-full Status Flag.
changes following
When the Transmit FIFO is enabled (FIFOBYP is HIGH and CE is LOW) TXHALF
TXCLK
is asserted when the HOTLink Transmit FIFO is half full (128 characters is half
full). If a Transmit FIFO reset has been initiated (TXRST was sampled asserted
for a minimum of seven TXCLK cycles), TXHALF is asserted to enforce the
full/unavailable status of the Transmit FIFO during reset.
When the Transmit FIFO is bypassed (FIFOBYP is LOW), TXHALF remains
deasserted, having no logical function.
TXHALF is forced to the High-Z state only during a “full-chip” reset (i.e., while
RESET is LOW).
60
TXEMPTY
Three-state TTL output, Transmit FIFO Empty Status Flag.
When the Transmit FIFO is enabled (FIFOBYP is HIGH and CE is LOW),
changes following
TXCLK or REFCLK TXEMPTY is asserted when the HOTLink Transmit FIFO has no data to forward
to the encoder. If a Transmit FIFO reset has been initiated (TXRST was sampled
asserted for a minimum of seven TXCLK cycles), TXEMPTY is deasserted and
remains deasserted until the Transmit FIFO reset operation is complete.
When the Transmit FIFO is bypassed (FIFOBYP is LOW), TXEMPTY is asserted
to indicate that the transmitter can accept data. TXEMPTY is also used as a BIST
progress indicator when TXBISTEN is asserted.
When TXBISTEN is asserted LOW, TXEMPTY becomes the transmit BIST-loop
counter indicator (regardless of the logic state of FIFOBYP). In this mode
TXEMPTY is asserted for one TXCLK or REFCLK period at the end of each transmitted BIST sequence.
Note: During BIST operations, when the Transmit FIFO is enabled (FIFOBYP is
HIGH), it is necessary to keep TXCLK operating, even though no data is loaded
into the Transmit FIFO and TXEN is never asserted, to allow the TXEMPTY flag
to respond to the BIST state changes.
The asserted state of this output (HIGH or LOW) is determined by the state of the
EXTFIFO input. When EXTFIFO is LOW, TXEMPTY is active LOW. When
EXTFIFO is HIGH, TXEMPTY is active HIGH.
If CE is sampled asserted (LOW), TXEMPTY is driven to an active state. If CE is
sampled deasserted (HIGH), TXEMPTY is placed into a High-Z state.
Receive Path Signals
8
RXCLK
41, 43, RXDATA[7:0]
45, 47,
48, 53,
59,61
Bidirectional TTL clock Receive Clock.
Internal Pull-up
When the Receive FIFO is enabled (FIFOBYP is HIGH), this clock is the Receive
interface input clock and is used to control Receive FIFO read and reset, operations. When the Receive FIFO is bypassed (FIFOBYP is LOW), this clock becomes
the recovered Receive PLL character clock output which runs continuously at the
character rate.
Three-state TTL output, Parallel Receive DATA Outputs.
changes following
When the decoder is enabled (ENCBYP is HIGH), the low-order eight bits of the
decoded DATA character are presented on the RXDATA[7:0] outputs. COMMAND
RXCLK
characters, when they are received, do not disturb these outputs. When the
decoder is bypassed, the low order eight bits of the non-decoded character are
presented on the RXDATA[7:0] outputs.
When the Receive FIFO is disabled (FIFOBYP is LOW), these outputs change on
the rising edge of the RXCLK output. When the Receive FIFO is enabled
(FIFOBYP is HIGH), these outputs change on the rising edge of RXCLK input.
RXEN is the three-state control for RXDATA[7:0].
Document Number: 38-02020 Rev. *H
Page 7 of 56
CY7C9689A
Pin Descriptions
Pin
Name
31, 33 RXDATA[9:8]/
RXCMD[2:3]
(continued)
I/O Characteristics
Signal Description
Three-state TTL output, Parallel Receive DATA or COMMAND Output.
changes following
When BYTE8/10 is HIGH and the decoder is enabled (ENCBYP is HIGH) these
RXCLK
outputs reflects the value for the most recently received RXCMD[2:3].
When BYTE8/10 is LOW and the decoder is enabled (ENCBYP is HIGH) these
outputs reflects the value for the most recently received RXDATA[9:8].
When the decoder is bypassed (ENCBYP is LOW), RXDATA[9:8] functions as the
9th and 10th bits of the 10- or 12-bit non-decoded receive character.
When the Receive FIFO is disabled (FIFOBYP is LOW), these outputs change on
the rising edge of the RXCLK output. When the Receive FIFO is enabled
(FIFOBYP is HIGH), these outputs change on the rising edge of the RXCLK input.
RXEN is a three-state control for RXDATA[9:8]/RXCMD[2:3].
23, 29 RXDATA[11:10] Three-state TTL output, Parallel Receive COMMAND Outputs.
/RXCMD[1:0]
changes following
When the decoder is enabled (ENCBYP is HIGH) these outputs reflect the value
RXCLK
for the most recently received RXCMD[1:0].
When BYTE8/10 is HIGH and the decoder is bypassed (ENCBYP is LOW), these
outputs have no meaning and are driven LOW.
When BYTE8/10 is LOW and the decoder is bypassed (ENCBYP is LOW),
RXCMD[1:0] functions as the 11th and 12th (MSB) bits of the 12-bit non-decoded
receive character.
When the Receive FIFO is disabled (FIFOBYP is LOW), this output changes on
the rising edge of the RXCLK output. When the Receive FIFO is enabled
(FIFOBYP is HIGH), these outputs change on the rising edge of the RXCLK input.
RXEN is a three-state control for RXCMD[1:0].
69
RXEN
TTL input, sampled
on RXCLK
Internal Pull-up
65
RXSC/D
Three-state TTL output, COMMAND or DATA Output Indicator.
When BYTE8/10 is HIGH and the decoder is enabled (ENCBYP is HIGH), this
changes following
RXCLK
output indicates which group of outputs have been updated. If RXSC/D is HIGH,
RXCMD[3:0] contains a new COMMAND. The DATA on the RXDATA[7:0] pins
remain unchanged. If RXSC/D is LOW, RXDATA[7:0] contains a new DATA
character. The COMMAND output on RXCMD[3:0] remain unchanged.
When BYTE8/10 is LOW and the decoder is enabled (ENCBYP is HIGH), this
output indicates which group of outputs have been updated. If RXSC/D is HIGH,
RXCMD[1:0] contains a new COMMAND and the DATA on the RXDATA[9:0]
remain unchanged. If RXSC/D is LOW, RXDATA[9:0] contains a new DATA
character and the COMMAND output on RXCMD[1:0] remain unchanged.
When the decoder is bypassed (ENCBYP is LOW) RXSC/D is not used and may
be left unconnected.
RXEN is a three-state control for RXSC/D.
6
VLTN
Three-state TTL output,
changes following
RXCLK
Internal Pull-down
Document Number: 38-02020 Rev. *H
Receive Enable Input.
RXEN is a three-state control for the parallel data bus read operations. RXEN is
sampled on the rising edge of the RXCLK input (or output) and enables parallel
data bus read operations (when selected). The device is selected when RXEN is
asserted during an RXCLK cycle immediately following one in which CE is sampled
LOW. The parallel data pins are driven to active levels after the rising edge of
RXCLK. When RXEN is de-asserted (ending the selection) the parallel data pins
are High-Z after the rising edge of RXCLK.
Depending on the level on EXTFIFO, this signal can be active HIGH or active LOW.
If EXTFIFO is LOW, then RXEN is active LOW. If EXTFIFO is HIGH, then RXEN
is active HIGH. Data is delivered on the clock cycle following any clock edge when
RXEN is active.
Code Rule Violation Detected.
VLTN is asserted in response to detection of a 4B/5B or 5B/6B character that does
not meet the coding rules of these characters. When VLTN is asserted, the values
on the output DATA and COMMAND buses remain unchanged. VLTN remains
asserted for one RXCLK period.
VLTN is used to report character mismatches when RXBISTEN is driven LOW.
VLTN is driven LOW when the decoder is bypassed (ENCBYP is LOW).
RXEN is a three-state control for VLTN.
Page 8 of 56
CY7C9689A
Pin Descriptions
Pin
67
Name
RXRST
(continued)
I/O Characteristics
Signal Description
TTL input, sampled on Receive FIFO Reset. Active LOW.
RXCLK
When the Receive FIFO is enabled (FIFOBYP is HIGH), RXEN is deasserted, CE
Internal Pull-up
is asserted (LOW), and RXRST is sampled while asserted (LOW) by RXCLK for
seven cycles, the Receive FIFO begins its internal reset process.
Once the reset operation is started, the RXEMPTY flag is asserted and the
interface counters and address pointer are zeroed. The reset operation proceeds
to clear out the internal write pointers and counters. The RXEMPTY output remains
asserted through the reset operation and remains asserted until new data is written
to the Receive FIFO. While RXRST remains asserted, the Receive FIFO remains
in reset and cannot accept received characters.
When the Receive FIFO is bypassed (FIFOBYP is LOW), RXRST is ignored.
24, 25 RXMODE[1:0]
Static control input
TTL levels
Normally wired HIGH or
LOW
Receiver Discard Policy Mode Select.
00b—allows all characters to be written into the Receive FIFO or output to the
Receive data bus
01b—discards all JK or LM sync characters except the “last” one of a string of sync
characters. Single sync characters in a data stream are included in the data written
into the Receive FIFO.
1Xb—discards all JK or LM sync characters. The data stream written into the
Receive FIFO does not include sync characters.
77
RXBISTEN
TTL input,
asynchronous
Internal Pull-up
Receiver BIST Enable. Active LOW.
When LOW, the receiver is configured to perform a character-for-character match
of the incoming data stream with a 511-character BIST sequence. The result of
character mismatches are indicated on the VLTN pin. Completion of each
511-character BIST loop is accompanied by an assertion pulse on the RXFULL
flag.
The state of ENCBYP, FIFOBYP, and BYTE8/10 have no effect on BIST operation.
73
RFEN
TTL input,
asynchronous
Internal Pull-up
Reframe Enable.
Used to control when the framer is allowed to adjust the character boundaries
based on detection of one or more framing characters in the data stream.
When framing is enabled (RFEN is HIGH) the receive framer realigns the serial
stream to the incoming 10-bit JK sync character (if BYTE8/10 is HIGH) or the 12-bit
LM sync character (if BYTE8/10 is LOW). Framing is disabled when RFEN is LOW.
The deassertion of RFEN freezes the character boundary relationship between
the serial stream and character clock. RFEN is an asynchronous input, sampled
by the internal Receive PLL character clock.
10
RXFULL
Three-state TTL output, Receive FIFO Full Flag.
changes following
When the Receive FIFO is enabled (FIFOBYP is HIGH) and its flags are driven
RXCLK
(CE is LOW), RXFULL is asserted when space is available for four or fewer
characters to be written to the HOTLink Receive FIFO. If the RXCLK input is not
continuous or the FIFO is accessed at a rate slower than data is being received,
RXFULL may also indicate that some data has been lost because of FIFO overflow.
When the Receive FIFO is bypassed (FIFOBYP is LOW), RXFULL is deasserted
to indicate that valid data may be present. RXFULL is also used as a BIST progress
indicator, and pulses once every pass through the 511 character BIST loop.
When RXBISTEN is asserted (LOW), RXFULL becomes the receive BIST loop
progress indicator (regardless of the logic state of FIFOBYP). While RXBISTEN
is asserted, RXFULL is asserted until the receiver detects the start of the BIST
pattern. Then RXFULL is deasserted for the duration of the BIST pattern, pulsing
asserted for one RXCLK period on the last symbol of each BIST loop. If 14 of 28
consecutive symbols are received in error, RXFULL returns to the asserted state
until the start of a BIST pattern is again detected.
The asserted state of this output (HIGH or LOW) is determined by the state of the
EXTFIFO input. When EXTFIFO is LOW, RXFULL is active LOW. When EXTFIFO
is HIGH, RXFULL is active HIGH.
Document Number: 38-02020 Rev. *H
Page 9 of 56
CY7C9689A
Pin Descriptions
Pin
Name
(continued)
I/O Characteristics
Signal Description
19
RXHALF
Three-state TTL output, Receive FIFO Half-full Flag.
changes following
When the Receive FIFO is enabled (FIFOBYP is HIGH and CE is LOW) RXHALF
RXCLK
is asserted when the HOTLink Receive FIFO is half full (128 characters is half full).
If a Receive FIFO reset has been initiated (RXRST was sampled asserted for a
minimum of seven RXCLK cycles), RXHALF is deasserted to enforce the
empty/unavailable status of the Receive FIFO during reset. If FIFOBYP is LOW,
RXHALF remains deasserted having no logical function.
RXHALF is forced to the High-Z state only during a “full-chip” reset (i.e., while
RESET is LOW).
21
RXEMPTY
Three-state TTL output, Receive FIFO Empty Flag.
changes following
When the Receive FIFO is enabled (FIFOBYP is HIGH) and its flags are driven
(CE is LOW), RXEMPTY is asserted when the HOTLink Receive FIFO has no data
RXCLK
to forward to the parallel interface. If a Receive FIFO reset has been initiated
(RXRST was sampled asserted for a minimum of seven RXCLK cycles),
RXEMPTY is asserted to enforce the empty/unavailable status of the Receive
FIFO during reset.
Any read operation occurring when RXEMPTY is asserted results in no change in
the FIFO status, and the data from the last valid read remains on the RXDATA bus.
When the Receive FIFO is bypassed but the decoder is enabled, RXEMPTY is
used as a valid data indicator. When deasserted it indicates that valid data is
present at the RXDATA or RXCMD outputs as indicated by RXSC/D. When
asserted it indicates that a SYNC character (JK or LM) is present on the RXCMD
output pins. When the Receive FIFO is bypassed (FIFOBYP is LOW), RXEMPTY
is deasserted whenever data is ready.
The asserted state of this output (HIGH or LOW) is determined by the state of the
EXTFIFO input. When EXTFIFO is LOW, RXEMPTY is active LOW. When
EXTFIFO is HIGH, RXEMPTY is active HIGH.
Control Signals
71
CE
TTL input sampled on
TXCLK, RXCLK, or
REFCLK
Document Number: 38-02020 Rev. *H
Chip Enable Input. Active LOW.
When CE is asserted and sampled LOW by RXCLK, the Receive FIFO status flags
are driven to their active states. When this input is deasserted and sampled by
RXCLK, the Receive FIFO status flags are placed in a High-Z state.
When CE has been sampled LOW and RXEN changes from deasserted to
asserted and is sampled by RXCLK, the RXSC/D, RXDATA[7:0],
RXDATA[9:8]/RXCMD[2:3] and VLTN output drivers are enabled and go to their
driven levels. These pins remain driven until RXEN is sampled deasserted.
When the Transmit FIFO is enabled (FIFOBYP is HIGH), and CE is asserted and
sampled by TXCLK, the Transmit FIFO status flags are driven to their active states.
When this input is deasserted and sampled by TXCLK, the Transmit FIFO status
flags are placed in a High-Z state.
When the Transmit FIFO is bypassed (FIFOBYP is LOW), and CE is asserted and
sampled by REFCLK, the Transmit FIFO status flags are driven to their active
states. When this input is deasserted and sampled by REFCLK, the Transmit FIFO
status flags are placed in a High-Z state.
When the Transmit FIFO is enabled (FIFOBYP is HIGH), CE has been sampled
LOW, and TXEN changes from deasserted to asserted and is sampled by TXCLK,
the TXSC/D, TXDATA[7:0], TXDATA[9:8]/RXCMD[2:3], and TXCMD[1:0] inputs
are sampled and passed to the Transmit FIFO. These inputs are sampled on all
consecutive TXCLK cycles until TXEN is sampled deasserted.
When the Transmit FIFO is bypassed (FIFOBYP is LOW), CE has been sampled
LOW, and TXEN changes from deasserted to asserted and is sampled by
REFCLK, the TXSC/D, TXDATA[7:0], TXDATA[9:8]/RXCMD[2:3], and
TXCMD[1:0] inputs are sampled and passed to the encoder or serializer as
directed by other control inputs. These inputs are sampled on all consecutive
REFCLK cycles until TXEN is sampled deasserted.
Page 10 of 56
CY7C9689A
Pin Descriptions
Pin
Name
(continued)
I/O Characteristics
Signal Description
12
REFCLK
TTL clock input
PLL Frequency Reference Clock.
This clock input is used as the timing reference for the transmit and receive PLLs.
When the Transmit FIFO is bypassed (FIFOBYP is LOW), REFCLK is also used
as the clock for the parallel transmit interface.
75
SPDSEL
Static control input
TTL levels
Normally wired HIGH or
LOW
Speed Select.
Used to select from one of two operating serial rates for the CY7C9689A. When
SPDSEL is HIGH, the signaling rate is between 100 and 200 MBaud. When LOW,
the signaling rate is between 50 and 100 MBaud. Used in combination with
RANGESEL and BYTE8/10 to configure the VCO multipliers and dividers.
74
RANGESEL
Static control input
TTL levels
Normally wired HIGH or
LOW
Range Select.
Selects the proper prescaler for the REFCLK input. If RANGESEL is LOW, the
REFCLK input is passed directly to the Transmit PLL clock multiplier. If
RANGESEL is HIGH, REFLCK is divided by two before being sent to the Transmit
PLL multiplier.
When the Transmit FIFO is bypassed (FIFOBYP is LOW), with RANGESEL HIGH
or SPDSEL LOW, TXFULL toggles at half the REFCLK rate to provide a character
rate indication, and to show when data can be accepted.
51
RESET
Asynchronous
TTL input
Master Reset for Internal Logic.
Pulsed LOW for one or more REFCLK cycles.
28
FIFOBYP
Static control input
TTL levels
Normally wired HIGH or
LOW
FIFO Bypass Enable.
When asserted, the Transmit and Receive FIFOs are bypassed. In this mode
TXCLK is not used. Instead all transmit data must be synchronous to REFCLK.
Transmit FIFO status flags are synchronized to REFCLK. All received data is
synchronous to RXCLK output. Receive FIFO status flags are synchronized to
RXCLK (the recovered Receive PLL character clock).
When not asserted, the Transmit and Receive FIFOs are enabled. In this mode all
Transmit FIFO writes are synchronized to TXCLK, and all Receive FIFO reads are
synchronous to the RXCLK input.
50
BYTE8/10
Static control input
TTL levels
Normally wired HIGH or
LOW
8/10-bit Parallel Data Size Select.
When set for 8-bit data (BYTE8/10 is HIGH) and the encoder is enabled (ENCBYP
is HIGH), 8-bit DATA characters and 4-bit COMMAND characters are captured at
the TXDATA[7:0] or TXCMD[3:0] inputs (selected by the TXSC/D input) and
passed to the Transmit FIFO (if enabled) and encoder. Received characters are
decoded, passed through the Receive FIFO (if enabled) and presented at either
the RXDATA[7:0] or RXCMD[3:0] outputs and indicated by the RXSC/D output.
When set for 8-bit data (BYTE8/10 is HIGH) and the encoder is bypassed
(ENCBYP is LOW), the internal data paths are set for 10-bit characters. Each
received character is presented to the Receive FIFO (if enabled) and is passed to
the RXDATA[9:0] outputs.
When set for 10-bit data (BYTE8/10 is LOW) and the encoder is enabled (ENCBYP
is HIGH), 10-bit DATA characters and 2-bit COMMAND characters are captured
at the TXDATA[9:0] or TXCMD[1:0] inputs (selected by the TXSC/D input) and
passed to the Transmit FIFO (if enabled) and encoder. Received characters are
decoded, passed through the Receive FIFO (if enabled) and presented at either
the RXDATA[9:0] or RXCMD[1:0] outputs and indicated by the RXSC/D output.
When set for 10-bit data (BYTE8/10 is LOW) and the encoder is bypassed
(ENCBYP is LOW), the internal clock data paths are set for 12-bit characters. Each
received character is presented to the Receive FIFO (if enabled) and is passed to
the RXDATA[9:0] and the RXCMD[1:0] outputs.
Document Number: 38-02020 Rev. *H
Page 11 of 56
CY7C9689A
Pin Descriptions
Pin
(continued)
Name
I/O Characteristics
Signal Description
49
EXTFIFO
Static control input
TTL levels
Normally wired HIGH or
LOW
External FIFO Mode.
EXTFIFO modifies the active state of the RXEN and TXEN inputs and the timing
of the Transmitter and Receiver data buses. When configured for external FIFOs
(EXTFIFO is HIGH), TXEN is assumed to be driven by the empty flag of an
attached CY7C42X5 FIFO, and RXEN is assumed to be driven by the almost full
flag of an attached CY7C42X5 FIFO. In this mode the active data transition is in
the clock following the clock edge that “enables” the data bus.
When not configured for external FIFOs (EXTFIFO is LOW), TXEN is assumed to
be driven as a pipeline register and RXEN is assumed to be driven by a controller
for a pipeline register. In this mode the active data transition is within the same
clock as the clock edge that “enables” the data bus.
EXTFIFO also modifies the output state of the Receive and Transmit FIFO flags.
When configured for external FIFOs (EXTFIFO is HIGH), the Full and Empty FIFO
flags are active HIGH (the Half full flag is always active LOW). When not configured
for external FIFOs (EXTFIFO is LOW), all of the FIFO flags are active LOW.
27
ENCBYP
Static control input
TTL levels
Normally wired HIGH or
LOW
Enable Encoder Bypass Mode.
When asserted, both the encoder and decoder are bypassed. Data is transmitted
without 4B/5B or 5B/6B encoding (but with NRZI encoding), LSB first. Received
data are presented as parallel characters to the parallel interface without decoding.
When deasserted, data is passed through both the encoder in the Transmit path
and the decoder in the Receive path.
Analog I/O and Control
89, 90, OUTA±
81, 82 OUTB±
PECL compatible
differential output
Differential Serial Data Outputs.
These PECL-compatible differential outputs are capable of driving terminated
transmission lines or commercial fiber-optic transmitter modules. To minimize the
power dissipation of unused outputs, the outputs should be left unconnected and
the associated CURSETA or CURSETB should be connected to VDD.
94, 93, INA±
86, 85 INB±
PECL compatible
differential input
Differential Serial Data Inputs.
These inputs accept the serial data stream for deserialization and decoding. Only
one serial stream at a time may be fed to the receive PLL to extract the data
content. This stream is selected using the A/B input.
97
CURSETA
Analog
Current-set Resistor Input for OUTA±.
A precision resistor is connected between this input and a clean ground to set the
output differential amplitude and currents for the OUTA± differential driver.
78
CURSETB
Analog
Current-set Resistor Input for OUTB±.
A precision resistor is connected between this input and a clean ground to set the
output differential amplitude and currents for the OUTB± differential driver.
100
CARDET
PECL input,
asynchronous
Carrier Detect Input.
Used to allow an external device to signify a valid signal is being presented to the
high-speed PECL input buffers, as is typical on an Optical Module. When CARDET
is deasserted LOW, the LFI indicator asserts LOW signifying a Link Fault. This
input can be tied HIGH for copper media applications.
2
A/B
Asynchronous TTL
input
Input A or Input B Selector.
When HIGH, input INA± is selected, when LOW, INB± is selected.
3
LFI
TTL output, changes
following RXCLK
Link Fault Indication Output. Active LOW.
LFI changes synchronous with RXCLK. This output is driven LOW when the serial
link currently selected by A/B is not suitable for data recovery. This could be
because:
Serial Data Amplitude is below acceptable levels
Input transition density is not sufficient for PLL clock recovery
Input Data stream is outside an acceptable frequency range of operation
CARDET is LOW
Document Number: 38-02020 Rev. *H
Page 12 of 56
CY7C9689A
Pin Descriptions
Pin
Name
(continued)
I/O Characteristics
Signal Description
5
DLB
Asynchronous TTL
input
Diagnostic Loop Back Selector.
When DLB is LOW, LOOP Mode is OFF. Output of the transmitter shifter is routed
to both OUTA± and OUTB± and the serial input selected by A/B is routed to the
receive PLL for data recovery.
When DLB is HIGH, Diagnostic Loopback is Enabled. Output of the transmitter
serial data is routed to the receive PLL for data recovery. Primarily used for System
Diagnostic test. The serial inputs are ignored and OUTA± and OUTB± are both
active.
1
TEST
Asynchronous TTL
input normally wired
HIGH
Test Mode Select.
Used to force the part into a diagnostic test mode used for factory ATE test. This
input must be tied HIGH during normal operation.
Power
80, 87, VDDA
88, 95,
96, 98
Power for PECL-compatible I/O signals and internal circuits.
76, 79, VSSA
83, 84,
91, 92,
99
Ground for PECL-compatible I/O signals and internal circuits.
14, 17, VDD
35, 55,
62, 64
Power for TTL I/O signals and internal circuits.
4,11,
VSS
13, 15,
26, 37,
38, 39,
52, 57,
63, 66
Ground for TTL I/O signals and internal circuits.
Document Number: 38-02020 Rev. *H
Page 13 of 56
CY7C9689A
CY7C9689A HOTLink Operation
Overview
The CY7C9689A is designed to move parallel data across both
short and long distances with minimal overhead or host system
intervention. This is accomplished by converting the parallel
characters into a serial bit-stream, transmitting these serial bits
at high speed, and converting the received serial bits back into
the original parallel data format.
The CY7C9689A offers a large feature set, allowing it to be used
in a wide range of host systems. Some of the configuration
options are
Encoder
Data from the host interface or Transmit FIFO is next passed to
an Encoder block. The CY7C9689A contains both 4B/5B and
5B/6B encoders that are used to improve the serial transport
characteristics of the data. For those systems that contain their
own encoder or scrambler, this Encoder may be bypassed.
Serializer/Line Driver
The data from the Encoder is passed to a Serializer. This
Serializer operates at 10 or 12 times the character rate. With the
internal FIFOs enabled, REFCLK can run at 1x, 2x, or 4x the
character rate. With the FIFOs bypassed, REFCLK can operate
at 1x or 2x the character rate. The serialized data is output in
NRZI format from two PECL-compatible differential line drivers
configured to drive transmission lines or optical modules.
■
AMD TAXIchip 4B/5B- and 5B/6B-compatible encoder/decoder
■
AMD TAXIchip-compatible serial link
■
AMD TAXIchip parallel COMMAND and DATA I/O bus
architecture
Receive Data Interface
■
8-bit or 10-bit character size
■
User-definable data packet or frame structure
■
Two-octave data rate range
■
Asynchronous (FIFOed) or synchronous data interface
Serial data is received at one of two PECL-compatible differential
line receivers. The data is passed to both a Clock and Data
Recovery PLL and to a Deserializer that converts NRZI serial
data into NRZ parallel characters. The Framer adjusts the
boundaries of these characters to match those of the original
transmitted characters.
■
Embedded or bypassable FIFO data storage
■
Encoded or non-encoded
■
Multi-PHY capability
This flexibility allows the CY7C9689A to meet the data transport
needs of almost any system.
Transmit Data Path
Transmit Data Interface/Transmit Data FIFO
The transmit data interface to the host system is configurable as
either an asynchronous buffered (FIFOed) parallel interface or
as a synchronous pipeline register. The bus itself can be
configured for operation with either 8-bit or 10-bit character
widths.
When configured for asynchronous operation (where the
host-bus interface clock operates asynchronous to the serial
character and bit stream clocks), the host interface becomes that
of a synchronous FIFO clocked by TXCLK. In this configuration
an internal 256-character Transmit FIFO is enabled that allows
the host interface to be written at any rate from DC to 50 MHz.
When configured for synchronous operation, the transmit
interface is clocked by REFCLK and operates synchronous to
the internal character and bit-stream clocks. The input register
can be written at either 1/10 or 1/12 the serial bit rate. This
interface can be clocked at up to 40 MHz when configured for
8-bit data width, and up to 33 MHz when configured for 10-bit
data bus width. Actual clock rate depends on data rate as well as
RANGESEL and SPDSEL logic levels.
Line Receiver/Deserializer/Framer
Decoder
The parallel characters are passed through a pair of 5B/4B or
6B/5B decoders and returned to their original form. For systems
that make use of external decoding or descrambling, the decoder
may be bypassed.
Receive Data Interface/Receive Data FIFO
Data from the decoder is passed either to a synchronous
Receive FIFO or is passed directly to the output register. The
output register can be configured for either 8-bit character or
10-bit character operation.
When configured for an asynchronous buffered (FIFOed)
interface, the data is passed through a 256-character Receive
FIFO that allows data to be read at any rate from DC to 50 MHz.
When configured for synchronous operation (Receive FIFO is
bypassed) data is clocked out of the Receive Output register at
up to 20 MHz when configured for 8-bit characters, or 16.67 MHz
when configured for 10-bit characters. The receive interface is
also configurable for FIFO flags with either HIGH or LOW status
indication
Oscillator Speed Selection
The CY7C9689A is designed to operate over a two-octave range
of serial signaling rates, covering the 50- to 200-MBaud range.
To cover this wide range, the PLLs are configured into various
sub-regions using the SPDSEL and RANGESEL inputs, and to
a limited extent the BYTE8/10 input. These inputs are used to
configure the various prescalers and clock dividers used with the
transmit and receive PLLs.
Both asynchronous and synchronous interface operations
support user control over the logical sense of the FIFO status
flags. Full and empty flags on both the transmitter and receiver
can be active HIGH or active LOW. This facilitates interfacing
with existing control logic or external FIFOs with minimal or no
external glue logic.
Document Number: 38-02020 Rev. *H
Page 14 of 56
CY7C9689A
CY7C9689A TAXI HOTLink Transceiver
Block Diagram Description
Figure 2. Transmit Input Register
TXDATA[7:0]
TXCMD[3:0]
TXEN
TXSC/D
CE
12
Transmit Input/Output Register
The CY7C9689A provides a synchronous interface for data and
command inputs, instead of the TAXI’s asynchronous strobed
interface. The Transmit Input Register, shown in Figure 2,
captures the data and command to be processed by the
HOTLink Transmitter, and allows the input timing to be made
compatible with asynchronous or synchronous host system
buses. These buses can take the form of external FIFOs, state
machines, or other control structures. Data and command
present on the TXDATA[9:0] and TXSC/D inputs are captured at
the rising edge of the selected sample clock. The transmit data
bus bit-assignments vary depending on the data encoding and
bus-width selected. These bus bit-assignments are shown in
Table 1, and list the functional names of these different signals.
Note that the function of several of these signals changes in
different operating modes. The logical sense of the enable and
FIFO flag signals depends on the intended interface convention
and is set by the EXTFIFO pin.
REFCLK
TXCLK
Transmit Input Register
14
To Encoder
Block
Transmit FIFO
The transmit interface supports both synchronous and
asynchronous clocking modes, each supporting both UTOPIA
and Cascade timing models. The selection of the specific
clocking mode is determined by the RANGESEL and SPDSEL
inputs and the FIFO Bypass (FIFOBYP) signal.
Table 1. Transmit Input Bus Signal Map
Transmit Encoder Mode[1]
TXDATA Bus Input Bit
Encoded 8-bit
Character Stream[2]
TXSC/D
TXSC/D
Pre-encoded 10-bit
Character Stream
Encoded 10-bit
Character Stream[3]
Pre-encoded 12-bit
Character Stream
TXSC/D
TXDATA[0]
TXDATA[0]
TXD[0][4]
TXDATA[0]
TXD[0][5]
TXDATA[1]
TXDATA[1]
TXD[1]
TXDATA[1]
TXD[1]
TXDATA[2]
TXDATA[2]
TXD[2]
TXDATA[2]
TXD[2]
TXDATA[3]
TXDATA[3]
TXD[3]
TXDATA[3]
TXD[3]
TXDATA[4]
TXDATA[4]
TXD[4]
TXDATA[4]
TXD[4]
TXDATA[5]
TXDATA[5]
TXD[5]
TXDATA[5]
TXD[5]
TXDATA[6]
TXDATA[6]
TXD[6]
TXDATA[6]
TXD[6]
TXDATA[7]
TXDATA[7]
TXD[7]
TXDATA[7]
TXD[7]
TXDATA[8]/TXCMD[3]
TXCMD[3]
TXD[8]
TXDATA[8]
TXD[8]
TXDATA[9]/TXCMD[2]
TXCMD[2]
TXD[9]
TXDATA[9][3]
TXD[9]
TXCMD[1]
TXCMD[1]
TXCMD[1]
TXD[10][5]
TXCMD[0]
TXCMD[0]
TXCMD[0]
TXD[11]
Notes
1. All open cells are ignored.
2. When ENCBYP is HIGH and BYTE8/10 is HIGH, transmitted bit order is the encoded form (MSB to LSB) of TXDATA[7,6,5,4] and TXDATA[3,2,1,0] or TXCMD[3,2,1,0] as selected by TXSC/D.
3. When ENCBYP is HIGH and BYTE8/10 is LOW, transmitted bit order is the encoded form (MSB to LSB) of TXDATA[8,7,6,5,4] and TXDATA[9,3,2,1,0] or
TXCMD[1,0] as selected by TXSC/D.
4. When ENCBYP is LOW and BYTE8/10 is HIGH, the transmitted bit order is (LSB to MSB) TXD[0,1,2,3,4,5,6,7,8,9].
5. When ENCBYP is LOW and BYTE8/10 is LOW, the transmitted bit order is (LSB to MSB) TXD[0,1,2,3,4,5,6,7,8,9,11,10].
Document Number: 38-02020 Rev. *H
Page 15 of 56
CY7C9689A
Synchronous Interface
Transmit FIFO
Synchronous interface clocking operates the entire transmit data
path synchronous to REFCLK. It is enabled by connecting
FIFOBYP LOW to disable the internal FIFOs.
The Transmit FIFO is used to buffer data and command captured
in the input register for later processing and transmission. This
FIFO is sized to hold 256 14-bit characters. When the Transmit
FIFO is enabled, and a Transmit FIFO write is enabled (the
device is selected and TXEN is sampled asserted), data is
captured in the transmit input register and stored into the
Transmit FIFO. All Transmit FIFO write operations are clocked
by TXCLK.
Asynchronous Interface
Asynchronous interface clocking controls the writing of host bus
data into the Transmit FIFO. It is enabled by setting FIFOBYP
HIGH to enable the internal FIFOs. In these configurations, all
writes to the Transmit Input Register, and associated transfers to
the Transmit FIFO, are controlled by TXCLK. The remainder of
the transmit data path is clocked by REFCLK or synthesized
derivatives of REFCLK.
Shared Bus Timing Model
The Shared Bus Timing Model allows multiple CY7C9689A
transmitters to be accessed from a common host bus. It is
enabled by setting EXTFIFO LOW. In shared bus timing, the
TXEMPTY and TXFULL outputs and TXEN input are all active
LOW signals. If the CY7C9689A is addressed by asserting CE
LOW, it becomes “selected” when TXEN is asserted LOW.
Following selection, data or command is written into the Transmit
FIFO on every clock cycle where TXEN remains LOW.
Cascade Timing Model
The Cascade timing model is a variation of the shared bus timing
model. Here the TXEMPTY and TXFULL outputs, and TXEN
input, are all active HIGH signals. Cascade timing makes use of
the same selection sequences as shared bus timing, but write
data accesses use a delayed write. This delayed write is
necessary to allow direct coupling to external FIFOs, or to state
machines that initiate a write operation one clock cycle before
the data is available on the bus.
The Transmit FIFO presents Full, Half-Full, and Empty FIFO
flags. These flags are provided synchronous to TXCLK. When
the Transmit FIFO is enabled, it allows operation with a
Moore-type external controlling state machine. When configured
for Cascade timing, the timing and active levels of these signals
are also designed to support direct expansion to Cypress
CY7C42x5 synchronous FIFOs.
Regardless of bus width (8- or 10-bit characters) the Transmit
FIFO can be clocked at any rate from DC to 50 MHz. This gives
the Transmit FIFO a maximum bandwidth of 50 million
characters per second. Since the serial outputs can only move
20 million characters per second at their fastest operating rate,
there is ample time to service multiple CY7C9689A HOTLinks
with a single controller.
The read port of the Transmit FIFO is connected to a logic block
that performs data formatting and validation. All data read operations from the Transmit FIFO are controlled by a Transmit Control
State Machine that operates synchronous to REFCLK.
Encoder Block
The Encoder logic block performs two primary functions:
encoding the data for serial transmission and generating BIST
patterns to allow at-speed link and device testing.
Cascade timing is enabled by setting EXTFIFO HIGH.
BIST LFSR
When used for FIFO depth expansion, Cascade timing allows
the size of the internal Transmit FIFO to be expanded to an
almost unlimited depth. It allows a CY7C42x5 series
synchronous FIFO to be attached to the transmit interface
without any extra logic, as shown in Figure 3.
The Encoder logic block operates on data stored in a register.
This register accepts information directly from the Transmit
FIFO, the Transmit Input Register or from the Transmit Control
State Machine when it inserts special characters into the data
stream.
Figure 3. External FIFO Depth Expansion of the CY7C9689A
Transmit Data Path
This same register is converted into a Linear Feedback Shift
Register (LFSR) when the BIST pattern generator is enabled
(TXBISTEN is LOW). When enabled, this LFSR generates a
511-character sequence that includes all Data and Special
Character codes, including the explicit violation symbols. This
provides a predictable but pseudo-random sequence that can be
matched to an identical LFSR in the Receiver.
CY7C42x5 FIFO
FF*
WEN*
D
TXCLK
FF*
WEN*
D
WCLK
CY7C9689A
TXEN
EF*
REN*
TXFULL
Q
TXDATA
TXSC/D
TXCLK
RCLK
“1”
EXTFIFO
Encoder
The data passed through the Transmit FIFO and pipeline
register, or as received directly from the Transmit Input Register,
is seldom in a form suitable for transmission across a serial link.
The characters must usually be processed or transformed to
guarantee:
■a
minimum transition density (to allow the serial receiver PLL
to extract a clock from the data stream)
■some way to allow the remote receiver to determine the correct
character boundaries (framing).
Document Number: 38-02020 Rev. *H
Page 16 of 56
CY7C9689A
The CY7C9689A contains an integrated 4B/5B encoder that
accepts 8-bit data characters and converts these into 10-bit
transmission characters that have been optimized for transport
on serial communications links. This 4B/5B encoding scheme is
compliant with the ANSI X3T9.5 (FDDI) committee’s 4B/5B code.
The CY7C9689A also contains a 5B/6B encoder that accepts
10-bit data characters and converts these into 12-bit transmission characters.
The 4B/5B, 5B/6B encoder can be bypassed for those systems
that operate with external 4B/5B or 5B/6B encoders or use
alternate forms of encoding or scrambling to ensure good transmission characteristics. The complete encoding tables are listed
in Table 7 and Table 8.
When the Encoder is enabled, the transmit data characters (as
passed through the Transmit FIFO and pipeline register) are
converted to either a 10-bit or 12-bit Data symbol or a 10-bit or 12-bit
Command Character, depending upon the state of the TXSC/D input.
If TXSC/D is HIGH, the data on the command inputs are encoded into
Command Character as shown in Table 8. If TXSC/D is LOW, the
data inputs are encoded using the Data Character encoding in
Table 7.
The 4B/5B, 5B/6B coding function of the Encoder can be
bypassed for systems that include an external coder or
scrambler function as part of the controller or host system. This
is performed by setting ENCBYP LOW. With the encoder
bypassed, each 10-bit or 12-bit character (as captured in the
Transmit Input Register) is passed directly to the Transmit Shifter
(or Transmit FIFO) without modification.
Transmit Shifter
The Transmit Shifter accepts 10-bit (BYTE8/10 = HIGH) or 12-bit
(BYTE8/10 = LOW) parallel data from the Encoder block once
each character time, and shifts it out the serial interface output
buffers using a PLL-multiplied bit-clock with NRZI encoding. This
bit-clock runs at 2.5, 5, or 10 times the REFCLK rate (3, 6, or 12
times when BYTE8/10 is LOW) as selected by RANGESEL and
SPDSEL (see Table 3). Timing for the parallel transfer is
controlled by the counter and dividers in the Clock Multiplier PLL
and is not affected by signal levels or timing at the input pins. Bits
in each character are shifted out LSB first.
Routing Matrix
The Routing Matrix is a precision multiplexor that allows local
diagnostic loopback. The signal routing for the transmit serial
outputs is controlled by the DLB input as listed Table 2.in
Serial Line Drivers
The serial interface PECL Output Drivers (ECL referenced to
+5 v) are the transmission line drivers for the serial media.
OUTA± receives its data directly from the transmit shifter, while
OUTB± receives its data from the Routing Matrix. These two
outputs (OUTA± and OUTB±) are capable of direct connection to
+5 v optical modules, and can also directly drive DC- or
AC-coupled transmission lines.
The PECL-compatible Output Drivers can be viewed as
programmable current sources. The output voltage is determined by the output current and the load impedance ZLOAD. The
desired output voltage swing is therefore controlled by the
current-set resistor RCURSET associated with that driver.
Different RCURSET values are required for different line
Document Number: 38-02020 Rev. *H
Table 2. Transmit Data Routing Matrix
DLB[0]
Data Connections
0
TRANSMIT
SHIFTER
OUTA
A/B
OUTB
INB
RECEIVE
PLL
INA
1
TRANSMIT
SHIFTER
OUTA
A/B
OUTB
INB
RECEIVE
PLL
INA
impedance/amplitude combinations. The output swing is
designed to center around VDD–1.33 v. Each output must be
externally biased to VDD–1.33 v.
This differential output-swing can be specified two ways: either
as a peak-to-peak voltage into a single-end load, or as an
absolute differential voltage into a differential load.
When specified into a single-ended load (one of the outputs
switching into a load), the single output will both source and sink
current as it changes between its HIGH and LOW levels. The
voltage difference between this HIGH level and LOW level
determine the peak-to-peak signal-swing of the output. This
amplitude relationship is controlled by the load impedance on the
driver, and by the resistance of the RCURSET resistor for that
driver, as listed in Eq. 1
180  Z LOAD
R CURSET = --------------------------------V OPP
Eq. 1
In Eq. 1, VOPP is the difference in voltage levels at one output of
the differential driver when that output is driving HIGH and LOW,
ZLOAD is that load seen by the one output when it is sourcing and
sinking current. With a known load impedance and a desired
signal swing, it is possible to calculate the value of the associated
CURSETA or CURSETB resistor that sets this current.
Unused differential output drivers should be left open, and can
reduce their power dissipation by connecting their respective
CURSETx input to VDD.
Transmit PLL Clock Multiplier
The Transmit PLL Clock Multiplier accepts an external clock at
the REFCLK input, and multiples that clock by 2.5, 5, or 10 (3, 6,
or 12 when BYTE8/10 is LOW and the encoder is disabled) to
generate a bit-rate clock for use by the transmit shifter. It also
provides a character-rate clock used by the Transmit Controller
state machine.
The clock multiplier PLL can accept a REFCLK input between
8 MHz and 40 MHz, however, this clock range is limited by the
operation mode of the CY7C9689A as selected by the SPDSEL
and RANGESEL inputs, and to a limited extent, by the BYTE8/10
Page 17 of 56
CY7C9689A
and FIFOBYP signals. The operating serial signalling rate and
allowable range of REFCLK frequencies is listed in Table 3.
Transmit Control State Machine
The Transmit Control State Machine responds to multiple inputs
to control the data stream passed to the encoder. It operates in
response to:
Table 3. Speed Select and Range Select Settings
RANGESEL
Serial
Data Rate
(MBaud)
REFCLK[7]
Frequency
(MHz)
LOW
LOW
50–100
10–20
LOW
HIGH[6]
50–100
20–40
HIGH
LOW
100–200
10–20
HIGH
HIGH
100–200
20–40
SPDSEL
TXHALT may be used to prevent a remote FIFO overflow, which
would result in lost data. This back-pressure mechanism can
significantly improve data integrity in systems that cannot
guarantee the full bandwidth of the host system at all times.
Serial Line Receivers
Two differential line receivers, INA± and INB±, are available for
accepting serial data streams, with the active input selected
using the A/B input. The DLB input allow the transmit Serializer output
to be selected as a third input serial stream, but this path is generally
used only for local diagnostic loopback purposes. The serial line
receiver inputs are all differential, and will accommodate wire interconnect with filtering losses or transmission line attenuation greater
than 9 dB (VDIF > 200 mV, or 400 mV peak-to-peak differential) or can
be directly connected to +5 v fiber-optic interface modules (any ECL
logic family, not limited to ECL 100K). The common-mode tolerance
of these line receivers accommodates a wide range of signal termination voltages.
■the
state of the FIFOBYP input
■the
presence of data in the Transmit FIFO
■the
contents of the Transmit FIFO
■the
state of the transmitter BIST enable (TXBISTEN)
As can be seen in Table 2, these inputs are configured to allow
single-pin control for most applications. For those systems
requiring selection of only INA± or INB±, the DLB signals can be tied
LOW, and the A/B selection can be performed using only A/B. For
those systems requiring only a single input and a local loopback,
the A/B can be tied HIGH or LOW, and DLB can be used for
loopback control.
■the
state of external halt signal (TXHALT).
Signal Detect
These signals are used by the Transmit Control State Machine
to control the data formatter, read access to the Transmit FIFO
and BIST. They determine the content of the characters passed
to the Encoder and Transmit Shifter.
The selected Line Receiver (that routed to the clock and data
recovery PLL) is simultaneously monitored for:
When the Transmit FIFO is bypassed, the Transmit Control State
Machine operates synchronous to REFCLK. In this mode, data
from the TXDATA bus is passed directly from the Input Register
to the Pipeline Register. If no data is enabled into the Input
register (TXEN is deasserted or TXFULL is asserted) then the
Transmit Control State Machine presents a JK or LM (when
BYTE8/10 = LOW) Command Character code to the Encoder to
maintain link synchronization.
■transition
If both the Encoder and Transmit FIFO are bypassed and no data
is enabled into the Input Register, the Transmit Control State
Machine injects JK or LM (when BYTE8/10 = LOW) into the
Serial Shifter Register at this time slot. This also occurs if the
Encoder is bypassed, the Transmit FIFO is enabled, and the
Transmit FIFO is empty.
External Control of Data Flow
The Transmit Control State Machine supports halting of data
transmission by the TXHALT input. This control signal input is
only interpreted when the Transmit FIFO is enabled. TXHALT is
brought directly to the state machine without going through the
Transmit FIFO.
The assertion of TXHALT causes character processing to stop
at the next FIFO character location. No additional data is read
from the Transmit FIFO until TXHALT is deasserted.
■analog
amplitude (> 400 mV pk-pk)
density
■received
data stream outside normal frequency range
(±400 ppm)
■carrier
detected
All of these conditions must be valid for the Signal Detect block
to indicate a valid signal is present. This status is presented on
the LFI (Link Fault Indicator) output, which changes synchronous
to RXCLK. While link status is monitored internally at all times, it
is necessary to have transitions on RXCLK to allow this signal to
change externally.
Clock/Data Recovery
The extraction of a bit-rate clock and recovery of data bits from
the received serial stream is performed within the Clock/Data
Recovery (CDR) block. The clock extraction function is
performed by a high-performance embedded PLL that tracks the
frequency of the incoming bit stream and aligns the phase of its
internal bit-rate clock to the transitions in the serial data stream.
The CDR makes use of the clock present at the REFCLK input.
It is used to ensure that the VCO (within the CDR) is operating
at the correct frequency (rather than some harmonic of the bit
rate), to improve PLL acquisition time, and to limit unlocked
frequency excursions of the CDR VCO when no data is present
at the serial inputs.
Notes
6. When SPDSEL is LOW and the FIFOs are bypassed (FIFOBYP is LOW), the RANGESEL input is ignored and is internally mapped to the LOW setting.
7. When configured for 12-bit preencoded data (BYTE8/10 and ENCBYP are both LOW) the allowable REFCLK ranges are 8.33 to 16.67 MHz and 16.67 to
33.33 MHz.
Document Number: 38-02020 Rev. *H
Page 18 of 56
CY7C9689A
Regardless of the type of signal present, the CDR will attempt to
recover a data stream from it. If the frequency of the recovered
data stream is outside the limits for the range controls, the CDR
PLL will track REFCLK instead of the data stream. When the
frequency of the selected data stream returns to a valid
frequency, the CDR PLL is allowed to track the received data
stream. The frequency of REFCLK is required to be within ±400
ppm of the frequency of the clock that drives the REFCLK signal
at the remote transmitter to ensure a lock to the incoming data
stream.
For systems using multiple or redundant connections, the LFI
output can be used to select an alternate data stream. When an
LFI indication is detected, external logic can toggle selection of
the INA± and INB± inputs through the A/B input. When a port
switch takes place, it is necessary for the PLL to reacquire the
new serial stream and frame to the incoming characters.
Clock Divider
This block contains the clock division logic, used to transfer the
data from the Deserializer/Framer to the Decoder once every
character (once every ten or twelve bits) clock. This counter is
free running and generates outputs at the bit-rate divided by 10
(12 when the BYTE8/10 is LOW). When the Receive FIFO is
bypassed, one of these generated clocks is driven out the
RXCLK pin.
Deserializer/Framer
The CDR circuit extracts bits from the serial data stream and
clocks these bits into the Shifter/Framer at the bit-clock rate.
When enabled, the Framer examines the data stream looking for
JK or LM (when BYTE8/10 is LOW) characters at all possible bit
positions. The location of this character in the data stream is
used to determine the character boundaries of all following
characters.
The framer operates in two different modes, as selected by the
RFEN input. When RFEN is asserted (HIGH), the framer is
allowed to reset the internal character boundaries on any
detected JK or LM (when BYTE8/10 is LOW) character.
If RFEN is LOW, the framer is disabled and no changes are made
to character boundaries.
The framer in the CY7C9689A operates by shifting the internal
character position to align with the character clock. This ensures
that the recovered clock does not contain any significant phase
changes/hops during normal operation or framing, and allows
the recovered clock to be replicated and distributed to other
circuits using PLL-based logic elements.
Decoder Block
The decoder logic block performs two primary functions:
decoding the received transmission characters back into Data
and Command Character codes, and comparing generated BIST
patterns with received characters to permit at-speed link and
device testing.
5B/4B, 6B/5B Decoder
The framed parallel output of the Deserializer is passed to the
5B/4B, 6B/5B Decoder. If the Decoder is enabled, it is transformed from a 10-bit or 12-bit transmission character back to the
original Data and Command Character codes. This block uses
the standard decoder patterns in Table 7 and Table 8 of this data
Document Number: 38-02020 Rev. *H
sheet. Data Patterns on the data bus are indicated by a LOW on
RXSC/D, and Command Character codes on the command bus are
indicated by a HIGH. Invalid patterns or disparity errors are signaled
as errors by a HIGH on VLTN.
If the Decoder is bypassed and BYTE8/10 is HIGH, the ten (10)
data bits of each transmission character are passed unchanged
from the framer to the Pipeline Register.
When the Decoder is bypassed and BYTE8/10 is LOW, the
twelve (12) data bits of each transmission character are passed
unchanged from the framer to the Pipeline Register.
BIST LFSR
The output register of the Decoder block is normally used to
accumulate received characters for delivery to the Receive
Formatter block. When configured for BIST mode (RXBISTEN is
LOW), this register becomes a signature pattern generator and
checker by logically converting to a Linear Feedback Shift
Register (LFSR). When enabled, this LFSR generates a
511-character sequence that includes all Data and Command
Character codes, including the explicit violation symbols. This
provides a predictable but pseudo-random sequence that can be
matched to an identical LFSR in the Transmitter. When synchronized with the received data stream, it checks each character in
the Decoder with each character generated by the LFSR and
indicates compare errors at the VLTN output of the Receive
Output Register.
The LFSR is initialized by the BIST hardware to the BIST loop
start code of HEX data 00 (00 is sent only once per BIST loop).
Once the start of the BIST loop has been detected by the
receiver, RXRVS is asserted for pattern mismatches between
the received characters and the internally generated character
sequence. Code rule violations or running disparity errors that
occur as part of the BIST loop do not cause an error indication.
RXFULL pulses asserted for one RXCLK cycle per BIST loop and
can be used to check test pattern progress.
The specific patterns checked by the receiver are described in
Table 4.
If a large number of errors are detected, the receive BIST state
machine aborts the compare operations and resets the LFSR to
the D0.0 state to look for the start of the BIST sequence again.
Receive Control State Machine
The Receive Control State Machine responds to multiple input
conditions to control the routing and handling of received
characters. It controls the staging of characters across various
registers and the Receive FIFO. It controls the various discard
policies and error control within the receiver, and operates in
response to:
■the
received character stream
■the
room for additional data in the Receive FIFO
■the
state of the receiver BIST enable (RXBISTEN)
■the
state of FIFOBYP.
These signals and conditions are used by the Receive Control
State Machine to control the Receive Formatter, write access to
the Receive FIFO, the Receive Output register, and BIST. They
determine the content of the characters passed to each of these
destinations.
Page 19 of 56
CY7C9689A
Table 4. CY7C9689A TAXI HOTLink BIST Sequence
D.00
C.JK
C.IH
C.SR
C.SS
C.JK
C.IH
C.QI
D.EE
C.RR D.B3
C.QQ D.FB
C.TR
C.SR
C.SS
C.QQ D.F8
C.TS
D.89
D.42
C.HI
D.94
C.TT
C.TR
D.15
D.0C
C.JK
C.RS
D.CD D.6A
D.3D
D.1E
C.HH D.8F
D.4B
D.23
D.11
D.04
C.JK
C.RS
D.C5
D.68
C.II
C.RS
D.C0
C.TS
C.QH D.D2
C.RR D.BC
C.TT
C.QH D.D7
D.6D
D.3A
C.HH
C.QI
D.EB
D.73
D.35
D.1C
C.JK
C.RS
D.CF
D.6B
D.33
C.HI
D.91
D.44
C.II
C.IH
C.QI
D.E6
C.RR D.B2
C.QI
C.HQ
D.A8
C.TT
C.QH D.D4
C.TS
D.E3
D.71
D.34
C.JK
C.IH
C.QI
D.ED
D.7A
C.HI
D.99
D.46
C.HI
D.96
C.HQ D.AE
C.HQ D.A3
D.51
D.24
C.JK
C.IH
C.QI
D.EC
C.TS
C.QH
D.D1
D.64
C.II
C.IH
C.QI
C.RR C.TR
C.QI
D.E0
C.TS
C.TR
C.SR
C.SS
C.SS
C.SS
C.SS
C.QQ D.F0
C.TS
C.TR
C.SR
C.QQ D.F4
C.TS
C.TR
C.QI
D.E1
D.70
C.II
C.IH
C.SR
C.QH D.D3
D.65
D.38
C.RS
D.C6
C.RR D.B6
C.QQ D.FC
C.TS
D.50
C.II
C.TR
D.77
D.2C
D.55
D.E4
C.JK
C.HQ D.AA
C.HQ D.A1
C.TT
C.QH
C.RR D.B0
C.TT
C.IH
C.SR
C.QQ D.FD
D.7E
C.HI
D.9B
D.47
D.29
D.12
C.HH D.8C
D.DD D.6E
C.HI
D.93
D.45
C.JK
C.RS
D.C4
C.TS
C.TR
C.QI
D.E2
C.TR
C.QQ D.F6
C.HQ D.A9
D.52
C.HI
D.9C
C.TT
C.QH D.DF
C.SR
D.28
C.RR D.BA
D.6F
D.3B
D.17
D.0D
D.0A
C.HH D.85
D.48
C.II
C.RS
D.C8
C.TS
C.QH D.D8
C.TS
C.QH D.DA
C.RR
D.BD
D.5E
C.HI
D.9F
D.4F
D.2B
D.13
D.05
D.08
C.JK
C.RS
D.CC C.TS
C.QH D.D9
D.66
C.HI
D.92
C.HQ D.AC
C.TT
C.QH D.D5
D.6C
C.II
C.RS
D.C1
D.60
C.II
C.IH
C.SR
C.SS
C.II
C.SS
C.SS
C.QQ D.F1
D.74
C.II
C.IH
C.QI
D.E5
D.78
C.RS
D.C2
C.RR D.B4
C.TT
C.TR
C.QI
D.E9
D.72
C.HI
D.98
C.TT
C.QH
D.DE
C.RR D.BF
D.5F
D.2F
D.1B
D.07
D.09
D.02
C.HH D.84
D.54
C.II
C.IH
C.QI
D.E7
D.79
D.36
D.5C
C.II
C.RS
D.CB
D.63
D.31
D.49
D.22
C.HH D.80
C.TT
C.HI
D.9D
D.4E
C.HI
D.97
C.RR D.B9
D.56
C.HI
D.9E
C.HQ D.AO C.TT
C.TR
C.TT
C.TR
C.QI
D.EA
C.RR
D.B1
C.HH D.8A
C.HQ D.A5
D.58
C.II
C.RS
D.CA
C.RR D.B5
D.14
C.JK
C.IH
C.QI
D.EF
D.7B
D.37
D.1D
D.0E
C.TR
C.SR
C.SS
C.QQ D.F9
D.76
C.HI
D.9A
C.HQ D.AD
D.4D
D.2A
C.HH D.81
D.40
C.II
C.IH
C.SR
C.SS
C.HQ D.AF
D.5B
D.19
D.06
C.HH D.86
D.27
C.SR
C.SS
C.SS
C.QQ D.F2
D.18
C.JK
C.RS
D.CE
C.SS
C.QQ D.F3
C.RR D.B8
C.RR D.B7
D.5D
C.HH D.87
D.5A
C.QQ D.FA
C.HQ D.A6
C.HQ D.A2
C.TT
C.QH D.D6
C.RR D.BE
C.HQ D.AB
D.53
D.25
D.2E
C.HH D.83
D.41
D.20
C.JK
C.SR
C.SS
C.TT
D.75
D.3C
C.JK
C.RS
D.C7
D.69
D.32
C.HH D.88
C.QH D.DB
D.67
D.39
D.16
C.HH D.8E
C.HQ
D.A7
D.59
D.26
C.TR
C.QI
D.E8
C.TS
C.QH D.D0
C.TS
C.TR
C.SR
D.30
C.JK
C.IH
C.SR
C.QQ D.FE
C.RR D.BB
D.57
The Receive Control State Machine always operates
synchronous to the recovered character clock (bit-clock/10 or
bit-clock/12). When the Receive FIFO is bypassed, RXCLK
becomes an output that changes synchronous to the internal
character clock. RXCLK operates at the same frequency as the
internal character clock.
Document Number: 38-02020 Rev. *H
C.IH
C.QH D.DC C.TS
C.HH D.82
C.HQ D.A4
C.TT
C.QQ D.F5
D.7C
C.RS
D.C3
D.61
D.2D
C.HH D.8D
D.4A
C.HI
D.95
D.1A
C.II
Discard Policies
When the Receive FIFO is enabled, the Receive Control State
Machine has the ability to selectively discard specific characters
from the data stream that are determined by the present configuration as being unnecessary. When discarding is enabled, it
reduces the host system overhead necessary to keep the
Receive FIFO from overflowing and losing data.
Page 20 of 56
CY7C9689A
The discard policy is configured as part of the operating mode
and is set using the RXMODE[1:0] inputs. The four discard
policies are listed in Table 5.
Figure 4. External FIFO Depth Expansion of the CY7C9689A
Receive Data Path)
Table 5. Receiver Discard Policies
Policy #
0 (00)
Policy Description
Keep all received characters
1 (01)
Process Commands, discard all but the last JK or
LM SYNC character
2 (1X)
Process Commands, discard all C5.0 characters
Policy 0 is the simplest and also applies for all conditions where
the Receive FIFO is bypassed. In this mode, every character that
is received is placed into the Receive FIFO (when enabled) or
into the Receive Output Register.
In discard policy 1, the JK or LM SYNC character, which is
automatically transmitted when no data is present in the Transmit
FIFO, is treated differently here. In this mode, whenever two or
more adjacent JK or LM characters are received, all of them are
discarded except the last one received before any other
character type. This allows these fill characters to be removed
from the data stream, but the last SYNC character which can be
used as a delimiter.
Policy 2 is identical to policy 1 except that all C5.0 characters are
removed from the data stream.
When the FIFOs are bypassed (FIFOBYP LOW), no characters
are actually discarded, but the receiver discard policy can be
used to control external filtering of the data. The RXEMPTY FIFO
flag is used to indicate if the character on the output bus is valid
or not. In discard policy 0, the RXEMPTY flag is always
deasserted to indicate that valid data is always present. In
discard policy 1, the RXEMPTY flag indicates an empty condition
for all but the last JK or LM character before any other character
is presented. In discard policy 2, the RXEMPTY flag indicates an
empty condition for all JK or LM SYNC characters. When any
other character is present, this flag indicates that valid or “interesting” Data or Special Characters are present.
Receive FIFO
The Receive FIFO is used to buffer data captured from the
selected serial stream for later processing by the host system.
This FIFO is sized to hold 256 14-bit characters. When the FIFO
is enabled, it is written to by the Receive Control State Machine.
When data is present in the Receive FIFO (as indicated by the
RXFULL, RXHALF, and RXEMPTY Receive FIFO status flags),
it can be read from the Output Register by asserting CE and
RXEN.
The read port on the Receive FIFO may be configured for the
same two timing models as the transmit interface: UTOPIA and
Cascade. Both are forms of a FIFO interface. The UTOPIA timing
model has active LOW RXEMPTY and RXFULL status flags, and
an active LOW RXEN enable. When configured for Cascade
operation, these same signals are all active HIGH. Either timing
model supports connection to various host bus interfaces, state
machines, or external FIFOs for depth expansion (see Figure 4)
Document Number: 38-02020 Rev. *H
CY7C42x5 FIFO
EF*
REN*
Q
RXCLK
EF*
REN*
RXEN
FF*
RXEMPTY
WEN*
Q
RCLK
CY7C9689A
RXDATA
RXSC/D
D
RXCLK
WCLK
“1”
EXTFIFO
The Receive FIFO presents Full, Half-Full, and Empty FIFO
status flags. These flags are provided synchronous to RXCLK to
allow operation with a Moore-type external controlling state
machine. When configured with the Receive FIFO enabled,
RXCLK is an input. When the Receive FIFO is bypassed
(FIFOBYP is LOW), RXCLK is an output operating at the
received character rate.
Receive Input Register
The input register is clocked by the rising edge of RXCLK. It
samples numerous signals that control the reading of the
Receive FIFO and operation of the Receive Control State
Machine.
Receive Output Register
The Receive Output Register changes in response to the rising
edge of RXCLK. The Receive FIFO status flag outputs of this
register are placed in a High-Z state when the CY7C9689A is not
addressed (CE is sampled HIGH). The RXDATA bus output
drivers are enabled when the device is selected by RXEN being
asserted in the RXCLK cycle immediately following that in which
the device was addressed (CE is sampled LOW), and RXEN
being sampled by RXCLK. This initiates a Receive FIFO read
cycle.
Just as with the TXDATA bus on the Transmit Input Register, the
receive outputs are also mapped by the specific decoding and
bus-width selected by the ENCBYP, BYTE8/10 and FIFOBYP
inputs. These assignments are shown in Table 6.
If the Receive FIFO and Decoder are bypassed, all received
characters are passed directly to the Receive Output Register. If
framing is enabled, and JK or LM sync characters have been
detected meeting the present framing requirements, the output
characters will appear on proper character boundaries. If framing
is disabled (RFEN is LOW) or sync characters have not been
detected in the data stream, the received characters may not be
output on their proper 10-bit boundaries. In this mode, some form
of external framing and decoding/descrambling must be used to
recover the original source data.
Page 21 of 56
CY7C9689A
Table 6. Receiver Output Bus Signal Map
Receiver Decoder Mode[1]
RXDATA Bus Output Bit
Encoded 8-bit
Character Stream[8]
Pre-encoded 10-bit
Character Stream
Encoded 10-bit
Character Stream[9]
Pre-encoded 12-bit
Character Stream
RXSC/D
RXSC/D
RXDATA[0]
RXDATA[0]
RXD[0][10, 11]
RXDATA[0]
RXD[0][10, 12]
RXDATA[1]
RXDATA[1]
RXD[1]
RXDATA[1]
RXD[1]
RXDATA[2]
RXDATA[2]
RXD[2]
RXDATA[2]
RXD[2]
RXDATA[3]
RXDATA[3]
RXD[3]
RXDATA[3]
RXD[3]
RXDATA[4]
RXDATA[4]
RXD[4]
RXDATA[4]
RXD[4]
RXDATA[5]
RXDATA[5]
RXD[5]
RXDATA[5]
RXD[5]
RXDATA[6]
RXDATA[6]
RXD[6]
RXDATA[6]
RXD[6]
RXDATA[7]
RXDATA[7]
RXD[7]
RXDATA[7]
RXD[7]
RXDATA[8]/RXCMD[3]
RXCMD[3]
RXD[8]
RXDATA[8]
RXD[8]
RXD[9]
RXDATA[9][9]
RXD[9]
RXSC/D
RXDATA[9]/RXCMD[2]
RXCMD[2]
RXCMD[1]
RXCMD[1]
RXCMD[1]
RXD[10][12]
RXCMD[0]
RXCMD[0]
RXCMD[0]
RXD[11]
VLTN
VLTN
VLTN
Notes
8. When BYTE8/10 is HIGH, received bit order is decoded form the serial stream and presented (MSB to LSB) at RXDATA[7,6,5,4] and RXDATA[3,2,1,0] or
RXCMD[3,2,1,0] as indicated by RXSC/D.
9. When BYTE8/10 is LOW, received bit order is decoded form the serial stream and presented (MSB to LSB) at RXDATA[8,7,6,5,4] and RXDATA[9,3,2,1,0] or
RXCMD[1,0] as indicated by RXSC/D.
10. First bit shifted into the receiver.
11. When ENCBYP is LOW and BYTE8/10 is HIGH, the received bit order is (LSB to MSB) RXD[0,1,2,3,4,5,6,7,8,9].
12. When ENCBYP is LOW and BYTE8/10 is LOW, the received bit order is (LSB to MSB) RXD[0,1,2,3,4,5,6,7,8,9,11,10].
Document Number: 38-02020 Rev. *H
Page 22 of 56
CY7C9689A
Maximum Ratings
Static discharge voltage........................................... > 2001 V
(per MIL-STD-883, Method 3015)
(Above which the useful life may be impaired. For user guidelines, not tested.)
Storage temperature ................................ –65 °C to +150 °C
Ambient temperature with (power applied)–55 °C to +125 °C
Supply voltage to ground potential ................–0.5 v to +6.5 v
DC voltage applied to outputs............... –0.5 v to VDD + 0.5 v
Output current into TTL outputs (LOW) ....................... 30 mA
Latch-up current ..................................................... > 200 mA
Operating Range
Range
Ambient Temperature
VDD
0 C to +70 C
5.0 V  10%
–40 C to +85 C
5.0 V  10%
Commercial
Industrial
DC input voltage ................................... –0.5 v to VDD + 0.5 v
CY7C9689A DC Electrical Characteristics
Over the Operating Range
Parameter
Description
Test Conditions
Min.
Max.
Unit
2.4
–
V
TTL Outputs
IOH = 2 mA, VDD = Min.
VOHT
Output HIGH voltage
VOLT
Output LOW voltage
IOL = 8 mA, VDD = Min.
IOST
Output short circuit current
VOUT = 0 V[13]
IOZL
High-Z output leakage current
–
0.4
V
–30
80
mA
–20
20
mA
TTL Inputs
VIHT
Input HIGH voltage
2.0
VCC
V
VILT
Input LOW voltage
–0.5
0.8
V
IIHT
Input HIGH current
VIN = VDD
–
±40
A
IILT
Input LOW current
VIN = 0.0 V
–
40
A
IILPDT
Input HIGH current with internal pull-down
VIN = VCC
–
+300
A
IILPUT
Input LOW current with internal pull-up
VIN = 0.0 V
–300
–
A
Transmitter PECL-Compatible Output Pins: OUTA+, OUTA, OUTB+, OUTB
VOHE
Output HIGH voltage (VDD referenced)
Load = 50  to VDD  1.33 v;
RCURSET = 10 k
VDD 1.03
VDD 0.83
V
VOLE
Output LOW voltage (VDD referenced)
Load = 50  to VDD  1.33 v;
RCURSET = 10 k
VDD 2.0
VDD 1.62
V
VODIF
Output differential voltage |(OUT+)  (OUT)|
Load = 50  to VDD  1.33 v;
RCURSET = 10 k
600
1100
mV
Receiver Single-ended PECL-Compatible Input Pin: CARDET
VIHE
Input HIGH voltage (VDD referenced)
VDD 1.165
VDD
V
VILE
Input LOW voltage (VDD referenced)
2.5
VDD 1.475
V
IIHE
Input HIGH current
VIN = VIHE(min.)
–
+40
IILE
Input LOW current
VIN = VILE(max.)
–40
A
A
Receiver Differential Line Receiver Input Pins: INA+, INA, INB+, INB
VDIFF
Input differential voltage |(IN+)  (IN)|
200
2500
mV
VIHH
Highest input HIGH voltage
–
VDD
V
VILL
Lowest input LOW voltage
2.5
–
V
IIHH
Input HIGH current
VIN = VIHH Max.
–
750
A
IILL[14]
Input LOW current
VIN = VILL Min.
200
–
A
Notes
13. Tested one output at a time, output shorted for less than one second, less than 10% duty cycle.
14. To guarantee positive currents for all PECL voltages, an external pull-down resistor must be present.
Document Number: 38-02020 Rev. *H
Page 23 of 56
CY7C9689A
CY7C9689A DC Electrical Characteristics (continued)
Over the Operating Range
Parameter
Description
Test Conditions
Miscellaneous
IDD[15]
Power supply current
Freq. = Max.
Commercial
Min.
Max.
Typ.
Max.
170
250
Unit
mA
Capacitance[16]
Parameter
Description
Test Conditions
Max.
Unit
CINTTL
TTL input capacitance
TA = 25 C, f0 = 1 MHz, VDD = 5.0 V
7
pF
CINPECL
PECL input capacitance
TA = 25 C, f0 = 1 MHz, VDD = 5.0 V
4
pF
AC Test Loads and Waveforms
5.0 V
R1
OUTPUT
R1=500
R2=333
CL  10 pF
(Includes fixture and
probe capacitance)
VDD – 1.3
CL
CL
R2
(a) TTL AC Test Load
Vth=1.5 v
0.0 V
[17]
3.0 V
3.0 V
RL
2.0 V
0.8 v
(b) PECL AC Test Load
0.8 v
< 1 ns
(c) TTL Input Test Waveform
80%
Vth=1.5 v
VILE
< 1 ns
[17]
VIHE
VIHE
2.0 V
RL =50
CL < 5 pF
(Includes fixture and
probe capacitance)
80%
20%
 250 ps
20%
VILE
 250 ps
(d) PECL Input Test Waveform
Notes
15. Maximum ICC is measured with VDD = MAX, RFEN = LOW, and outputs unloaded. Typical IDD is measured with VDD = 5.0 V, TA = 25 °C, RFEN = LOW, and
outputs unloaded.
16. Tested initially and after any design or process changes that may affect these parameters, but not 100% tested.
17. Cypress uses constant current (ATE) load configurations and forcing functions. This figure is for reference only.
Document Number: 38-02020 Rev. *H
Page 24 of 56
CY7C9689A
CY7C9689A Transmitter TTL Switching Characteristics, FIFO Enabled
Over the Operating Range
Parameter
Description
Min.
Max.
Unit
50
MHz
–
ns
fTS
TXCLK clock cycle frequency with transmit FIFO enabled
tTXCLK
TXCLK period
tTXCPWH
TXCLK HIGH time
6.5
–
ns
tTXCPWL
TXCLK LOW time
6.5
–
ns
tTXCLKR[16]
TXCLK Rise time[18]
0.7
5
ns
tTXCLKF[16]
TXCLK fall time[18]
0.7
5
ns
20
tTXA
Flag access time from TXCLKto Output
2
15
ns
tTXDS
Transmit data set-up time toTXCLK
4
–
ns
tTXDH
Transmit data hold time from TXCLK
1
–
ns
tTXENS
Transmit enable set-up time toTXCLK
4
–
ns
tTXENH
Transmit enable hold time fromTXCLK
1
–
ns
tTXRSS
Transmit FIFO Reset (TXRST) set-up time toTXCLK
4
–
ns
tTXRSH
Transmit FIFO Reset (TXRST hold time fromTXCLK
1
–
ns
tTXCES
Transmit chip enable (CE) set-up time toTXCLK
4
–
ns
tTXCEH
Transmit chip enable (CE) hold time fromTXCLK
1
–
ns
tTXZA
Sample of CE LOW by TXCLK, output high-Z to Active HIGH or LOW
0
–
ns
tTXOE
Sample of CE LOW by TXCLKto output valid
1.5
20
ns
tTXAZ
Sample of CE HIGH by TXCLKto output in high-Z
1.5
20
ns
Notes
18. Input/output rise and fall time is measured between 0.8 V and 2.0 V.
19. Parallel data output specifications are only valid if all outputs are loaded with similar DC and AC loads.
Document Number: 38-02020 Rev. *H
Page 25 of 56
CY7C9689A
CY7C9689A Receiver TTL Switching Characteristics, FIFO Enabled
Over the Operating Range
Parameter
Description
Min.
Max.
Unit
50
MHz
fRIS
RXCLK clock cycle frequency with receive FIFO enabled
tRXCLKIP
RXCLK input period
tRXCPWH
RXCLK input HIGH time
6.5
ns
tRXCPWL
RXCLK input LOW time
6.5
ns
tRXCLKIR[16]
RXCLK input Rise time[20]
0.7
5
ns
tRXCLKIF[16]
RXCLK input Fall time[20]
0.7
5
ns
20
ns
tRXENS
Receive enable set-up time toRXCLK
4
ns
tRXENH
Receive enable hold time fromRXCLK
1
ns
tRXRSS
Receive FIFO reset (RXRXT) set-up time toRXCLK
4
ns
tRXRSH
Receive FIFO reset (RXRXT) hold time fromRXCLK
1
ns
tRXCES
Receive chip enable (CE) set-up time toRXCLK
4
ns
tRXCEH
Receive chip enable (CE) Hold Time fromRXCLK
1
ns
tRXA
Flag and data access time from RXCLKto output
1.5
tRXZA
Sample of CE LOW by RXCLK, Output High-Z to Active HIGH or LOW,[21]
or Sample of RXEN Asserted by RXCLK, Output High-Z to Active HIGH or LOW
tRXOE
Sample of CE LOW by RXCLK to Output Valid,[21]
or Sample of RXEN Asserted by RXCLKto RXDATA Outputs Valid
1.5
20
ns
tRXZA
Sample of CE HIGH by RXCLK to Output in High-Z,[21]
or Sample of RXEN Asserted by RXCLKto RXDATA Outputs in High-Z
1.5
20
ns
15
0
ns
ns
CY7C9689A Transmitter TTL Switching Characteristics, FIFO Bypassed
Over the Operating Range
Min.
Max.
Unit
tTRA
Parameter
Flag access time from REFCLKto output
Description
2
15
ns
tREFDS
Write data set-up time to REFCLK
4
ns
tREFDH
Write data hold time from REFCLK
2
ns
tREFENS
Transmit enable set-up time toREFCLK
4
ns
tREFENH
Transmit enable hold time fromREFCLK
2
ns
tREFCES
Transmit chip enable (CE) set-up time toREFCLK
4
ns
tREFCEH
Transmit chip enable (CE) hold time fromREFCLK
2
ns
tREFZA
Sample of CE LOW by REFCLK, output High-Z to Active HIGH or LOW
tREFOE
Sample of CE LOW by REFCLK to flag output Valid
1.5
20
ns
tREFAZ
Sample of CE HIGH by REFCLK to flag output High-Z
1.5
20
ns
0
ns
Notes
20. Input/output rise and fall time is measured between 0.8 V and 2.0 V.
21. Parallel data output specifications are only valid if all outputs are loaded with similar DC and AC loads.
Document Number: 38-02020 Rev. *H
Page 26 of 56
CY7C9689A
CY7C9689A Receiver TTL Switching Characteristics, FIFO Bypassed
Over the Operating Range
Parameter
fROS[22]
Min.
Max.
Unit
RXCLK clock output frequency—100 to 200 MBaud 8-bit Operation
(SPDSEL is HIGH and BYTE8/10 is HIGH)
Description
10
20
MHz
RXCLK clock output frequency—50 to 100 MBaud 8-bit Operation
(SPDSEL is LOW and BYTE8/10 is HIGH)
5
10
MHz
RXCLK clock output frequency—100 to 200 MBaud 10-bit Operation
(SPDSEL is HIGH and BYTE8/10 is LOW)
8.33
16.67
MHz
RXCLK clock output frequency—50 to 100 MBaud 10-bit Operation
(SPDSEL is LOW and BYTE8/10 is LOW)
4.16
8.33
MHz
25
240
ns
tRXCLKOP
RXCLK output period
tRXCLKOD
RXCLK output duty cycle
40
60
%
tRXCLKOR[16]
RXCLK output rise time[18]
0.25
2
ns
tRXCLKOF[16]
RXCLK output fall time[18]
0.25
2
ns
tRXENS
Receive enable set-up time toRXCLK
4
ns
tRXENH
Receive enable hold time fromRXCLK
1
ns
tRXZA
Sample of CE LOW by RXCLK, Outputs High-Z to Active
Sample of RXEN Asserted by RXCLK to RXDATA Outputs High-Z to Active
0
ns
tRXOE
Sample of CE LOW by RXCLK to Flag Output Valid
Sample of RXEN Asserted by RXCLK to RXDATA Output Low-Z
1.5
20
ns
tRXAZ
Sample of CE HIGH by RXCLK to Flag Output High-Z
Sample of RXEN Deasserted by RXCLK to RXDATA Output High-Z
1.5
20
ns
Note
22. The period of tROS will match the period of the transmitter PLL reference (REFCLK) when receiving serial data. When data is interrupted, RXCLK may drift to REFCLK +0.2%.
Document Number: 38-02020 Rev. *H
Page 27 of 56
CY7C9689A
CY7C9689A REFCLK Input Switching Characteristics
Over the Operating Range
Parameter
fREF
Conditions
Description
Min.
Max.
Unit
0
8.33
16.67
MHz
0
1
10
20
MHz
0
1[18]
0
16.67
33.3
MHz
REFCLK clock frequency—50 to 100 MBaud, 8-bit
Mode, REFCLK = 4x Character Rate
0
1[18]
1
20
40
MHz
REFCLK clock frequency—100 to 200 MBaud,
10-bit Mode, REFCLK = Character Rate
1
0
0
8.33
16.67
MHz
REFCLK clock frequency—100 to 200 MBaud,
8-bit Mode, REFCLK = Character Rate
1
0
1
10
20
MHz
REFCLK clock frequency—100 to 200 MBaud,
10-bit Mode, REFCLK = 2x Character Rate
1
1
0
16.67
33.3
MHz
REFCLK clock frequency—100 to 200 MBaud,
8-bit Mode, REFCLK = 2x Character Rate
1
1
1
20
40
MHz
120
ns
SPDSEL
RANGESEL
BYTE8/10
REFCLK clock frequency—50 to 100 MBaud,
10-bit Mode, REFCLK = 2x Character Rate
0
0
REFCLK clock frequency—50 to 100 MBaud, 8-bit
Mode, REFCLK = 2x Character Rate
0
REFCLK clock frequency—50 to 100 MBaud,
10-bit Mode, REFCLK = 4x Character Rate
tREFCLK
REFCLK period
25
tREFH
REFCLK HIGH time
6.5
tREFL
REFCLK LOW time
tREFRX
REFCLK frequency referenced to received clock period[24]
ns
6.5
0.04
ns
+0.04
%
CY7C9689A Receiver Switching Characteristics
Over the Operating Range
Parameter
tB[25]
Description
Bit time
Max.
Unit
20.0
5.0
ns
600
ps
alignment[16, 26]
tSA
Static
tEFW
Error free window[16, 27, 28]
tIN_J
Min.
IN± peak-to-peak input jitter
0.65
tolerance[16, 27, 29, 30]
UI
0.5
UI
Notes
23. When configured for synchronous operation with the FIFOs bypassed (FIFOBYP is LOW), if RANGESEL is HIGH the SPDSEL input is ignored and operation is
forced to the 100–200 MBaud range.
24. REFCLK has no phase or frequency relationship with RXCLK and only acts as a centering reference to reduce clock synchronization time. REFCLK must be
within 0.04% of the transmitter PLL reference (REFCLK) frequency, necessitating a 200-PPM crystal.
25. The PECL switching threshold is the midpoint between the PECL VOH, and VOL specification (approximately VDD  1.33 v).
26. Static alignment is a measure of the alignment of the Receiver sampling point to the center of a bit. Static alignment is measured by the absolute difference of
the left and right edge shifts (|tSH_L – tSH_R|) of one bit until a character error occurs.
27. Receiver UI (Unit Interval) is calculated as 1/(fREF*N) when operated in 8-bit mode (N = 10) and 10-bit mode (N = 12) if no data is being received, or 1/(fREF*N)
of the remote transmitter if data is being received. In an operating link this is equivalent to N * tB when REFCLK = 1X the character rate. An alternate multiply
ratios (2X or 4X, as selected by SPDSEL and RANGESEL), the numerator is multiplied by 2 or 4 respectively.
28. Error Free Window is a measure of the time window between bit centers where a transition may occur without causing a bit sampling error. EFW is measured
over the operating range, input jitter 50% Dj.
29. The specification is sum of 25% Duty Cycle Distortion (DCD), 10% Data Dependant Jitter (DDJ), 15% Random Jitter (RJ).
30. Parallel data output specifications are only valid if all outputs are loaded with similar DC and AC loads.
Document Number: 38-02020 Rev. *H
Page 28 of 56
CY7C9689A
CY7C9689A Transmitter Switching Characteristics
Over the Operating Range
Parameter
tB[25]
Description
Bit time
[16]
tRISE
PECL output rise time 2080% (PECL Test Load)
tFALL
PECL output fall time 8020% (PECL Test Load)[16]
Min.
Max.
Unit
20.0
5.0
ns
200
1700
ps
200
1700
ps
[16, 31]
tDJ
Deterministic jitter (peak-peak)
0.02
UI
tRJ
Random jitter () [16, 32]
0.008
UI
tJT
Transmitter total output jitter (peak-peak)[16]
0.08
UI
CY7C9689A HOTLink Transmitter Switching Waveforms
Write Cycle
Asynchronous (FIFO) Interface
EXTFIFO = HIGH
tTXCLK
FIFOBYP = HIGH
tTXCPWH
tTXCPWL
TXCLK
tTXDS
TXHALT
TXSC/D
TXDATA[7:0]
TXDATA[9:8]/TXCMD[2:3]
TXCMD[1:0]
tTXDH
Note 33
tTXENH
NO OPERATION
TXEN
tTXENS
tTXA
TXFULL
TXHALF
TXEMPTY
Document Number: 38-02020 Rev. *H
tTXA
Page 29 of 56
CY7C9689A
CY7C9689A HOTLink Transmitter Switching Waveforms
(continued)
Notes
31. While sending continuous JK, outputs loaded to 50 to VDD 1.3 v, over the operating range.
32. While sending continuous HH, after 100,000 samples measured at the cross point of differential outputs, time referenced to REFCLK input, over the operating range.
33. When EXTFIFO is HIGH, the write data is captured on the clock cycle following TXEN = HIGH.
Write Cycle
Asynchronous (FIFO) Interface
EXTFIFO = LOW
FIFOBYP = HIGH
TXCLK
tTXDS
TXHALT
TXSC/D
TXDATA[7:0]
TXDATA[9:8]/TXCMD[2:3]
TXCMD[1:0]
tTXDH
Note 34
tTXENS
tTXENH
TXEN
NO OPERATION
tTXA
TXFULL
TXHALF
TXEMPTY
Document Number: 38-02020 Rev. *H
tTXA
Page 30 of 56
CY7C9689A
CY7C9689A HOTLink Transmitter Switching Waveforms
(continued)
OUTPUT ENABLE Timing
Asynchronous (FIFO) Interface
EXTFIFO = HIGH
FIFOBYP = HIGH
TXCLK
TXHALT
TXSC/D
TXDATA[7:0]
TXDATA[9:8]/TXCMD[2:3]
TXCMD[1:0]
NO OPERATION
TXEN
Note 35
tTXRSS
tTXRSH
TXRST
tTXCES
tTXCEH
CE
tTXOE
tTXOAZ
TXFULL
TXHALF
TXEMPTY
tTXOZA
Notes
34. Illustrates timing only. TXEN and TXRST not usually active in same time period.
35. When transferring data to the Transmitter input from a depth expanded external FIFO, the data is captured from the external FIFO one clock cycle following the
actual enable (TXEN = HIGH).
Document Number: 38-02020 Rev. *H
Page 31 of 56
CY7C9689A
CY7C9689A HOTLink Transmitter Switching Waveforms
(continued)
OUTPUT ENABLE Timing
Asynchronous (FIFO) Interface
EXTFIFO = LOW
FIFOBYP = HIGH
TXCLK
TXHALT
TXSC/D
TXDATA[7:0]
TXDATA[9:8]/TXCMD[2:3]
TXCMD[1:0]
TXEN
NO OPERATION
tTXRSS
CE
TXRST
tTXRSH
Note 34
tTXCES
tTXCEH
CE
TXRST
tTXOE
tTXOAZ
TXFULL
TXHALF
TXEMPTY
tTXOZA
Write Cycle
Synchronous Interface
EXTFIFO = HIGH
FIFOBYP = LOW
tREFCLK
tREFH
tREFL
REFCLK
tREFDS
TXHALT
TXSC/D
TXDATA[7:0]
TXDATA[9:8]/TXCMD[2:3]
TXCMD[1:0]
tREFDH
Note 36
tREFENH
NO OPERATION
TXEN
tREFENS
tTRA
TXFULL
TXHALF
TXEMPTY
tTRA
Note
36. \When transferring data to the Transmitter input from a synchronous external controller, the data is captured in the same clock cycle as the actual enable (TXEN
= LOW).
Document Number: 38-02020 Rev. *H
Page 32 of 56
CY7C9689A
CY7C9689A HOTLink Transmitter Switching Waveforms
(continued)
Write Cycle
Synchronous Interface
EXTFIFO = LOW
FIFOBYP = LOW
REFCLK
tREFDS
TXHALT
TXSC/D
TXDATA[7:0]
XDATA[9:8]/TXCMD[2:3]
TXCMD[1:0]
tREFDH
Note 37
tREFENS
tREFENH
TXEN
NO OPERATION
tTRA
TXFULL
TXHALF
TXEMPTY
OUTPUT ENABLE Timing
Synchronous Interface
EXTFIFO = HIGH
FIFOBYP = LOW
REFCLK
TXHALT
TXSC/D
TXDATA[7:0]
TXDATA[9:8]/TXCMD[2:3]
TXCMD[1:0]
TXEN
tREFENH
NO OPERATION
tREFENS
tREFCES
tREFCEH
CE
tREFOE
tREFAZ
TXFULL
TXEMPTY
tREFZA
Note
37. On inhibited reads, or if the Receive FIFO goes empty, the data outputs do not change.
Document Number: 38-02020 Rev. *H
Page 33 of 56
CY7C9689A
CY7C9689A HOTLink Transmitter Switching Waveforms
(continued)
OUTPUT ENABLE Timing
Synchronous Interface
EXTFIFO = LOW
FIFOBYP = LOW
REFCLK
TXHALT
TXSC/D
TXDATA[7:0]
TXDATA[9:8]/TXCMD[2:3]
TXCMD[1:0]
TXEN
NO OPERATION
CE
TXFULL
TXEMPTY
Document Number: 38-02020 Rev. *H
Page 34 of 56
CY7C9689A
CY7C9689A HOTLink Receiver Switching Waveforms
Read Cycle
Asynchronous (FIFO) Interface
EXTFIFO = HIGH
FIFOBYP = HIGH
tRXCLKOP
tRXCLKIP
tRXCLKOD
tRXCPWH
tRXCLKOD
tRXCPWL
RXCLK
tRXENH
tRXENS
RXEN
NO OPERATION
READ
READ
tRXA
tRXA
RXEMPTY
Note 38
FIFO EMPTY
RXFULL
RXHALF
RXDATA[7:0]
RXDATA[9:8/RXCMD[2:3]
RXCMD[1:0]
VALID DATA
Note 39
CE
Read Cycle
Asynchronous (FIFO) Interface
EXTFIFO = LOW
FIFOBYP = HIGH
RXCLK
tRXENS
RXEN
tRXENH
READ
tRXA
tRXA
FIFO EMPTY
RXEMPTY
RXFULL
RXHALF
RXDATA[7:0]
RXDATA[9:8/RXCMD[2:3]
RXCMD[1:0]
VALID DATA
Note 40
CE
Notes
38. When reading data from synchronous data interface, the data is captured on any clock cycle that RXEN = LOW. RXEMPTY = HIGH indicates data is available.
RXEMPTY = LOW indicates that the FIFO is empty.
39. Illustrates timing only. RXEN and RXRST not usually active in same time period.
40. Receive FIFO Reads are inhibited while the outputs are High-Z.
Document Number: 38-02020 Rev. *H
Page 35 of 56
CY7C9689A
CY7C9689A HOTLink Receiver Switching Waveforms
(continued)
Output Enable Timing
RXCLK
tRXENH
tRXENS
RXEN
NO OPERATION
Note 41
tRXRSH
tRXRSS
RXRST
tRXCES
tRXCEH
CE
tRXAZ
tRXOE
RXFULL
RXDATA[7:0]
RXDATA[9:8/RXCMD[2:3]
RXCMD[1:0]
Note 42
OLD DATA
tRXZA
tREFCLK
tREFL
tREFH
REFCLK
Static Alignment
Error-Free Window
tB/2 tSA
tB/2 tSA
tEFW
INA
INB
INA
INB
tB
BIT CENTER
SAMPLE WINDOW
BIT CENTER
Table 7. HOTLink TAXI-compatible Encoder Patterns
4B/5B Encoder
5B/6B Encoder
HEX
Data
4-bit Binary
Data[43]
5-bit Encoded
Symbol[44, 45]
HEX
Data
5-bit Binary
Data[43]
6-bit Encoded
Symbol[44, 45]
0
0000
11110
00
00000
110110
1
0001
01001
01
00001
010001
Notes
41. Binary Input Data is the parallel input data which is input to the Transmitter and output from the Receiver. Binary bits are listed from left to right in the following
order: 8-Bit mode (BYTE8/10 is HIGH and TXSC/D or RXSC/D is LOW)—TXDATA/RXDATA[7], [6], [5], [4], and TXDATA/RXDATA[3], [2], [1], [0]; 10-Bit mode
(BYTE8/10 is LOW and TXSC/D or RXSC/D is LOW)—TXDATA/RXDATA[8], [7], [6], [5], [4], and TXDATA/RXDATA[9], [3], [2], [1], [0].
42. The ENCODED Symbols are shown here as “ones and zeros”, but are converted to and from an NRZI stream at the transmitter output and receiver input. NRZI
represents a “one” as a state transition (either LOW-to-HIGH or HIGH-to-LOW) and a “zero” as no transition within the bit interval.
43. Encoded Serial Symbol bits are shifted out with the most significant bit (Left-most) of the most significant nibble coming out first.
44. Binary CMD is the parallel input data which is input to the Transmitter and output from the Receiver. Binary bits are listed from left to right in the following order:
8-Bit mode (BYTE8/10 is HIGH and TXSC/D or RXSC/D is HIGH)—TXCMD/RXCMD[3], [2], [1], [0]; 10-Bit mode (BYTE8/10 is LOW and TXSC/D or RXSC/D
is HIGH)—TXCMD/RXCMD[1], [0].
45. While these Commands are legal data and will not disrupt normal operation if used occasionally, they may cause data errors if grouped into recurrent fields.
Normal PLL operation cannot be guaranteed if one or more of these commands is continuously repeated.
Document Number: 38-02020 Rev. *H
Page 36 of 56
CY7C9689A
Table 7. HOTLink TAXI-compatible Encoder Patterns (continued)
4B/5B Encoder
5B/6B Encoder
HEX
Data
4-bit Binary
Data[43]
5-bit Encoded
Symbol[44, 45]
HEX
Data
5-bit Binary
Data[43]
6-bit Encoded
Symbol[44, 45]
2
0010
10100
02
00010
100100
3
0011
10101
03
00011
100101
4
0100
01010
04
00100
010010
5
0101
01011
05
00101
010011
6
0110
01110
06
00110
010110
7
0111
01111
07
00111
010111
8
1000
10010
08
01000
100010
9
1001
10011
09
01001
110001
A
1010
10110
0A
01010
110111
B
1011
10111
0B
01011
100111
C
1100
11010
0C
01100
110010
D
1101
11011
0D
01101
110011
E
1110
11100
0E
01110
110100
F
1111
11101
0F
01111
110101
–
–
–
10
10000
111110
–
–
–
11
10001
011001
–
–
–
12
10010
101001
–
–
–
13
10011
101101
–
–
–
14
10100
011010
–
–
–
15
10101
011011
–
–
–
16
10110
011110
–
–
–
17
10111
011111
–
–
–
18
10001
101010
–
–
–
19
11001
101011
–
–
–
1A
11010
101110
–
–
–
1B
11011
101111
–
–
–
1C
11100
111010
–
–
–
1D
11101
111011
–
–
–
1E
11110
111100
–
–
–
1F
11111
111101
Table 8. HOTLink TAXI Compatible Command Symbols
CY7C9689A (Transmitter)
CY7C9689A (Receiver)
Command Input
TXCMD[3:0]
Command Output
RXCMD[3:0]
HEX
Binary CMD[46]
Encoded
Symbol[44, 45]
Mnemonic
HEX
Binary CMD[46]
11000 10001
JK (8-bit SYNC)
0
0000
8-bit mode (BYTE8/10 is HIGH)
0
0000
Note
46. Signals labeled in italics are internal to the CY7C9689A.
Document Number: 38-02020 Rev. *H
Page 37 of 56
CY7C9689A
Table 8. HOTLink TAXI Compatible Command Symbols (continued)
CY7C9689A (Transmitter)
CY7C9689A (Receiver)
Command Input
TXCMD[3:0]
Command Output
RXCMD[3:0]
1
0001
11111 11111
II
1
0001
2
0010
01101 01101
TT
2
0010
3
0011
01101 11001
TS
3
0011
4
0100
11111 00100
IH
4
0100
5
0101
01101 00111
TR
5
0101
6
0110
11001 00111
SR
6
0110
7
0111
11001 11001
SS
7
0111
8[47]
1000
00100 00100
HH
8
1000
9[47]
1001
00100 11111
HI
9
1001
A[47]
1010
00100 00000
HQ
A
1010
B
1011
00111 00111
RR
B
1011
C
1100
00111 11001
RS
C
1100
D[47]
1101
00000 00100
QH
D
1101
E[47]
1110
00000 11111
QI
E
1110
F[47]
1111
00000 00000
QQ
F
1111
10-bit mode (BYTE8/10 is LOW)
0
00
011000 100011
LM (10-bit SYNC)
0
00
1
01
111111 111111
I’I’
1
01
2
10
011101 011101
T’T’
2
10
3
11
011101 111001
T’S’
3
11
Functional Description
The interconnection of two or more CY7C9689A Transceivers
forms a general-purpose communications subsystem capable of
transporting user data at up to 20 MBytes per second over
several types of serial interface media. The CY7C9689A is highly
configurable with multiple modes of operation.
In the transmit section of the CY7C9689A, data moves from the
input register, through the Transmit FIFO, to the 4B/5B Encoder.
The encoded data is then shifted serially out the OUTx±
differential PECL compatible drivers. The bit-rate clock is
generated internally from a 2.5x, 5x, or 10x PLL clock multiplier.
A more complete description is found in the section CY7C9689A
HOTLink Transmit-Path Operating Mode Description.
In the receive section of the CY7C9689A, serial data is sampled
by the receiver on one of the INx± differential line receiver inputs.
The receiver clock and data recovery PLL locks onto the selected
serial bit stream and generates an internal bit-rate sample clock.
The bit stream is deserialized, decoded, and presented to the
Receive FIFO, along with a character clock. The data in the FIFO
can then be read either slower or faster than the incoming
character rate. A more complete description is found in the
section CY7C9689A HOTLink Receive-Path Operating Mode
Description.
The Transmitter and Receiver parallel interface timing and
functionality can be configured to Cascade directly to external
FIFOs for depth expansion, couple directly to registers, or couple
directly to state machines. These interfaces can accept or output
either:
■
8-bit characters
■
10-bit characters
■
10-bit pre-encoded characters (pre-scrambled or
pre-encoded)
■
12-bit pre-encoded characters (pre-scrambled or
pre-encoded).
The bit numbering and content of the parallel transmit interface
is shown in Table 1. When operated with the 4B/5B, 5B/6B
Encoder bypassed, the TXSC/D and RXSC/D bits are ignored.
The HOTLink Transceiver serial interface provides a seamless
interface to various types of media. A minimal number of external
passive components are required to properly terminate transmission lines and provide LVPECL loads. For power supply
decoupling, a single capacitor (in the range of 0.02 F to 0.1 F)
is required per power/ground pair. Additional information on
interfacing these components to various media can be found in
the HOTLink Design Considerations application note.
Note
47. Signals shown as dotted lines represent the differences in timing and active state of signals when operated in Cascade Timing.
Document Number: 38-02020 Rev. *H
Page 38 of 56
CY7C9689A
CY7C9689A TAXI HOTLink Transmit-Path
Operating Mode Descriptions
at every rising edge of the REFCLK (along with TXEN) to
maintain the data stream. If TXEN is not asserted, the Serializer
is loaded with JK or LM sync characters.
The TAXI HOTLink Transmitter can be configured into several
operating modes, each providing different capabilities and fitting
different transmission needs. These modes are selected using
the FIFOBYP, ENCBYP and BYTE8/10 inputs on the
CY7C9689A Transceiver. These modes can be reduced to five
primary classes:
In this mode the LSB of each input character (TXDATA[0]) is
shifted out first, followed sequentially by TXDATA[1] through
TXDATA[9] (TXDATA[11] when BYTE8/10 is LOW).
■
Synchronous Encoded
■
Synchronous Pre-encoded
■
Asynchronous Encoded
■
Asynchronous Pre-encoded.
Synchronous Encoded
In this mode, the Transmit FIFO is bypassed, while the 4B/5B,
5B/6B encoder is enabled. One character is accepted at the
Transmit Input Register at the rising edge of REFCLK, and
passed to the Encoder where it is encoded for serial transmission. The Serializer operates synchronous to REFCLK,
which is multiplied by 10 or 5 to generate the serial data bit-clock.
In this mode the TXRST and TXHALT inputs are not interpreted
and may be tied either HIGH or LOW. To place the CY7C9689A
into synchronous modes, FIFOBYP must be LOW.
This mode is usually used for products that must meet specific
predefined protocol requirements, and cannot tolerate the
uncontrolled insertion of SYNC fill characters. The host system
is required to provide new data at every rising edge of REFCLK
(along with TXEN) to maintain the data stream. If TXEN is not
asserted, the Encoder is loaded with JK or LM sync characters.
Input Register Mapping
In Encoded modes, the bits of the TXDATA input bus are mapped
into characters (as shown in Table 1), including a TXSVS bit,
eight bits of data, and a TXSC/D bit to select either Special
Character codes or Data characters.
The TXSC/D bit controls the encoding of the TXDATA[7:0] or
TXDATA[9:0] bits of each character. It is used to identify if the
input character represents a Data Character or a Special
Character code. If TXSC/D is LOW, the character appeared on
the TXDATA bus is encoded using the Data Character codes
listed in Table 7. If TXSC/D is HIGH, the character on the
TXCMD bus is encoded using the Special Character codes listed
in Table 8.
Synchronous Pre-encoded
In synchronous pre-encoded mode, both the Transmit FIFO and
the 4B/5B encoder are bypassed, and data passes directly from
the Transmit Input Register to the Serializer. The Serializer
operates synchronous to REFCLK, which is multiplied by 10 or
5 when BYTE8/10 is HIGH (as selected by the SPDSEL and
RANGESEL inputs) to generate the serial data bit-clock. In this
mode, part of the TXCMD bus inputs are used as part of the data
input bus. To place the CY7C9689A into synchronous modes,
FIFOBYP must be LOW.
This mode is usually used for products containing external
encoders or scramblers, that must meet specific protocol
requirements. The host system is required to provide new data
Document Number: 38-02020 Rev. *H
Asynchronous Encoded
In Asynchronous Encoded mode, both the Transmit FIFO and
the Encoder are enabled. This provides 256 characters of data
buffering. The Serializer operates synchronous to REFCLK,
which is multiplied by 2.5, 5, or 10 to generate the serial data
bit-clock (as selected by SPDSEL and RANGESEL). In this
mode the TXRST and TXHALT inputs are interpreted.
This mode supports the same Input Register mapping as
Synchronous Encoded mode. Because both the Transmit FIFO
and Encoder are enabled, the input FIFO may be loaded at any
rate supported by the FIFO (up to 50 MHz), without generating
any decoder errors at the receive end of the link.
CY7C9689A TAXI HOTLink Receive-Path
Operating Mode Descriptions
The HOTLink Receiver can be configured into several operating
modes, each providing different capabilities and fitting different
reception needs. These modes are selected using the FIFOBYP,
ENCBYP, BYTE8/10 inputs on the CY7C9689A Transceiver.
These modes can be reduced to four primary classes:
■
Synchronous Decoded
■
Synchronous Undecoded
■
Asynchronous Decoded
■
Asynchronous Undecoded.
In all these modes, serial data is received at one of the differential
line receiver inputs and routed to the Deserializer and Framer.
The PLL in the clock and data recovery block is used to extract
a bit-rate clock from the transitions in the data stream, and uses
that clock to capture bits from the serial stream. These bits are
passed to the Deserializer where they are formed into 10- or
12-bit characters.
To align the incoming bit stream to the proper character boundaries, the Framer must be enabled by asserting RFEN HIGH.
The Framer logic-block checks the incoming bit stream for the
unique pattern that defines the character boundaries. This logic
filter looks for the JK or LM (when BYTE8/10 is LOW) sync
character. Once a sync character is found, the Framer captures
the offset of the data stream from the present character boundaries, and resets the boundary to reflect this new offset, thus
framing the data to the correct character boundaries.
Since noise induced errors can cause the incoming data to be
corrupted, and since many combinations of corrupt and legal
data can create an aliased sync character, the framer may also
be disabled by deasserting RFEN LOW.
Synchronous Decoded
In these modes, the Receive FIFO is bypassed, while the 5B/4B,
6B/5B Decoder is enabled. Framed characters output from the
Deserializer are decoded, and passed directly to the Receive
Output Register. The Deserializer operates synchronous to the
recovered bit-clock, which is divided by 10, generate the output
Page 39 of 56
CY7C9689A
RXCLK clock. In this mode the RXRST input is not interpreted
and may be biased either HIGH or LOW.
These modes are usually used for products that must meet
specific protocol requirements. New decoded characters are
provided at the RXDATA outputs once every rising edge of
RXCLK. If RXEMPTY is asserted LOW, the characters on the
RXCMD output register is a JK or LM sync character, and the
discard policy is set to non-0. Because the decoder is now
enabled, all received characters are checked for compliance to
the 4B/5B decoding rules.
Output Register Mapping
The RXDATA[11:0] output bus is mapped into a character
consisting of eight bits of data and four bits of command, or ten
bits of data and two bits of command. An accompanying RXSC/D
bit identifies the character as either command or data.
The Violation (VLTN) output indicates a code violation has
occurred. When the VLTN output is asserted HIGH, this indicates
a transmission error is detected in the character at the current
transfer clock cycle.
Synchronous Undecoded
In this mode, both the Receive FIFO and the 5B/4B, 6B/5B
Decoder are bypassed, and data passes directly from the Deserializer to the output register. The Deserializer operates
synchronous to the recovered bit-clock, which is divided by 10 to
generate the output RXCLK clock. In this mode the RXRST input
is not interpreted and may be biased either HIGH or LOW.
This mode is usually used for products containing external
decoders or descramblers that must meet specific protocol
requirements. New data is provided at the RXDATA outputs once
every rising edge of RXCLK. Received characters are not
checked for any specific coding requirements and no decoding
errors are reported.
Asynchronous Decoded
In Asynchronous Decoded mode, both the Receive FIFO and the
Decoder of the CY7C9689A are enabled. The deserializer
operates synchronous to the recovered bit-clock, which is
divided by 10 to generate the Receive FIFO write clock.
Characters are read from the Receive FIFO, using the external
RXCLK input, when addressed by CE and selected by RXEN. In
this mode the RXRST input is interpreted.
Asynchronous Decoded mode supports the same Output
Register mapping as the Synchronous Decoded mode. Because
Document Number: 38-02020 Rev. *H
both the Receive FIFO and Decoder are enabled, the output
FIFO may be read at any rate supported by the FIFO, however,
if the Receive FIFO ever indicates a full condition (RXFULL is
asserted), data may be lost.
Asynchronous Undecoded
In Asynchronous Undecoded modes, the Receive FIFO is
enabled. This means that all characters received from the serial
interface are written to the Receive FIFO before being passed to
the output register. The Deserializer operates synchronous to
the recovered bit-clock, which is divided by 10 (or 12) to generate
the Receive FIFO write clock. Data is read from the Receive
FIFO, using the RXCLK input clock, when addressed by CE and
selected by RXEN.
These modes are usually used for products containing external
decoders or descramblers, that must meet specific protocol
requirements. New data may be read from the Receive FIFO any
time that the FIFO status flags indicate a non-empty condition
(RXEMPTY is deasserted). To ensure that data is not lost, the
Receive FIFO must be read faster than data is loaded into the
Receive FIFO.
If the receiver is to provide framed characters, it is necessary for
the transmit end to include JK or LM sync characters in the data
stream. This can be done by:
■
operating the transmitter in encoded mode and writing JK or
LM characters into the data stream
■
operating the transmitter in pre-encoded mode and writing the
10-bit value for an encoded JK (1100010001) or LM
(011000100011) character to the data stream
■
not enabling the transmitter when it is operated in synchronous
mode, or by allowing the transit FIFO to go empty when it is
operated in asynchronous mode.
BIST Operation and Reporting
The CY7C9689ADX HOTLink Transceiver incorporates the
same Built-In Self-Test (BIST) capability. This link diagnostic
uses a Linear Feedback Shift Register (LFSR) to generate a
511-character repeating sequence that is compared,
character-for-character, at the receiver.
BIST mode is intended to check the entire high-speed serial link
at full link-speed, without the use of specialized and expensive
test equipment. The complete sequence of characters used in
BIST are documented in Table 4.
Page 40 of 56
CY7C9689A
Figure 5. Built-In Self-Test Illustration
TXCLK
TXBISTEN
TXEMPTY
TXHALF
TXFULL
Enable TX BIST
BIST
LOOP
REFCLK
LOW to enable FIFO Flags
LOW to enable VLTN reads
Ignore these outputs
ERROR
Start of RX
BIST Wait
Forced to indicate EMPTY by BIST
BIST
LOOP
Enable RX BIST
BIST Enable Inputs
There are separate BIST enable inputs for the transmit and
receive paths of the CY7C9689A. These inputs are both active
LOW; i.e., BIST is enabled in its respective section of the device
when the BIST enable input is determined to be at a logic-0 level.
Both BIST enable inputs are asynchronous; i.e., they are
synchronized inside the CY7C9689A to the internal state
machines.
BIST Transmit Path
OUTB
TXCMD[1:0]
TXSC/D
TXDATA[9:0]
TXEN
Don’t Care
Start of RX
BIST match
OUTA
CE
RXEN
RXDATA[9:0]
RXSC/D
RXCMD[1:0]
VLTN
RXEMPTY
RXHALF
RXFULL
RXBISTEN
RXCLK
CY7C9689A
Start of TX BIST
INA
INB
A/B
HIGH to select A
maximum limit while the BIST operation takes place. To allow
removal of stale data from the Transmit FIFO, it may also be
reset during a BIST operation. The reset operation proceeds as
documented, with the exception of the information presented on
the TXEMPTY FIFO status flag. Since this flag is used to present
BIST loop status, it continues to reflect the state of the transmit
BIST loop status until TXBISTEN is no longer recognized internally. The completion of the reset operation may still be
monitored through the TXFULL FIFO status flag.
The TXEMPTY flag, when used for transmit BIST progress
indication, continues to reflect the active HIGH or active LOW
settings determined by the UTOPIA or Cascade timing model
selected by EXTFIFO; i.e., when configured for the Cascade
timing model, the TXEMPTY and TXFULL FIFO flags are active
HIGH, when configured for the UTOPIA timing model the
TXEMPTY and TXFULL FIFO flags are active LOW. The illustration in Figure 5 uses the UTOPIA conventions.
The transmit path operation with BIST is controlled by the
TXBISTEN input and overrides most other inputs (see Figure 5).
When the Transmit FIFO is enabled (not bypassed) and
TXBISTEN is recognized internally, all reads from the Transmit
FIFO are suspended and the BIST generator is enabled to
sequence out the 511 character repeating BIST sequence. If the
recognition occurs in the middle of a data field, the following data
is not transmitted at that time, but remains in the Transmit FIFO.
Once the TXBISTEN signal is removed, the data in the Transmit
FIFO is again available for transmission. To ensure proper data
handling at the destination, the transmit host controller should
either use TXHALT to prevent transmission of data at specific
boundaries, or allow the Transmit FIFO to completely empty
before enabling BIST.
When TXBISTEN is first recognized, the TXEMPTY flag is
clocked to a reset state, regardless of the addressed state of the
Transmit FIFO (if CE is LOW or not), but is not driven out of the
part unless CE has been sampled asserted (LOW). Following
this, on each completed pass through the BIST loop, the
TXEMPTY flag is set for one interface clock period (TXCLK or
REFCLK).
With transmit BIST enabled, the Transmit FIFO remains
available for loading of data. It may be written up to its normal
The TXEMPTY flag remains set until the interface is addressed
and the state of TXEMPTY has been observed. If the device is
Document Number: 38-02020 Rev. *H
Page 41 of 56
CY7C9689A
not addressed (CE is not sampled LOW), the flag remains set
internally regardless of the number of TXCLK clock cycles that
are processed. If the device status is not polled on a sufficiently
regular basis, it is possible for the host system to miss one or
more of these BIST loop indications.
A pass through the loop is defined as that condition where the
Encoder generates the 0x00 (where 0x denotes Hex number,
e.g. 0x00 denotes HEX00) state. Depending on the initial state
of the BIST LFSR, the first pass through the loop may occur at
substantially less than 511 character periods. Following the first
pass, as long as TXBISTEN remains LOW, all remaining passes
are exactly 511 characters in length.
When the Transmit FIFO is bypassed, the interface is clocked by
the REFCLK signal instead of TXCLK. While the active or
asserted state of the TXEMPTY signal is still controlled by the
EXTFIFO, the state of any completed BIST loops is no longer
preserved. Instead, the TXEMPTY flag reflects the dynamic state
of the BIST loop progress, and is asserted only once every 511
character periods. If the interface is not addressed at the time
that this occurs, then the FIFO status flags remain in a high-Z
state and the loop event is lost.
BIST Receive Path
The receive path operation in BIST is similar to that of the
transmit path. While the Receive FIFO is enabled (not bypassed)
and RXBISTEN is recognized internally, all writes to the Receive
FIFO are suspended.
Any data present in the Receive FIFO when RXBISTEN is recognized remains in the FIFO and cannot be read until the BIST
operation is complete. The data in the Receive FIFO remains
valid, but is NOT available for reading through the host parallel
interface. This is because the error output indicator for receive
BIST operations is the VLTN signal, which is normally part of the
RXDATA bus. To prevent read operations while BIST is in
operation, the RXEMPTY and RXHALF flags are forced to
indicate an Empty condition. Once RXBISTEN has been
removed and recognized internally, the Receive FIFO status
flags are updated to reflect the current content status of the
Receive FIFO.
To allow removal of stale data from the Receive FIFO, it may be
reset during a BIST operation. The reset operation proceeds as
documented, with the exception that the RXEMPTY and
RXHALF status flags already indicate an empty condition. The
RXFULL flag is used to present BIST progress. The active
(asserted) state on RXFULL (and RXEMPTY) remain controlled
by the present operating mode and interface timing model
(UTOPIA or Cascade).
When RXBISTEN has been recognized, RXFULL becomes the
receive BIST loop indicator (regardless of the logic state of
FIFOBYP). When RXBISTEN is first recognized, the RXFULL
flag is clocked to a set state, regardless of the addressed state
of the Receive FIFO (if CE is sampled LOW or not). Following
this, RXFULL remains set until the receiver detects the start of
the BIST pattern. Then RXFULL is deasserted for the duration of
the BIST pattern, pulsing asserted for one RXCLK period on the
last symbol of each BIST loop. If 14 of 28 consecutive characters
are received in error, RXFULL returns to the set state until the
start of a BIST sequence is again detected.
Document Number: 38-02020 Rev. *H
Just like the BIST status flag on the transmit data path, the
RXFULL flag captures the asserted states, and keeps them until
they are read. This means that if the status flag is not read on a
regular basis, events may be lost.
The detection of errors is presented on the VLTN output. Unlike
the RXFULL FIFO status flag, the active state of this output is not
controlled by the EXTFIFO input. With the Receive FIFO
enabled, these outputs should operate the same as the RXFULL
flag, with respect to preserving the detection state of an error
until it is read.
Unlike the RXFULL flag, which only needs the CY7C9689A to be
addressed (CE sampled LOW by RXCLK) to enable the RXFULL
three-state driver, and an RXCLK to “read” the flag, the VLTN
output requires a selection (assertion of RXEN while addressed)
to enable the RXDATA bus three-state drivers. The selection
process is necessary to ensure that a multi-PHY implementation
does not enable multiple VLTN drivers at the same time.
When the Receive FIFO is bypassed, the interface is clocked by
the RXCLK output signal. While the active or asserted state of
the RXFULL signal is still controlled by the EXTFIFO input, the
state of any completed BIST loops or detected errors are no
longer preserved. Instead, the RXFULL flag reflects the dynamic
state of the BIST loop progress, and is asserted only once every
511 character periods. If the interface is not addressed at the
time that this occurs, then the FIFO status flags remain in a
high-Z state and the loop event is lost. This is also true of the
VLTN output, such that if the CY7C9689A receive path is not
selected to enable the RXDATA bus three-state drivers, the
detection of a BIST miscompare is lost.
BIST Three-state Control
When BIST is enabled on either the transmitter or the receiver,
the three-state enable signals for the BIST status flags and error
indicators work the same as for normal data processing. The
output drivers for the BIST status that is presented on FIFO
status flags are only enabled when CE has been sampled
asserted (LOW) by the respective clock (TXCLK, RXCLK, or
REFCLK).
To access the BIST error information, it is necessary to perform
a read cycle of the addressed receiver. This means that CE must
be LOW to enable the receiver (Rx_Match), and RXEN must be
asserted from HIGH to LOW to select the device. Because the
part is in BIST, no data is read from the FIFO, but the data bus is
driven. This allows the VLTN indicator to be driven onto the
RXDATA bus. So long as RXEN remains asserted, the receiver
stays selected, the data bus remains driven, and VLTN has
meaning.
Bus Interfacing
The parallel transmit and receive host interfaces to the
CY7C9689A are configurable for either synchronous or
asynchronous operation. Each of these configurations supports
two selectable timing and control models of Shared Bus or
Cascade.
All asynchronous bus configurations have the internal Transmit
and Receive FIFOs enabled. This allows data to be written or
read from these FIFOs at any rate up to the maximum 50-MHz
clock rate of the FIFOs. All internal operations of the
CY7C9689A do not use the external TXCLK or RXCLK, but
Page 42 of 56
CY7C9689A
instead make use of synthesized derivatives of REFCLK for
transmit path operations and a recovered character clock for
receive path operations.
All synchronous bus configurations require the bus interface
operations to be synchronous to REFCLK on the transmit path
and the recovered clock (output as RXCLK) on the receive path.
The internal FIFOs are bypassed in all synchronous modes.
The two supported timing and control models are Shared Bus
and Cascade. The Shared Bus is based on the timing model of
a FIFO with active LOW FIFO status flags and read/write
enables.
The Cascade timing model is a modification of the Shared Bus
model that changes the flags and FIFO read/write enables to
active HIGH. This model is present primarily to allow depth
expansion of the internal FIFO by direct coupling to external
CY7C42x5 synchronous FIFOs. To allow this direct coupling, the
cycle-to-cycle timing between the transmit and receive enables
(TXEN and RXEN) are also modified to ensure correct data
transfer.
These four configurations of bus operation and timing/control
can all be used with or without external FIFOs. Depending on the
specific mode selected, the amount of external hardware
necessary to properly couple the CY7C9689A to state machines
or external FIFOs is minimal in all cases, and may be zero if the
proper configuration is selected.
With only minor exceptions, all configurations of the CY7C9689A
in the Shared Bus mode borrowed concepts from the ATM
Forum’s UTOPIA Bus operation. concepts of addressing and
selection to control the enabled/disabled state of the output
drivers, and when data can be written to or read from the part.
Shared Bus Interface Concept
The CY7C9689A Parallel Interface is designed for interfacing to
a Shared Bus. The maximum TXCLK and RXCLK frequency is
50 MHz, which provides a total bandwidth of 50Million characters
per second in each direction. More than two CY7C9689A can be
serviced on the same bus at full serial line speed.
The CY7C9689A is designed to be the Slave in Master-Slave
type of shared bus architecture. Generally, the bus Master (a
Medium Access Device, MAC) is a higher layer device that
sources out going data/command and sinks incoming
data/command to/from Slaves (CY7C9689A) on the shared bus
(see Figure 6)
Figure 6. Shared Bus Architecture
The data bus (TXDATA, RXDATA), command bus (TXCMD,
RXCMD) and FIFO status flags (TXFULL, RXEMPTY, etc.) of
each CY7C9689A on the shared bus can be connected together
respectively. Each Slave can be assigned an address. The
address of each Slave can be decoded by a decoder which
drives the CE input of each Slave. The bus Master will poll each
Slave by selecting (or “Addressing”) the device, and sample the
FIFO flags. Depending on the FIFOs status on each Slave
device, the Master can schedule read accesses to Slaves which
have data in the RXFIFOs, and write accesses to Slaves which
have room in the TXFIFOs. While data is being transferred on
the data/command bus, the bus Master can continue to poll each
Slave device independently.
Device Selection
All actions on the Shared Bus interface are controlled by the Chip
Enable and selection states of the interface. These states control
the read and write access to the Receive and Transmit FIFOs,
access to the FIFO status flags, reset of the Transmit and
Receive FIFOs, and read and write access to the Serial Address
Register. The CY7C9689A supports the concept of an “address
match” through a single Chip Enable (CE) input.
Address Match and FIFO Flag Access
The CY7C9689A makes use of a single active-LOW Chip Enable
(CE) to generate address-match conditions. This allows multiple
CY7C9689A devices to share a common bus, with device output
three-state controls being managed by either an address match
condition (CE sampled LOW), or by a selection state.
The Transmit and Receive FIFO flag output drivers are enabled
in any TXCLK, REFCLK, or RXCLK cycle following CE being
sampled asserted (LOW) by the rising edge of the respective
clock. The CE input is sampled separately by the clocks for the
transmit and receive interfaces, which allows these clocks to be
both asynchronous to each other, and to operate at different
clock rates. An example of both Transmit and Receive FIFO flag
access is shown in Figure 7
Figure 7. FIFO Flag Driver Enables.
TXCLK
CE
TXFULL
Bus
Master
Transmit Port Addressing
CEn
CE1
CE2
CY7C9689A
Valid
CY7C9689A
RXCLK
TXDATA/TXCMD
RXDATA/RXCMD
Status, Control
............
CE
CY7C9689A
RXEMPTY
Valid
Receive Port Addressing
Document Number: 38-02020 Rev. *H
Page 43 of 56
CY7C9689A
When the Transmit FIFO is enabled (FIFOBYP is HIGH) and CE
is sampled LOW by the rising edge of TXCLK, the output drivers
for the TXFULL and TXEMPTY FIFO flags are enabled. When
CE is sampled HIGH by the rising edge of TXCLK, these same
output drivers are disabled.
All normal forms of selection require that an Chip Enable must
be asserted (CE sampled LOW) either at the same time as the
selection control signal being sampled asserted, or one or more
clock cycles prior to the selection control signal being sampled
asserted.
When the Transmit FIFO is bypassed (FIFOBYP is LOW and not
in byte-packed mode) and CE is sampled LOW by the rising
edge of REFCLK, the output drivers for the TXFULL and
TXEMPTY FIFO flags are enabled. When CE is sampled HIGH
by the rising edge of REFCLK, the FIFO flag output drivers are
disabled.
Transmit Data Selection
When CE is sampled LOW by the rising edge of RXCLK (input
or output), the output drivers for the RXFULL and RXEMPTY
FIFO flags are enabled. When CE is sampled HIGH by the rising
edge of RXCLK, the FIFO flag output drivers are disabled.
Device Selection
The concept of selection is used to control the access to the
transmit and receive parallel-data ports of the device. There are
three primary types of selection:
■
Transmit data selection (with and without internal Transmit
FIFO)
■
Receive data selection (with and without internal Receive
FIFO)
■
Continuous selection (for either or both transmit and receive
interfaces).
In addition to these normal selection types, there are two
additional sequences that are used to control the internal
Transmit and Receive FIFOs reset operations, and to control
read/write access to the Serial Address Register:
■
Transmit reset sequence
■
Receive reset sequence.
Of these operations, the transmit data selection and transmit
reset sequence are mutually exclusive and cannot exist at the
same time. The receive data selection and receive reset
sequence are also mutually exclusive and cannot exist at the
same time. Either transmit operation can exist at the same time
as either receive operation.
Document Number: 38-02020 Rev. *H
Asynchronous With Shared Bus Timing and Control
(Transmit FIFO Enabled)
When CE is sampled LOW and TXRST is sampled HIGH by the
rising edge of TXCLK, a Tx_Match condition is generated. This
Tx_Match condition continues until CE is sampled HIGH or
TXRST is sampled LOW at the rising edge of TXCLK. When a
Tx_Match (or Tx_RstMatch) condition is present, the TXEMPTY
and TXFULL output drivers are enabled. When a Tx_Match (or
Tx_RstMatch) condition is not present, these same drivers are
disabled (High-Z).
The selection state of the Transmit FIFO is entered when a
Tx_Match condition is present, and TXEN transitions from HIGH
to LOW. Once selected, the Transmit FIFO remains selected
until TXEN is sampled HIGH by the rising edge of TXCLK. In the
selected state, data present on the TXDATA inputs is captured
and stored in the Transmit FIFO. This transmit interface selection
process is shown in Figure 8.
Synchronous With Shared Bus Timing and Control
(Transmit FIFO Bypassed)
When the Transmit FIFO is bypassed (FIFOBYP is LOW and not
in byte-packed mode), the CY7C9689A must still be selected to
write data into the Transmit Input Register.
When CE is sampled LOW and TXRST is sampled HIGH by the
rising edge of REFCLK, a Tx_Match condition is generated. This
Tx_Match condition continues until CE is sampled HIGH or
TXRST is sampled LOW at the rising edge of REFCLK. When a
Tx_Match (or Tx_RstMatch) condition is present, the TXEMPTY
and TXFULL output drivers are enabled (with the Transmit FIFO
bypassed, the status flags normally indicate an Empty condition).
When a Tx_Match (or Tx_RstMatch) condition is not present,
these same drivers are disabled (High-Z).
Page 44 of 56
CY7C9689A
Figure 8. Transmit Selection with Transmit FIFO Enabled
TXCLK
TXRST
CE
[48]
Tx_Match
Note 49
TXEN
Tx_Selected
[48]
TXDATA/TXCMD
D1
(Shared Bus Timing)
TXDATA/TXCMD
(Cascade Timing)
TXFULL
Not Full
D2
D3
D1
D2
D3
Not Full
Note 49
The selection state of the Transmit Input Register is entered
when a Tx_Match condition is present, and TXEN transitions
from HIGH to LOW. Once selected, the transmit input register
remains selected until TXEN is sampled HIGH by the rising edge
of REFCLK. In the selected state, data present on the TXDATA
inputs is captured in the Transmit Input Register and passed to
the Serializer or Encoder (as selected by the ENCBYP input).
This transmit interface selection process is shown in Figure 9.
When the 4B/5B Encoder is enabled and data is not written to
the Transmit Input Register, the data stream is automatically
padded with JK or LM SYNC characters. When the 4B/5B, 5B/6B
Encoder is disabled and no data is written to the Transmit Input
Register, JK or LM SYNC characters are also automatically
padded with SYNC characters.
Receive Data Selection
Asynchronous With Shared Bus Timing and Control
(Receive FIFO Enabled)
When CE is sampled LOW and RXRST is sampled HIGH by the
rising edge of RXCLK input, an Rx_Match condition is
generated. This Rx_Match condition continues until CE is
sampled HIGH or RXRST is sampled LOW at the rising edge of
RXCLK input. When an Rx_Match (or Rx_RstMatch) condition is
present, the RXEMPTY and RXFULL output drivers are enabled.
When an Rx_Match (or Rx_RstMatch) condition is not present,
these same drivers are disabled (High-Z).
The selection state of the Receive FIFO is entered when an
Rx_Match condition is present, and RXEN transitions from HIGH
to LOW. Once selected, the Receive FIFO remains selected until
RXEN is sampled HIGH by the rising edge of RXCLK input. The
selected state initiates a read cycle from the Receive FIFO and
enables the Receive FIFO data onto the RXDATA bus. This
receive interface selection process is shown in Figure 10
Notes
48. Signal names listed in italics are internal signals, shown for reference only.
49. Signals shown as dotted lines indicate timing and levels when configured for external FIFOs (EXTFIFO is HIGH).
Document Number: 38-02020 Rev. *H
Page 45 of 56
CY7C9689A
Figure 9. Transmit Selection with Transmit FIFO Bypassed
REFCLK
TXRST
CE
Tx_Match
[48]
Note 49
TXEN
Tx_Selected
[48]
TXDATA/TXCMD
D1
(Shared Bus Timing)
TXDATA/TXCMD
(Cascade Timing)
TXFULL
Not Full
D2
D3
D1
D2
D3
Not Full
Note 49
Synchronous With UTOPIA Timing and Control
(Receive FIFO Bypassed)
When the Receive FIFO is bypassed (FIFOBYP is LOW), the
CY7C9689A must still be selected to enable the output drivers
for the RXDATA bus. With the Receive FIFO bypassed, RXCLK
becomes a synchronous output clock operating at the character
rate.
When CE is sampled LOW and RXRST is sampled HIGH by the
rising edge of RXCLK output, an Rx_Match condition is
generated. This Rx_Match condition continues until CE is
sampled HIGH or RXRST is sampled LOW at the rising edge of
RXCLK.
When an Rx_Match (or Rx_RstMatch) condition is present, the
RXEMPTY and RXFULL output drivers are enabled. With the
Document Number: 38-02020 Rev. *H
Receive FIFO bypassed, these flags normally indicate a
non-empty condition but may indicate empty if a JK or LM SYNC
character is present in the output register and the receiver
discard policy is non-0. When an Rx_Match (or Rx_RstMatch)
condition is not present, these same drivers are disabled
(High-Z).
The selection state of the Receive Output Register is entered
when an Rx_Match condition is present, and RXEN transitions
from HIGH to LOW. Once selected, the Receive Output Register
remains selected until RXEN is sampled HIGH by the rising edge
of RXCLK output. In the selected state, the output drivers for the
RXDATA outputs are enabled, and new data is presented to the
RXDATA bus on every clock cycle
Page 46 of 56
CY7C9689A
Figure 10. Receive Selection with Receive FIFO Enabled
RXCLK
RXRST
CE
[48]
Rx_Match
RXEN
Rx_Selected
Note 49
[48]
RXDATA/RXCMD
D1
Not Empty
RXEMPTY
D3
Not Empty
Note 49
Continuous Selection
Continuous Selection is a specialized form of selection which
does not require sequenced assertion of CE and TXEN or RXEN
to select the device for data transfers. In this Continuous
Selection mode, the CE and associated TXEN or RXEN enable
signal must be asserted when the device is powered up or during
assertion of RESET. So long as these signals remain asserted,
the device remains selected and data is accepted and presented
on every clock cycle. Note: The use of continuous selection
makes it impossible to reset the respective internal FIFOs, or to
access the Serial Address Register.
FIFO Reset Address Match
When CE and TXRST are both LOW, and this condition is
sampled by the rising edge of TXCLK, a Tx_RstMatch condition
is generated. This Tx_RstMatch condition continues until CE or
TXRST is sampled HIGH by the rising edge of TXCLK. When a
Tx_RstMatch (or Tx_Match) condition is present, the TXEMPTY
and TXFULL output drivers are enabled (just as in a normal
Tx_Match condition). When a Tx_RstMatch (or Tx_Match)
condition is not present, these same drivers are disabled
(High-Z). The Transmit FIFO reset Address Match is shown in
Figure 11. Note that although TXRST remains LOW for more
than one clock cycle, the Tx_RstMatch does not because the CE
signal is no longer asserted (LOW).
When CE and RXRST are both LOW, and this condition is
sampled by the rising edge of RXCLK, an Rx_RstMatch
condition is generated. This Rx_RstMatch condition continues
until CE or RXRST is sampled HIGH, at the rising edge of
Document Number: 38-02020 Rev. *H
D2
Figure 11. Transmit FIFO Reset Address Match
TXCLK
TXRST
CE
Tx_RstMatch
Tx_Match
[48]
[48]
TXFULL
Valid
RXCLK. When an Rx_RstMatch (or Rx_Match) condition is
present, the RXEMPTY and RXFULL output drivers are enabled.
When an Rx_RstMatch (or Rx_Match) condition is not present,
these same drivers are disabled (High-Z). The Receive FIFO
reset Address Match is shown in Figure 12. Note that while the
FIFO flags remain asserted for more than one clock cycle, this is
due to an Rx_Match condition, not a continuation of the
Rx_RstMatch.
Page 47 of 56
CY7C9689A
Figure 12. Receive FIFO Reset Address Match
RXCLK
RXRST
CE
Rx_RstMatch
Rx_Match
[48]
[48]
RXEMPTY
Valid Valid
FIFO Reset Sequence
On power-up, the Transmitter and Receiver FIFOs are cleared
automatically. If the usage of the FIFOs in specific operating
modes results in stale or unwanted data, this data can be cleared
by resetting the respective FIFO. Data in the Transmit FIFO will
empty automatically if it is enabled to read the FIFO (assuming
TXHALT is not LOW). Stale received data can be “flushed” by
reading it, or the Receive FIFO can be reset to remove the
unwanted data.
The Transmit and Receive FIFOs are reset when the
Tx_RstMatch or Rx_RstMatch condition remains present for
eight consecutive clock cycles. Any disruption of the reset
sequence prior to reaching the eight cycle count, either by
removal of CE or the respective TXRST or RXRST, or assertion
of the associated TXEN or RXEN, terminates the sequence and
does not reset the FIFO. Because CE must remain asserted
during the reset sequence, the addressed FIFO flags remain
driven during the entire sequence.
Transmit FIFO Reset Sequence
The Transmit FIFO reset sequence (see Figure 15) is started
when TXRST and CE are first sampled LOW by the rising edge
of TXCLK. Because a Tx_RstMatch condition is present, the
Transmit FIFO flags are asserted and can be used to track the
status of any Transmit FIFO reset in progress. Once the reset
sequence has reached its maximum count (eight TXCLK cycles),
the Transmit FIFO flags are asserted to indicate a FULL
condition (TXEMPTY is deasserted, and both TXHALF and
Document Number: 38-02020 Rev. *H
TXFULL are asserted). This indicates that the Transmit FIFO
reset has been recognized by the Transmit Control State
Machine and that a reset has been started. However, if the TXEN
is asserted prior to or during the assertion and sampling of
TXRST, the reset sequence is inhibited until TXEN is removed.
Note: The FIFO FULL state forced by the reset operation is
different from a FULL state caused by normal FIFO data writes.
For normal FIFO write operations, when FULL is first asserted,
the Transmit FIFO must still accept up to four additional writes of
data. When a FULL state is asserted due to a Transmit FIFO
reset operation, the FIFO will not accept any additional data.
The Transmit FIFO reset does not complete until the external
reset condition is removed. This can be removed by deassertion
of either TXRST or CE. If CE is deasserted (HIGH) to remove the
reset condition, the Transmit FIFO flag’s drivers are disabled,
and the Transmit FIFO must be addressed at a later time to
validate completion of the Transmit FIFO reset. If TXRST is
deasserted (HIGH) to remove the reset condition, the
Tx_RstMatch is changed to a Tx_Match, and the Transmit FIFO
status flags remain driven. The Transmit FIFO reset operation is
complete when the Transmit FIFO flags indicate an EMPTY state
(TXEMPTY is asserted and both TXHALF and TXFULL are
deasserted). A valid Transmit FIFO reset sequence is shown in
Figure 15.
Here the TXRST and CE are asserted (LOW) at the same time.
When these signals are both sampled LOW by TXCLK, a
Tx_RstMatch condition is present. With TXEN deasserted
(HIGH), the Transmit FIFO is not selected for data transfers. This
Tx_RstMatch condition must remain for eight TXCLK cycles to
initiate the Tx_FIFO_Reset. Following this the TXFULL FIFO
status flag is asserted to indicate that the Transmit FIFO reset
sequence has completed and that a Transmit FIFO reset is in
progress.
When the TXRST signal is deasserted (HIGH), CE remains LOW
to allow the FIFO status flags to be driven. This allows the
completion of the reset operation to be monitored. To allow better
multi-tasking on multi-PHY implementations, it is possible to
deassert CE (HIGH) as soon as the FULL state is indicated. The
FIFO reset operation will complete and the EMPTY state
(indicating completion of the reset operation) can be detected
during a separate polling operation.
For those links implemented with a single PHY, it is possible to
hardwire CE LOW and still perform normal accesses and reset
operations. In a single-PHY implementation, a Transmit FIFO
reset can never be initiated with TXEN asserted at the same time
as TXRST. Since CE is always LOW, any assertion of TXEN
causes the Transmit FIFO to be selected, clearing the reset
counter.
Page 48 of 56
CY7C9689A
Figure 13. Transmit FIFO Reset Sequence with Constant CE
TXCLK
TXRST
TXEN
Note 50
CE
Tx_RstMatch
[51]
[51]
Tx_Match
Tx_FIFO_Reset
[51]
TXFULL
Note 50
Not Full
Full
Notes
50. Signals shown as dotted lines indicate timing and levels when configured for external FIFOs (EXTFIFO is HIGH).
51. Signal names listed in italics are internal signals, shown for reference only.
Document Number: 38-02020 Rev. *H
Page 49 of 56
CY7C9689A
Figure 14. Invalid Transmit FIFO Reset Sequence with TXEN Asserted
TXCLK
TXRST
Note 50
TXEN
CE
[51]
Tx_RstMatch
Tx_Match
Tx_FIFO_Reset
[51]
[51]
TXFULL
Note 50
Not Full
Figure 15. Transmit FIFO Reset Sequence
TXCLK
TXRST
TXEN
Note 50
CE
[51]
Tx_RstMatch
Tx_Match
[51]
[51]
Tx_FIFO_Reset
TXFULL
Note 50
Not Full
Figure 14 shows a sequence of input signals which will not
produce a FIFO reset. In this case TXEN was asserted to select
a Transmit FIFO for data transfers. Because TXEN remains
active, the assertion of CE and TXRST does not initiate a reset
Document Number: 38-02020 Rev. *H
Full
operation. This is shown by the TXFULL flag remaining HIGH
(deasserted) following what would be the normal expiration of
the seven-state reset counter.
Page 50 of 56
CY7C9689A
Receive FIFO Reset Sequence
The Receive FIFO reset sequence operates (for the most part)
the same as the Transmit FIFO reset sequence. The same
requirements exist for the assertion state of RXRST and
selection of the interface. A sample Receive FIFO reset
sequence is shown in Figure 16. Upon recognition of a Receive
FIFO reset, the Receive FIFO flags are forced to indicate an
EMPTY state to prohibit additional reads from the FIFO. Unlike
the Transmit FIFO, where the internal completion of the reset
operation is shown by first going FULL and later going EMPTY
when the internal reset is complete, there is no secondary
indication of the completion of the internal reset of the Receive
FIFO. The Receive FIFO is usable as soon as new data is placed
into it by the Receive Control State Machine
Figure 16. Receive FIFO Reset Sequence.
RXCLK
RXRST
RXEN
Note 50
CE
[51]
Rx_RstMatch
Rx_Match
Rx_FIFO_Reset
[51]
[51]
RXEMPTY
Document Number: 38-02020 Rev. *H
Note 50
Not Empty
Empty
Page 51 of 56
CY7C9689A
Printed Circuit Board Layout Suggestions
Power Supply Bypass
0.01-F MLC X7R
1206 Chip Cap (4 sites)
INA±
OUTA±
OUTB±
INB±
Power Supply Bypass
0.01-F MLC X7R
CURSETB
Resistor
CURSETA
Resistor
Power Supply Bypass
0.01-F MLC X7R
1206 Chip Cap (2 sites)
RXSC/D
REFCLK
CY7C9689A-AC
CY7C9689A-AC
Power Supply Bypass
0.01-F MLC X7R
RESET
Via to VDD plane
Power Supply Bypass
0.01-F MLC X7R
Via to VSS plane
This is a typical printed circuit board layout showing example placement of power supply bypass components and other components
mounted on the same side as the CY7C9689A. Other layouts, including cases with components mounted on the reverse side would
work as well
Document Number: 38-02020 Rev. *H
Page 52 of 56
CY7C9689A
Ordering Information
Ordering Code
Package Name
Package Type
Operating Range
CY7C9689A-AXC
A100
Pb-Free 100-lead Thin Quad Flat Pack
Commercial
CY7C9689A-AXI
A100
Pb-Free 100-lead Thin Quad Flat Pack
Industrial
Ordering Code Definitions
CY 7
C 9689 A
-
A X C
Temperature Grade
C : Commercial, I : Industrial
Lead free
Package (A : TQFP)
Silicon Revision
TAXI Compatible HOTLink Transceiver
CMOS Technology
Marketing Code
Company ID
Package Diagram
Figure 17. 100-Pin TQFP (14 × 14 ×1.4 mm)
51-85048 *I
Document Number: 38-02020 Rev. *H
Page 53 of 56
CY7C9689A
Acronyms
Document Conventions
Table 9. Acronyms Used in this Document
Units of Measure
Acronym
Description
Symbol
Unit of Measure
AC
alternating current
BIST
built-in self-test
CDR
clock/data recovery
CML
current mode logic
DC
direct current
DVB
digital video broadcasting
mA
milliamperes
ECL
emitter coupled logic
mm
millimeters
I/O
input/output
ms
milliseconds
JTAG
joint test action group
mV
millivolts
LFI
link fault indicator
nA
nanoamperes
LFSR
linear feedback shift register
ns
nanoseconds
LPEN
local loopback input
nV
nanovolts
PECL
positive-ECL

ohms
PLL
phase-locked loop
pp
peak-to-peak
pF
picofarads
TTL
transistor-transistor logic
VCO
voltage controlled oscillator
Document Number: 38-02020 Rev. *H
°C
degrees Celsius
Mbps
megabits per second
MHz
megahertz
µA
microamperes
µs
microseconds
ps
picoseconds
sps
samples per second
V
volts
Page 54 of 56
CY7C9689A
Document History Page
Document Title: CY7C9689A TAXI™-compatible HOTLink® Transceiver
Document Number: 38-02020
Rev.
ECN No.
Issue Date
Orig. of
Change
**
106249
04/20/01
SZV
Changed from Spec number: 38-00758 to 38-02020
*A
107695
06/28/01
SPN
Changed part number: CY7C9689 to CY7C9689A
*B
113563
04/10/02
REV
Removed parity reference
Deleted mention of Byte-packer
Fixed formatting to change mF to F
*C
118318
11/08/02
REV
Changed pins 23 and 29 to RXDATA[11:10]/RXCMD[1:0]
LFI was changed from “three state” to just output pin
Fixed flip flop to Q as output and D as input
Font problem with up-arrow symbols corrected
*D
506290
See ECN
PCX
Added Pb-Free part numbers to ordering information
*E
2896245
03/19/10
CGX
Updated ordering information.
Updated package diagram.
*F
3383795
09/26/11
SAAC
Added Contents.
Added Ordering Code Definitions.
Updated Package Diagram.
Added Acronyms, and Units of Measure.
Updated to new template.
*G
4421000
06/26/2014
LISZ
Description of Change
Updated Pin Descriptions:
Updated pin 12 description.
Updated CY7C9689A HOTLink Transmitter Switching Waveforms:
Updated Write Cycle, synchronous interface diagram on page 31 to add the
timing specification.
Updated to new template.
*H
4571709
11/17/2014
YLIU
No technical updates.
Completing Sunset Review.
Document Number: 38-02020 Rev. *H
Page 55 of 56
CY7C9689A
Sales, Solutions, and Legal Information
Worldwide Sales and Design Support
Cypress maintains a worldwide network of offices, solution centers, manufacturer’s representatives, and distributors. To find the office
closest to you, visit us at Cypress Locations.
PSoC® Solutions
Products
Automotive
Clocks & Buffers
Interface
Lighting & Power Control
cypress.com/go/automotive
cypress.com/go/clocks
cypress.com/go/interface
cypress.com/go/powerpsoc
psoc.cypress.com/solutions
PSoC 1 | PSoC 3 | PSoC 4 | PSoC 5LP
Cypress Developer Community
Community | Forums | Blogs | Video | Training
cypress.com/go/plc
Memory
cypress.com/go/memory
PSoC
cypress.com/go/psoc
Touch Sensing
cypress.com/go/support
cypress.com/go/touch
USB Controllers
Wireless/RF
Technical Support
cypress.com/go/USB
cypress.com/go/wireless
© Cypress Semiconductor Corporation, 2001-2014. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of
any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be used for
medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its products for use as
critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress products in life-support systems
application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Any Source Code (software and/or firmware) is owned by Cypress Semiconductor Corporation (Cypress) and is protected by and subject to worldwide patent protection (United States and foreign),
United States copyright laws and international treaty provisions. Cypress hereby grants to licensee a personal, non-exclusive, non-transferable license to copy, use, modify, create derivative works of,
and compile the Cypress Source Code and derivative works for the sole purpose of creating custom software and or firmware in support of licensee product to be used only in conjunction with a Cypress
integrated circuit as specified in the applicable agreement. Any reproduction, modification, translation, compilation, or representation of this Source Code except as specified above is prohibited without
the express written permission of Cypress.
Disclaimer: CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS MATERIAL, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. Cypress reserves the right to make changes without further notice to the materials described herein. Cypress does not
assume any liability arising out of the application or use of any product or circuit described herein. Cypress does not authorize its products for use as critical components in life-support systems where
a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress’ product in a life-support systems application implies that the manufacturer
assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Use may be limited by and subject to the applicable Cypress software license agreement.
Document Number: 38-02020 Rev. *H
Revised November 17, 2014
Page 56 of 56
HOTLink is a registered trademark of Cypress Semiconductor, Inc. AMD, TAXI, and TAXIchip are trademarks of Advanced Micro Devices. Inc. All product and company names mentioned in this
document are trademarks of their respective holders.