CYPRESS CYV15G0204TRB

CYV15G0204TRB
Independent Clock HOTLink II™ Dual
Serializer and Dual Reclocking Deserializer
Features
• Thermally enhanced BGA
• Pb-Free package option available
• 0.25μ BiCMOS technology
• Second-generation HOTLink® technology
• Compliant to SMPTE 292M and SMPTE 259M video
standards
• Dual-channel video serializer plus dual channel video
reclocking deserializer
Functional Description
— 195- to 1500-Mbps serial data signaling rate
— Simultaneous operation at different signaling rates
• Supports reception of either 1.485 or 1.485/1.001 Gbps data
rate with the same training clock
• Supports half-rate and full-rate clocking
• Internal phase-locked loops (PLLs) with no external PLL
components
• Selectable differential PECL-compatible serial inputs
— Internal DC-restoration
• Redundant differential PECL-compatible serial outputs
— No external bias resistors required
— Signaling-rate controlled edge-rates
•
•
•
•
— Internal source termination
Synchronous LVTTL parallel interface
JTAG boundary scan
Built-In Self-Test (BIST) for at-speed link testing
Link Quality Indicator
— Analog signal detect
— Digital signal detect
• Low-power 2.5W @ 3.3V typical
• Single 3.3V supply
The CYV15G0204TRB Independent Clock HOTLink II™ Dual
Serializer and Dual Reclocking Deserializer is a point-to-point
or point-to-multipoint communications building block enabling
transfer of data over a variety of high-speed serial links
including SMPTE 292M and SMPTE 259M video applications.
It supports signaling rates in the range of 195 to 1500 Mbps
per serial link. All transmit and receive channels are
independent and can operate simultaneously at different
rates. Each transmit channel accepts 10-bit parallel characters
in an Input Register and converts them to serial data. Each
receive channel accepts serial data and converts it to 10-bit
parallel characters and presents these characters to an Output
Register. The received serial data can also be reclocked and
retransmitted through the reclocker serial outputs. Figure 1
illustrates typical connections between independent video
co-processors and corresponding CYV15G0204TRB chips.
The CYV15G0204TRB satisfies the SMPTE 259M and
SMPTE 292M compliance as per SMPTE EG34-1999 Pathological Test Requirements.
As
a
second-generation
HOTLink
device,
the
CYV15G0204TRB extends the HOTLink family with enhanced
levels of integration and faster data rates, while maintaining
serial-link compatibility (data and BIST) with other HOTLink
devices. Each transmit (TX) channel of the CYV15G0204TRB
HOTLink II device accepts scrambled 10-bit transmission
characters. These characters are serialized and output from
dual Positive ECL (PECL) compatible differential transmission-line drivers at a bit-rate of either 10- or 20-times the
input reference clock for that channel.
Figure 1. HOTLink II™ System Connections
Independent
Channel
CYV15G0204TRB
Device
Reclocked
Outputs
10
Video Coprocessor
10
10
Serial Links
10
10
Video Coprocessor
Independent
Channel
CYV15G0204TRB
Device
10
10
Reclocked
Outputs
Cypress Semiconductor Corporation
Document #: 38-02101 Rev. *C
•
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised May 2, 2007
[+] Feedback
CYV15G0204TRB
hardware allows at-speed testing of the high-speed serial data
paths in each transmit and receive section, and across the
interconnecting links.
Each receive (RX) channel of the CYV15G0204TRB HOTLink
II device accepts a serial bit-stream from one of two selectable
PECL-compatible differential line receivers, and using a
completely integrated Clock and Data Recovery PLL, recovers
the timing information necessary for data reconstruction. The
recovered bit-stream is reclocked and retransmitted through
the reclocker serial outputs. Also, the recovered serial data is
deserialized and presented to the destination host system.
The CYV15G0204TRB is ideal for SMPTE applications where
different data rates and serial interface standards are
necessary for each channel. Some applications include
multi-format routers, switchers, format converters, SDI
monitors, cameras, and camera control units.
Each transmit and receive channel contains an independent
BIST pattern generator and checker, respectively. This BIST
Phase
Align
Buffer
Phase
Align
Buffer
Deserializer
Deserializer
Serializer
Serializer
TX
TX
Reclocker
RX
Reclocker
RX
ROUTD1±
ROUTD2±
IND1±
IND2±
TRGCLKD±
RXDD[9:0]
x10
INC1±
INC2±
TRGCLKC±
RXDC[9:0]
x10
ROUTC1±
ROUTC2±
REFCLKB±
TXDB[9:0]
x10
TOUTB1±
TOUTB2±
REFCLKA±
x10
TOUTA1±
TOUTA2±
TXDA[9:0]
CYV15G0204TRB Logic Block Diagram
Document #: 38-02101 Rev. *C
Page 2 of 31
[+] Feedback
CYV15G0204TRB
Serializer Path Block Diagram
Bit-Rate Clock A
REFCLKA+
Transmit
PLL
Transmit PLL
Clock
ClockMultiplier
Multiplier A
REFCLKA–
TXRATEA
= Internal Signal
OEA[2..1]
RESET
SPDSELA
TXCLKOA
Character-Rate Clock A
TXERRA
TXCLKA
PABRSTA
10
10
OUTA1+
OUTA1–
Shifter
10
BIST LFSR
10
TXDA[9:0]
Phase-Align
Phase-Align
Buffer
Buffer
TXCKSELA
OEA[2..1]
TXBISTA
1
Input
Register
0
OUTA2+
OUTA2–
Bit-Rate Clock B
REFCLKB+
Transmit
PLL
Transmit PLL
Clock
ClockMultiplier
Multiplier B
REFCLKB–
TXRATEB
OEB[2..1]
SPDSELB
TXCLKOB
Character-Rate Clock B
TXERRB
TXCLKB
PABRSTB
Document #: 38-02101 Rev. *C
10
10
Shifter
10
BIST LFSR
TXDB[9:0]
10
Phase-Align
Phase-Align
Buffer
Buffer
TXCKSELB
OEB[2..1]
TXBISTB
1
Input
Register
0
OUTB1+
OUTB1–
OUTB2+
OUTB2–
Page 3 of 31
[+] Feedback
CYV15G0204TRB
= Internal Signal
Reclocking Deserializer Path Block Diagram
RESET
TRST
TRGRATEC
JTAG
Boundary
Scan
Controller
x2
TRGCLKC
TMS
TCLK
TDI
TDO
SDASEL[2..1]C[1:0]
LDTDEN
Clock &
Data
Recovery
PLL
INC2+
INC2–
ULCC
10
10
Output
Register
INC1+
INC1–
Shifter
INSELC
BIST LFSR
LFIC
Receive
Signal
Monitor
10
BISTSTC
÷2
SPDSELC
RXDC[9:0]
RXCLKC+
RXCLKC–
RXBISTC[1:0]
RXRATEC
RXPLLPDC
Recovered Character Clock
Recovered Serial Data
Reclocker
Output PLL
Clock Multiplier C
RECLKOC
Register
ROE[2..1]C
ROE[2..1]C
ROUTC1+
ROUTC1–
ROUTC2+
ROUTC2–
Character-Rate Clock C
REPDOC
TRGRATED
x2
TRGCLKD
SDASEL[2..1]D[1:0]
LDTDEN
Clock &
Data
Recovery
PLL
IND2+
IND2–
ULCD
10
10
Output
Register
IND1+
IND1–
Shifter
INSELD
BIST LFSR
LFID
Receive
Signal
Monitor
10
BISTSTD
÷2
SPDSELD
RXDD[9:0]
RXCLKD+
RXCLKD–
RXBISTD[1:0]
RXRATED
RXPLLPDD
Recovered Character Clock
Recovered Serial Data
Reclocker
Output PLL
Clock Multiplier D
RECLKOD
ROE[2..1]D
Register
ROE[2..1]D
ROUTD1+
ROUTD1–
ROUTD2+
ROUTD2–
Character-Rate Clock D
REPDOD
Document #: 38-02101 Rev. *C
Page 4 of 31
[+] Feedback
CYV15G0204TRB
Device Configuration and Control Block Diagram
WREN
ADDR[3:0]
Device Configuration
and Control Interface
DATA[6:0]
Document #: 38-02101 Rev. *C
= Internal Signal
TXRATE[A..B]
TXCKSEL[A..B]
PABRST[A..B]
TOE[2..1][A..B]
TXBIST[A..B]
RXRATE[C..D]
SDASEL[2..1][C..D][1:0]
TRGRATE[C..D]
RXPLLPD[C..D]
RXBIST[C..D][1:0]
ROE[2..1][C..D]
Page 5 of 31
[+] Feedback
CYV15G0204TRB
Pin Configuration (Top View)[1]
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
IN
C1–
ROUT
C1–
IN
C2–
ROUT
C2–
VCC
IN
D1–
ROUT
D1–
GND
IN
D2–
ROUT
D2–
GND
TOUT
A1–
GND
GND
TOUT
A2–
VCC
VCC
TOUT
B1–
VCC
TOUT
B2–
IN
C1+
ROUT
C1+
IN
C2+
ROUT
C2+
VCC
IN
D1+
ROUT
D1+
GND
IN
D2+
ROUT
D2+
NC
TOUT
A1+
GND
NC
TOUT
A2+
VCC
NC
TOUT
B1+
NC
TOUT
B2+
TDI
TMS
INSELC
VCC
VCC
ULCD
ULCC
GND
DATA
[6]
DATA
[4]
DATA
[2]
DATA
[0]
GND
NC
SPD
SELD
VCC
LDTD
EN
TRST
GND
TDO
RESET INSELD
VCC
VCC
VCC
SPD
SELC
GND
DATA
[5]
DATA
[3]
DATA
[1]
GND
GND
GND
NC
VCC
NC
VCC
SCAN TMEN3
EN2
TCLK
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
RX
DC[8]
RX
DC[9]
VCC
VCC
NC
NC
TX
CLKOB
NC
GND
WREN
GND
GND
SPD
SELB
NC
SPD
SELA
NC
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
NC
NC
NC
NC
RX
DC[4]
TRG
CLKC–
GND
GND
NC
NC
NC
NC
RX
DC[5]
TRG
CLKC+
LFIC
GND
NC
NC
NC
TX
DB[6]
RX
DC[6]
RX
DC[7]
VCC
RE
PDOC
TX
ERRB
TX
CLKB
GND
GND
GND
GND
GND
GND
GND
GND
RX
DC[3]
RX
DC[2]
RX
DC[1]
RX
DC[0]
TX
DB[5]
TX
DB[4]
TX
DB[3]
TX
DB[2]
TX
DB[1]
TX
DB[0]
TX
DB[9]
TX
DB[7]
VCC
VCC
VCC
VCC
BIST
STC
REF
REF
CLKB+ CLKB–
RE
RX
RX
CLKOC CLKC+ CLKC–
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
RX
DD[4]
RX
DD[3]
GND
TX
DA[9]
ADDR
TRG
[0]
CLKD–
VCC
VCC
VCC
RX
DD[8]
VCC
RX
DD[5]
RX
DD[1]
GND
BIST
STD
VCC
VCC
LFID
RX
CLKD–
VCC
RX
DD[6]
RX
DD[0]
GND
VCC
VCC
RX
DD[9]
RX
CLKD+
VCC
RX
DD[7]
RX
DD[2]
GND
TX
DA[1]
GND
TX
DA[4]
TX
DA[8]
VCC
NC
TX
DB[8]
NC
NC
ADDR
TRG
TX
[2]
CLKD+ CLKOA
GND
TX
DA[3]
TX
DA[7]
VCC
NC
NC
NC
NC
ADDR
[3]
ADDR
[1]
NC
TX
ERRA
GND
TX
DA[2]
TX
DA[6]
VCC
NC
REF
CLKA+
NC
NC
RE
CLKOD
NC
TX
CLKA
NC
GND
TX
DA[0]
TX
DA[5]
VCC
RE
REF
PDOD CLKA–
NC
NC
Note
1. NC = Do not connect.
Document #: 38-02101 Rev. *C
Page 6 of 31
[+] Feedback
CYV15G0204TRB
Pin Configuration (Bottom View)[1]
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
A
TOUT
B2–
VCC
TOUT
B1–
VCC
VCC
TOUT
A2–
GND
GND
TOUT
A1–
GND
ROUT
D2–
IN
D2–
GND
ROUT
D1–
IN
D1–
VCC
ROUT
C2–
IN
C2–
ROUT
C1–
IN
C1–
B
TOUT
B2+
NC
TOUT
B1+
NC
VCC
TOUT
A2+
NC
GND
TOUT
A1+
NC
ROUT
D2+
IN
D2+
GND
ROUT
D1+
IN
D1+
VCC
ROUT
C2+
IN
C2+
ROUT
C1+
IN
C1+
C
TDO
GND
TRST
LDTD
EN
VCC
SPD
SELD
NC
GND
DATA
[0]
DATA
[2]
DATA
[4]
DATA
[6]
GND
ULCC
ULCD
VCC
VCC INSELC TMS
TMEN3 SCAN
EN2
VCC
NC
VCC
NC
GND
GND
GND
DATA
[1]
DATA
[3]
DATA
[5]
GND
SPD
SELC
VCC
VCC
VCC INSELD RESET TCLK
D
TDI
E
VCC
VCC
VCC
VCC
VCC
VCC
VCC
VCC
F
NC
TX
CLKOB
NC
NC
VCC
VCC
RX
DC[9]
RX
DC[8]
G
NC
SPD
SELA
NC
SPD
SELB
GND
GND
WREN
GND
H
GND
GND
GND
GND
GND
GND
GND
GND
J
NC
NC
NC
NC
GND
GND
GND
GND
K
NC
NC
NC
NC
GND
GND
TRG
CLKC–
RX
DC[4]
L
TX
DB[6]
NC
NC
NC
GND
LFIC
TRG
CLKC+
RX
DC[5]
M
TX
CLKB
TX
ERRB
REF
REF
CLKB– CLKB+
RE
PDOC
VCC
RX
DC[7]
RX
DC[6]
N
GND
GND
GND
GND
GND
GND
GND
GND
P
TX
DB[2]
TX
DB[3]
TX
DB[4]
TX
DB[5]
RX
DC[0]
RX
DC[1]
RX
DC[2]
RX
DC[3]
R
TX
DB[7]
TX
DB[9]
TX
DB[0]
TX
DB[1]
T
VCC
VCC
VCC
VCC
U
NC
NC
TX
DB[8]
NC
VCC
TX
DA[8]
TX
DA[4]
GND
V
NC
NC
NC
NC
VCC
TX
DA[7]
TX
DA[3]
GND
W
NC
NC
REF
CLKA+
NC
VCC
TX
DA[6]
TX
DA[2]
GND
TX
ERRA
NC
Y
NC
NC
REF
RE
CLKA– PDOD
VCC
TX
DA[5]
TX
DA[0]
GND
NC
TX
CLKA
Document #: 38-02101 Rev. *C
RX
RX
RE
CLKC– CLKC+ CLKOC
TX
DA[1]
BIST
STC
VCC
VCC
VCC
VCC
TRG
ADDR
CLKD–
[0]
TX
DA[9]
GND
RX
DD[3]
RX
DD[4]
VCC
VCC
VCC
VCC
VCC
TX
TRG
ADDR
CLKOA CLKD+
[2]
BIST
STD
GND
RX
DD[1]
RX
DD[5]
VCC
RX
DD[8]
VCC
VCC
VCC
ADDR
[1]
ADDR
[3]
GND
RX
DD[0]
RX
DD[6]
VCC
RX
CLKD–
LFID
VCC
VCC
NC
RE
CLKOD
GND
RX
DD[2]
RX
DD[7]
VCC
RX
CLKD+
RX
DD[9]
VCC
VCC
Page 7 of 31
[+] Feedback
CYV15G0204TRB
Pin Definitions
CYV15G0204TRB HOTLink II Dual Serializer and Dual Reclocking Deserializer
Name
I/O Characteristics Signal Description
Transmit Path Data and Status Signals
TXDA[7:0]
TXDB[7:0]
LVTTL Input,
synchronous,
sampled by the
associated
TXCLKx↑ or
REFCLKx↑[2]
Transmit Data Inputs. TXDx[9:0] data inputs are captured on the rising edge of the
transmit interface clock. The transmit interface clock is selected by the TXCKSELx
latch via the device configuration interface.
TXERRA
TXERRB
LVTTL Output,
synchronous to
REFCLKx↑ [3],
asynchronous to
transmit channel
enable / disable,
asynchronous to loss
or return of
REFCLKx±
Transmit Path Error. TXERRx is asserted HIGH to indicate detection of a transmit
Phase-Align Buffer underflow or overflow. If an underflow or overflow condition is
detected, TXERRx, for the channel in error, is asserted HIGH and remains asserted
until the transmit Phase-Align Buffer is re-centered with the PABRSTx latch via the
device configuration interface. When TXBISTx = 0, the BIST progress is presented
on the associated TXERRx output. The TXERRx signal pulses HIGH for one
transmit-character clock period to indicate a pass through the BIST sequence once
every 511 character times.
TXERRx is also asserted HIGH, when any of the following conditions is true:
• The TXPLL for the associated channel is powered down. This occurs when OE2x
and OE1x for a given channel are both disabled by setting OE2x = 0 and OE1x = 0.
• The absence of the REFCLKx± signal.
Transmit Path Clock Signals
REFCLKA±
REFCLKB±
Differential LVPECL Reference Clock. REFCLKx± clock inputs are used as the timing references for the
transmit PLL. These input clocks may also be selected to clock the transmit parallel
or single-ended
interface. When driven by a single-ended LVCMOS or LVTTL clock source, connect
LVTTL input clock
the clock source to either the true or complement REFCLKx input, and leave the
alternate REFCLKx input open (floating). When driven by an LVPECL clock source,
the clock must be a differential clock, using both inputs.
TXCLKA
TXCLKB
LVTTL Clock Input,
internal pull-down
Transmit Path Input Clock. When configuration latch TXCKSELx = 0, the
associated TXCLKx input is selected as the character-rate input clock for the
TXDx[9:0] input. In this mode, the TXCLKx input must be frequency-coherent to its
associated TXCLKOx output clock, but may be offset in phase by any amount. Once
initialized, TXCLKx is allowed to drift in phase as much as ±180 degrees. If the input
phase of TXCLKx drifts beyond the handling capacity of the Phase Align Buffer,
TXERRx is asserted to indicate the loss of data, and remains asserted until the
Phase Align Buffer is initialized. The phase of the TXCLKx input clock relative to its
associated REFCLKx± is initialized when the configuration latch PABRSTx is written
as 0. When the associated TXERRx is deasserted, the Phase Align Buffer is
initialized and input characters are correctly captured.
TXCLKOA
TXCLKOB
LVTTL Output
Transmit Clock Output. TXCLKOx output clock is synthesized by each channel’s
transmit PLL and operates synchronous to the internal transmit character clock.
TXCLKOx operates at either the same frequency as REFCLKx± (TXRATEx = 0), or
at twice the frequency of REFCLKx± (TXRATEx = 1). The transmit clock outputs
have no fixed phase relationship to REFCLKx±.
Notes
2. When REFCLKx± is configured for half-rate operation, these inputs are sampled relative to both the rising and falling edges of the associated REFCLKx±.
3. When REFCLKx± is configured for half-rate operation, these outputs are presented relative to both the rising and falling edges of the associated REFCLKx±.
Document #: 38-02101 Rev. *C
Page 8 of 31
[+] Feedback
CYV15G0204TRB
Pin Definitions (continued)
CYV15G0204TRB HOTLink II Dual Serializer and Dual Reclocking Deserializer
Name
I/O Characteristics Signal Description
Receive Path Data and Status Signals
RXDC[9:0]
RXDD[9:0]
LVTTL Output,
synchronous to the
RXCLK± output
Parallel Data Output. RXDx[9:0] parallel data outputs change relative to the receive
interface clock. If RXCLKx± is a full-rate clock, the RXCLKx± clock outputs are
complementary clocks operating at the character rate. The RXDx[9:0] outputs for the
associated receive channels follow rising edge of RXCLKx+ or falling edge of
RXCLKx–. If RXCLKx± is a half-rate clock, the RXCLKx± clock outputs are complementary clocks operating at half the character rate. The RXDx[9:0] outputs for the
associated receive channels follow both the falling and rising edges of the associated
RXCLKx± clock outputs.
When BIST is enabled on the receive channel, the BIST status is presented on the
RXDx[1:0] and BISTSTx outputs. See Table 6 on page 19 for each status reported
by the BIST state machine. Also, while BIST is enabled, the RXDx[9:2] outputs
should be ignored.
BISTSTC
BISTSTD
LVTTL Output,
synchronous to the
RXCLKx ± output
REPDOC
REPDOD
Asynchronous to
reclocker output
channel
enable / disable
BIST Status Output. When RXBISTx[1:0] = 10, BISTSTx (along with RXDx[1:0])
displays the status of the BIST reception. See Table 6 on page 19 for the BIST status
reported for each combination of BISTSTx and RXDx[1:0].
When RXBISTx[1:0] ≠ 10, BISTSTx should be ignored.
Reclocker Powered Down Status Output. REPDOx is asserted HIGH, when the
associated channel’s reclocker output logic is powered down. This occurs when
ROE2x and ROE1x are both disabled by setting ROE2x = 0 and ROE1x = 0.
Receive Path Clock Signals
TRGCLKC±
TRGCLKD±
Differential LVPECL CDR PLL Training Clock. TRGCLKx± clock inputs are used as the reference source
or single-ended
for the frequency detector (Range Controller) of the associated receive PLL to
LVTTL input clock
reduce PLL acquisition time.
In the presence of valid serial data, the recovered clock output of the receive CDR
PLL (RXCLKx±) has no frequency or phase relationship with TRGCLKx±.
When driven by a single-ended LVCMOS or LVTTL clock source, connect the clock
source to either the true or complement TRGCLKx input, and leave the alternate
TRGCLKx input open (floating). When driven by an LVPECL clock source, the clock
must be a differential clock, using both inputs.
RXCLKC±
RXCLKD±
LVTTL Output Clock Receive Clock Output. RXCLKx± is the receive interface clock used to control
timing of the RXDx[9:0] parallel outputs. These true and complement clocks are used
to control timing of data output transfers. These clocks are output continuously at
either the half-character rate (1/20th the serial bit-rate) or character rate (1/10th the
serial bit-rate) of the data being received, as selected by RXRATEx.
RECLKOC
RECLKOD
LVTTL Output
Reclocker Clock Output. RECLKOx output clock is synthesized by the associated
reclocker output PLL and operates synchronous to the internal recovered character
clock. RECLKOx operates at either the same frequency as RXCLKx± (RXRATEx =
0), or at twice the frequency of RXCLKx± (RXRATEx = 1).The reclocker clock outputs
have no fixed phase relationship to RXCLKx±.
Device Control Signals
RESET
LVTTL Input,
asynchronous,
internal pull-up
Document #: 38-02101 Rev. *C
Asynchronous Device Reset. RESET initializes all state machines, counters, and
configuration latches in the device to a known state. RESET must be asserted LOW
for a minimum pulse width. When the reset is removed, all state machines, counters
and configuration latches are at an initial state. As per the JTAG specifications the
device RESET cannot reset the JTAG controller. Therefore, the JTAG controller has
to be reset separately. Refer to “JTAG Support” on page 19 for the methods to reset
the JTAG state machine. See Table 4 on page 16 for the initialize values of the device
configuration latches.
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CYV15G0204TRB
Pin Definitions (continued)
CYV15G0204TRB HOTLink II Dual Serializer and Dual Reclocking Deserializer
Name
I/O Characteristics Signal Description
LDTDEN
LVTTL Input,
internal pull-up
Level Detect Transition Density Enable. When LDTDEN is HIGH, the Signal Level
Detector, Range Controller, and Transition Density Detector are all enabled to
determine if the RXPLL tracks TRGCLKx± or the selected input serial data stream.
If the Signal Level Detector, Range Controller, or Transition Density Detector are out
of their respective limits while LDTDEN is HIGH, the RXPLL locks to TRGCLKx± until
such a time they become valid. The SDASEL[A..D][1:0] inputs are used to configure
the trip level of the Signal Level Detector. The Transition Density Detector limit is one
transition in every 60 consecutive bits. When LDTDEN is LOW, only the Range
Controller is used to determine if the RXPLL tracks TRGCLKx± or the selected input
serial data stream. It is recommended to set LDTDEN = HIGH.
ULCC
ULCD
LVTTL Input,
internal pull-up
Use Local Clock. When ULCx is LOW, the RXPLL is forced to lock to TRGCLKx±
instead of the received serial data stream. While ULCx is LOW, the LFIx for the
associated channel is LOW indicating a link fault.
When ULCx is HIGH, the RXPLL performs Clock and Data Recovery functions on
the input data streams. This function is used in applications in which a stable
RXCLKx± is needed. In cases when there is an absence of valid data transitions for
a long period of time, or the high-gain differential serial inputs (INx±) are left floating,
there may be brief frequency excursions of the RXCLKx± outputs from TRGCLKx±.
SPDSELA
SPDSELB
SPDSELC
SPDSELD
3-Level Select[4]
static control input
INSELC
INSELD
LVTTL Input,
asynchronous
Receive Input Selector. The INSELx input determines which external serial bit
stream is passed to the receiver’s Clock and Data Recovery circuit. When INSELx
is HIGH, the Primary Differential Serial Data Input, INx1±, is selected for the
associated receive channel. When INSELx is LOW, the Secondary Differential Serial
Data Input, INx2±, is selected for the associated receive channel.
LFIC
LFID
LVTTL Output,
asynchronous
Link Fault Indication Output. LFIx is an output status indicator signal. LFIx is the
logical OR of six internal conditions. LFIx is asserted LOW when any of the following
conditions is true:
• Received serial data rate outside expected range
• Analog amplitude below expected levels
• Transition density lower than expected
• Receive channel disabled
• ULCx is LOW
• Absence of TRGCLKx±.
Serial Rate Select. The SPDSELx inputs specify the operating signaling-rate range
of each channel’s transmit (channels A and B) or receive PLL (channels C and D).
LOW = 195 – 400 MBd
MID = 400 – 800 MBd
HIGH = 800 – 1500 MBd.
Device Configuration and Control Bus Signals
WREN
LVTTL input,
asynchronous,
internal pull-up
Control Write Enable. The WREN input writes the values of the DATA[6:0] bus into
the latch specified by the address location on the ADDR[3:0] bus.[5]
ADDR[3:0]
LVTTL input
asynchronous,
internal pull-up
Control Addressing Bus. The ADDR[3:0] bus is the input address bus used to
configure the device. The WREN input writes the values of the DATA[6:0] bus into
the latch specified by the address location on the ADDR[3:0] bus.[5] Table 4 on page
16 lists the configuration latches within the device, and the initialization value of the
latches upon the assertion of RESET. Table 5 on page 18 shows how the latches are
mapped in the device.
Notes
4. 3-Level Select inputs are used for static configuration. These are ternary inputs that make use of logic levels of LOW, MID, and HIGH. The LOW level is usually
implemented by direct connection to VSS (ground). The HIGH level is usually implemented by direct connection to VCC (power). The MID level is usually
implemented by not connecting the input (left floating), which allows it to self bias to the proper level.
5. See Device Configuration and Control Interface for detailed information on the operation of the Configuration Interface.
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
Pin Definitions (continued)
CYV15G0204TRB HOTLink II Dual Serializer and Dual Reclocking Deserializer
Name
DATA[6:0]
I/O Characteristics Signal Description
LVTTL input
asynchronous,
internal pull-up
Control Data Bus. The DATA[6:0] bus is the input data bus used to configure the
device. The WREN input writes the values of the DATA[6:0] bus into the latch
specified by address location on the ADDR[3:0] bus.[5] Table 4 on page 16 lists the
configuration latches within the device, and the initialization value of the latches upon
the assertion of RESET. Table 5 on page 18 shows how the latches are mapped in
the device.
Internal Device Configuration Latches
RXRATE[C..D]
Internal Latch[6]
SDASEL[2..1][C..D] Internal Latch
[1:0]
TXCKSEL[A..B]
[6]
Internal Latch[6]
[6]
TXRATE[A..B]
Internal Latch
TRGRATE[C..D]
Internal Latch[6]
RXPLLPD[C..D]
Latch[6]
Internal
[6]
RXBIST[C..D][1:0]
Internal Latch
TXBIST[A..B]
Internal Latch[6]
Receive Clock Rate Select.
Signal Detect Amplitude Select.
Transmit Clock Select.
Transmit PLL Clock Rate Select.
Reclocker Output PLL Clock Rate Select.
Receive Channel Power Control.
Receive Bist Disabled.
Transmit Bist Disabled.
TOE2[A..B]
Internal
Latch[6]
Transmitter Differential Serial Output Driver 2 Enable.
TOE1[A..B]
Internal Latch[6]
Transmitter Differential Serial Output Driver 1 Enable.
ROE2[C..D]
Internal
Latch[6]
Reclocker Differential Serial Output Driver 2 Enable.
ROE1[C..D]
Internal
Latch[6]
Reclocker Differential Serial Output Driver 1 Enable.
PABRSTB[A..B]
Internal Latch[6]
Transmit Clock Phase Alignment Buffer Reset.
Factory Test Modes
SCANEN2
LVTTL input,
internal pull-down
Factory Test 2. SCANEN2 input is for factory testing only. This input may be left as
a NO CONNECT, or GND only.
TMEN3
LVTTL input,
internal pull-down
Factory Test 3. TMEN3 input is for factory testing only. This input may be left as a
NO CONNECT, or GND only.
TOUTA1±
TOUTB1±
CML Differential
Output
Transmitter Primary Differential Serial Data Output. The transmitter TOUTx1±
PECL-compatible CML outputs (+3.3V referenced) are capable of driving terminated
transmission lines or standard fiber-optic transmitter modules, and must be
AC-coupled for PECL-compatible connections.
TOUTA2±
TOUTB2±
CML Differential
Output
Transmitter Secondary Differential Serial Data Output. The transmitter TOUTx2±
PECL-compatible CML outputs (+3.3V referenced) are capable of driving terminated transmission lines or standard fiber-optic transmitter modules, and must be AC-coupled for
PECL-compatible connections.
ROUTC1±
ROUTD1±
CML Differential
Output
Reclocker Primary Differential Serial Data Output. The reclocker ROUTx1±
PECL-compatible CML outputs (+3.3V referenced) are capable of driving terminated
transmission lines or standard fiber-optic transmitter modules, and must be
AC-coupled for PECL-compatible connections.
ROUTC2±
ROUTD2±
CML Differential
Output
Reclocker Secondary Differential Serial Data Output. The reclocker ROUTx2±
PECL-compatible CML outputs (+3.3V referenced) are capable of driving terminated transmission lines or standard fiber-optic transmitter modules, and must be AC-coupled for
PECL-compatible connections.
INC1±
IND1±
Differential Input
Primary Differential Serial Data Input. The INx1± input accepts the serial data
stream for deserialization. The INx1± serial stream is passed to the receive CDR
circuit to extract the data content when INSELx = HIGH.
Analog I/O
Note
6. See Device Configuration and Control Interface for detailed information on the internal latches.
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
Pin Definitions (continued)
CYV15G0204TRB HOTLink II Dual Serializer and Dual Reclocking Deserializer
Name
INC2±
IND2±
I/O Characteristics Signal Description
Differential Input
Secondary Differential Serial Data Input. The INx2± input accepts the serial data
stream for deserialization. The INx2± serial stream is passed to the receiver CDR
circuit to extract the data content when INSELx = LOW.
TMS
LVTTL Input,
internal pull-up
Test Mode Select. Used to control access to the JTAG Test Modes. If maintained
high for ≥5 TCLK cycles, the JTAG test controller is reset.
TCLK
LVTTL Input,
internal pull-down
JTAG Test Clock.
TDO
3-State LVTTL
Output
Test Data Out. JTAG data output buffer. High-Z while JTAG test mode is not
selected.
TDI
LVTTL Input,
internal pull-up
Test Data In. JTAG data input port.
TRST
LVTTL Input,
internal pull-up
JTAG reset signal. When asserted (LOW), this input asynchronously resets the
JTAG test access port controller.
JTAG Interface
Power
VCC
+3.3V Power.
GND
Signal and Power Ground for all internal circuits.
CYV15G0204TRB HOTLink II Operation
The CYV15G0204TRB is a highly configurable, independent
clocking, device designed to support reliable transfer of large
quantities of digital video data, using high-speed serial links
from multiple sources to multiple destinations.
CYV15G0204TRB Transmit Data Path
Input Register
The parallel input bus TXDx[9:0] can be clocked in using
TXCLKx (TXCKSELx = 0) or REFCLKx (TXCKSELx = 1).
Phase-Align Buffer
Data from each Input Register is passed to the associated
Phase-Align Buffer, when the TXDx[9:0] input registers are
clocked using TXCLKx (TXCKSELx = 0 and TXRATEx = 0).
When the TXDx[9:0] input registers are clocked using
REFCLKx± (TXCKSELx = 1) and REFCLKx± is a full-rate
clock, the associated Phase Alignment Buffer in the transmit
path is bypassed. These buffers are used to absorb clock
phase differences between the TXCLKx input clock and the
internal character clock for that channel.
Once initialized, TXCLKx is allowed to drift in phase as much
as ±180 degrees. If the input phase of TXCLKx drifts beyond
the handling capacity of the Phase Align Buffer, TXERRx is
asserted to indicate the loss of data, and remains asserted
until the Phase Align Buffer is initialized. The phase of the
TXCLKx relative to its associated internal character rate clock
is initialized when the configuration latch PABRSTx is written
as 0. When the associated TXERRx is deasserted, the Phase
Align Buffer is initialized and input characters are correctly
captured.
If the phase offset, between the initialized location of the input
clock and REFCLKx, exceeds the skew handling capabilities
Document #: 38-02101 Rev. *C
of the Phase-Align Buffer, an error is reported on that
channel’s TXERRx output. This output indicates an error
continuously until the Phase-Align Buffer for that channel is
reset. While the error remains active, the transmitter for that
channel outputs a continuous “1001111000” character to
indicate to the remote receiver that an error condition is
present in the link.
Transmit BIST
Each transmit channel contains an internal pattern generator
that can be used to validate both the link and device operation.
These generators are enabled by the associated TXBISTx
latch via the device configuration interface. When enabled, a
register in the associated transmit channel becomes a
signature pattern generator by logically converting to a Linear
Feedback Shift Register (LFSR). This LFSR generates a
511-character sequence. This provides a predictable yet
pseudo-random sequence that can be matched to an identical
LFSR in the attached Receiver(s).
A device reset (RESET sampled LOW) presets the BIST
Enable Latches to disable BIST on both channels.
All data present at the associated TXDx[9:0] inputs are ignored
when BIST is active on that channel.
Transmit PLL Clock Multiplier
Each Transmit PLL Clock Multiplier accepts a character-rate
or half-character-rate external clock at the associated
REFCLKx± input, and that clock is multiplied by 10 or 20 (as
selected by TXRATEx) to generate a bit-rate clock for use by
the transmit shifter. It also provides a character-rate clock used
by the transmit paths, and outputs this character rate clock as
TXCLKOx.
Each clock multiplier PLL can accept a REFCLKx± input
between 19.5 MHz and 150 MHz, however, this clock range is
limited by the operating mode of the CYV15G0204TRB clock
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CYV15G0204TRB
SPDSELx are 3-level select[4] inputs that select one of three
operating ranges for the serial data outputs and inputs of the
associated channel. The operating serial signaling-rate and
allowable range of REFCLKx± frequencies are listed in
Table 1.
Note. When a disabled transmit channel (i.e., both outputs
disabled) is re-enabled:
• data on the serial outputs may not meet all timing specifications for up to 250 μs
• the state of the phase-align buffer cannot be guaranteed,
and a phase-align reset is required if the phase-align buffer
is used
Table 1. Operating Speed Settings
CYV15G0204TRB Receive Data Path
multiplier (TXRATEx) and by the level on the associated
SPDSELx input.
SPDSELx
TXRATEx
REFCLKx±
Frequency
(MHz)
LOW
1
reserved
0
19.5–40
MID (Open)
1
20–40
0
40–80
HIGH
1
40–75
0
80–150
Signaling
Rate (Mbps)
195–400
400–800
800–1500
The REFCLKx± inputs are differential inputs with each input
internally biased to 1.4V. If the REFCLKx+ input is connected
to a TTL, LVTTL, or LVCMOS clock source, the input signal is
recognized when it passes through the internally biased
reference point. When driven by a single-ended TTL, LVTTL,
or LVCMOS clock source, connect the clock source to either
the true or complement REFCLKx input, and leave the
alternate REFCLKx input open (floating).
When both the REFCLKx+ and REFCLKx– inputs are
connected, the clock source must be a differential clock. This
can either be a differential LVPECL clock that is DC-or
AC-coupled or a differential LVTTL or LVCMOS clock.
By connecting the REFCLKx– input to an external voltage
source, it is possible to adjust the reference point of the
REFCLKx+ input for alternate logic levels. When doing so, it
is necessary to ensure that the input differential crossing point
remains within the parametric range supported by the input.
Transmit Serial Output Drivers
The serial output interface drivers use differential Current
Mode Logic (CML) drivers to provide source-matched drivers
for 50Ω transmission lines. These drivers accept data from the
Transmit Shifters. These drivers have signal swings equivalent
to that of standard PECL drivers, and are capable of driving
AC-coupled optical modules or transmission lines.
Serial Line Receivers
Two differential Line Receivers, INx1± and INx2±, are
available on each channel for accepting serial data streams.
The active Serial Line Receiver on a channel is selected using
the associated INSELx input. The Serial Line Receiver inputs
are differential, and can accommodate wire interconnect and
filtering losses or transmission line attenuation greater than
16 dB. For normal operation, these inputs should receive a
signal of at least VIDIFF > 100 mV, or 200 mV peak-to-peak
differential. Each Line Receiver can be DC- or AC-coupled to
+3.3V powered fiber-optic interface modules (any ECL/PECL
family, not limited to 100K PECL) or AC-coupled to +5V
powered optical modules. The common-mode tolerance of
these line receivers accommodates a wide range of signal
termination voltages. Each receiver provides internal
DC-restoration, to the center of the receiver’s common mode
range, for AC-coupled signals.
Signal Detect/Link Fault
Each selected Line Receiver (i.e., that routed to the clock and
data recovery PLL) is simultaneously monitored for
• analog amplitude above amplitude level selected by
SDASELx
• transition density above the specified limit
• range controls report the received data stream inside
normal frequency range (±1500 ppm[23])
• receive channel enabled
• Presence of reference clock
• ULCx is not asserted.
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 LFIx (Link Fault Indicator) output associated with each
receive channel, which changes synchronous to the receive
interface clock.
Analog Amplitude
Transmit Channels Enabled
Each driver can be enabled or disabled separately via the
device configuration interface.
When a driver is disabled via the configuration interface, it is
internally powered down to reduce device power. If both serial
drivers for a channel are in this disabled state, the associated
internal logic for that channel is also powered down. A device
reset (RESET sampled LOW) disables all output drivers.
Document #: 38-02101 Rev. *C
While most signal monitors are based on fixed constants, the
analog amplitude level detection is adjustable to allow
operation with highly attenuated signals, or in high-noise
environments. The analog amplitude level detection is set by
the SDASELx latch via device configuration interface. The
SDASELx latch sets the trip point for the detection of a valid
signal at one of three levels, as listed in Table 2. This control
input affects the analog monitors for both receive channels.
The Analog Signal Detect monitors are active for the Line
Receiver as selected by the associated INSELx input.
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CYV15G0204TRB
Table 2. Analog Amplitude Detect Valid Signal Levels[7]
SDASEL Typical Signal with Peak Amplitudes Above
00
Analog Signal Detector is disabled
01
140 mV p-p differential
10
280 mV p-p differential
11
420 mV p-p differential
Transition Density
The Transition Detection logic checks for the absence of
transitions spanning greater than six transmission characters
(60 bits). If no transitions are present in the data received, the
Detection logic for that channel asserts LFIx.
Receive Channel Enabled
The CYV15G0204TRB contains two receive channels that can
be independently enabled and disabled. Each channel can be
enabled or disabled separately through the RXPLLPDx input
latch as controlled by the device configuration interface. When
the RXPLLPDx latch = 0, the associated PLL and analog
circuitry of the channel is disabled. Any disabled channel
indicates a constant link fault condition on the LFIx output.
When RXPLLPDx = 1, the associated PLL and receive
channel is enabled to receive a serial stream.
When a disabled receive channel is reenabled, the status of
the associated LFIx output and data on the parallel outputs for
the associated channel may be indeterminate for up to 2 ms.
Clock/Data Recovery
Range Controls
The CDR circuit includes logic to monitor the frequency of the
PLL Voltage Controlled Oscillator (VCO) used to sample the
incoming data stream. This logic ensures that the VCO
operates at, or near the rate of the incoming data stream for
two primary cases:
• when the incoming data stream resumes after a time in
which it has been “missing.”
• when the incoming data stream is outside the acceptable
signaling rate range.
To perform this function, the frequency of the RXPLL VCO is
periodically compared to the frequency of the TRGCLKx±
input. If the VCO is running at a frequency beyond
±1500 ppm[23] as defined by the TRGCLKx± frequency, it is
periodically forced to the correct frequency (as defined by
TRGCLKx±, SPDSELx, and TRGRATEx) and then released in
an attempt to lock to the input data stream.
The sampling and relock period of the Range Control is calculated as follows: RANGE_CONTROL_ SAMPLING_PERIOD
= (RECOVERED BYTE CLOCK PERIOD) * (4096).
During the time that the Range Control forces the RXPLL VCO
to track TRGCLKx±, the LFIx output is asserted LOW. After a
valid serial data stream is applied, it may take up to one
RANGE CONTROL SAMPLING PERIOD before the PLL
locks to the input data stream, after which LFIx should be
HIGH.
The operating serial signaling-rate and allowable range of
TRGCLK± frequencies are listed in Table 3.
Table 3. Operating Speed Settings
SPDSELx
TRGRATEx
TRGCLKx±
Frequency
(MHz)
Signaling
Rate (Mbps)
LOW
1
reserved
195 – 400
0
19.5–40
MID (Open)
1
20–40
0
40–80
HIGH
1
40–75
0
80–150
400–800
800–1500
The extraction of a bit-rate clock and recovery of bits from each
received serial stream is performed by a separate CDR block
within each receive channel. The clock extraction function is
performed by an integrated PLL that tracks the frequency of
the transitions in the incoming bit stream and align the phase
of the internal bit-rate clock to the transitions in the selected
serial data stream.
Each CDR accepts a character-rate (bit-rate ÷ 10) or
half-character-rate (bit-rate ÷ 20) training clock from the
associated TRGCLKx± input. This TRGCLKx± input is used to
• ensure that the VCO (within the CDR) is operating at the
correct frequency (rather than a harmonic of the bit-rate)
• reduce PLL acquisition time
• limit unlocked frequency excursions of the CDR VCO when
there is no input data present at the selected Serial Line
Receiver.
Regardless of the type of signal present, the CDR attempts to
recover a data stream from it. If the signalling rate of the
recovered data stream is outside the limits set by the range
control monitors, the CDR tracks TRGCLKx± instead of the
data stream. Once the CDR output (RXCLK±) frequency
returns back close to TRGCLKx± frequency, the CDR input is
switched back to the input data stream. If no data is present at
the selected line receiver, this switching behavior may result
in brief RXCLK± frequency excursions from TRGCLKx±.
However, the validity of the input data stream is indicated by
the LFIx output. The frequency of TRGCLKx± is required to be
within ±1500ppm[23] of the frequency of the clock that drives
the REFCLKx± input of the remote transmitter to ensure a lock
to the incoming data stream. This large ppm tolerance allows
the CDR PLL to reliably receive a 1.485 or 1.485/1.001 Gbps
SMPTE HD-SDI data stream with a constant TRGCLK
frequency.
For systems using multiple or redundant connections, the LFIx
output can be used to select an alternate data stream. When
an LFIx indication is detected, external logic can toggle
selection of the associated INx1± and INx2± input through the
associated INSELx input. When a port switch takes place, it is
necessary for the receive PLL for that channel to reacquire the
new serial stream.
Note
7. The peak amplitudes listed in this table are for typical waveforms that have generally 3–4 transitions for every ten bits. In a worse case environment the signals
may have a sine-wave appearance (highest transition density with repeating 0101...). Signal peak amplitudes levels within this environment type could increase
the values in the table above by approximately 100 mV.
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
Reclocker
Each receive channel performs a reclocker function on the
incoming serial data. To do this, the Clock and Data Recovery
PLL first recovers the clock from the data. The data is retimed
by the recovered clock and then passed to an output register.
Also, the recovered character clock from the receive PLL is
passed to the reclocker output PLL which generates the bit
clock that is used to clock the retimed data into the output
register. This data stream is then transmitted through the
differential serial outputs.
Reclocker Serial Output Drivers
The serial output interface drivers use differential Current
Mode Logic (CML) drivers to provide source-matched drivers
for 50Ω transmission lines. These drivers accept data from the
reclocker output register in the reclocker channel. These
drivers have signal swings equivalent to that of standard PECL
drivers, and are capable of driving AC-coupled optical
modules or transmission lines.
Reclocker Output Channels Enabled
Each driver can be enabled or disabled separately via the
device configuration interface.
machine aborts the compare operations and resets the LFSR
to look for the start of the BIST sequence again.
A device reset (RESET sampled LOW) presets the BIST
Enable Latches to disable BIST on both channels.
BIST Status State Machine
When a receive path is enabled to look for and compare the
received data stream with the BIST pattern, the {BISTSTx,
RXDx[0], RXDx[1]} bits identify the present state of the BIST
compare operation.
The BIST state machine has multiple states, as shown in
Figure 2 on page 20 and Table 6 on page 19. When the receive
PLL detects an out-of-lock condition, the BIST state is forced
to the Start-of-BIST state, regardless of the present state of the
BIST state machine. If the number of detected errors ever
exceeds the number of valid matches by greater than 16, the
state machine is forced to the WAIT_FOR_BIST state where
it monitors the receive path for the first character of the next
BIST sequence.
Power Control
The receive channel presents a 10-bit data signal (and a BIST
status signal when RXBISTx[1:0] = 10).
The CYV15G0204TRB supports user control of the powered
up or down state of each transmit and receive channel. The
receive channels are controlled by the RXPLLPDx latch via the
device configuration interface. When RXPLLPDx = 0, the
associated PLL and analog circuitry of the channel is disabled.
The transmit channels are controlled by the TOE1x and the
TOE2x latches via the device configuration interface. The
reclocker function is controlled by the ROE1x and the ROE2x
latches via the device configuration interface. When a driver is
disabled via the configuration interface, it is internally powered
down to reduce device power. If both serial drivers for a
channel are in this disabled state, the associated internal logic
for that channel is also powered down. When the reclocker
serial drivers are disabled, the reclocker function will be
disabled, but the deserialization logic and parallel outputs will
remain enabled.
Receive BIST Operation
Device Reset State
Each receiver channel contains an internal pattern checker
that can be used to validate both device and link operation.
These pattern checkers are enabled by the associated
RXBISTx[1:0] latch via the device configuration interface.
When enabled, a register in the associated receive channel
becomes a signature pattern generator and checker by
logically converting to a Linear Feedback Shift Register
(LFSR). This LFSR generates a 511-character sequence. This
provides a predictable yet pseudo-random sequence that can
be matched to an identical LFSR in the attached Transmitter(s). When synchronized with the received data stream,
the associated Receiver checks each character from the
deserializer with each character generated by the LFSR and
indicates compare errors and BIST status at the RXDx[1:0]
and BISTSTx bits of the Output Register.
When the CYV15G0204TRB is reset by assertion of RESET,
all state machines, counters, and configuration latches in the
device are initialized to a reset state. Additionally, the JTAG
controller must also be reset for valid operation (even if JTAG
testing is not performed). See “JTAG Support” on page 19 for
JTAG state machine initialization. See Table 4 on page 16 for
the initialize values of the configuration latches.
When a driver is disabled via the configuration interface, it is
internally powered down to reduce device power. If both
reclocker serial drivers for a channel are in this disabled state,
the associated internal reclocker logic is also powered down.
The deserialization logic and parallel outputs will remain
enabled. A device reset (RESET sampled LOW) disables all
output drivers.
Note. When the disabled reclocker function (i.e., both outputs
disabled) is re-enabled, the data on the reclocker serial
outputs may not meet all timing specifications for up to 250 μs.
Output Bus
The BIST status bus {BISTSTx, RXDx[0], RXDx[1]} indicates
010b or 100b for one character period per BIST loop to
indicate loop completion. This status can be used to check test
pattern progress.
If the number of invalid characters received ever exceeds the
number of valid characters by 16, the receive BIST state
Document #: 38-02101 Rev. *C
Following a device reset, it is necessary to enable the receive
channels used for normal operation. This can be done by
sequencing the appropriate values on the device configuration
interface.[5]
Device Configuration and Control Interface
The CYV15G0204TRB is highly configurable via the configuration interface. The configuration interface allows each
channel to be configured independently. Table 4 on page 16
lists the configuration latches within the device including the
initialization value of the latches upon the assertion of RESET.
Table 5 on page 18 shows how the latches are mapped in the
device. Each row in the Table 5 maps to a 7-bit latch bank.
Page 15 of 31
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CYV15G0204TRB
There are 12 such write-only latch banks. When WREN = 0,
the logic value in the DATA[7:0] is latched to the latch bank
specified by the values in ADDR[3:0]. The second column of
Table 5 specifies the channels associated with the corresponding latch bank. For example, the first three latch banks
(0,1 and 2) consist of configuration bits for channel A.
The first and second rows of each channel (address numbers
0, 1, 3, 4, 6, 7, 9, and 10) are the static control latches. The
third row of latches for each channel (address numbers 2, 5,
8, and 11) are the dynamic control latches that are associated
with enabling dynamic functions within the device.
Latch Types
There are some latches in the table that have a static value
(i.e., 1, 0, or X). The latches that have a ‘1’ or ‘0’ must be
configured with their corresponding value each time that their
associated latch bank is configured. The latches that have an
‘X’ are don’t cares and can be configured with any value.
There are two types of latch banks: static (S) and dynamic (D).
Each channel is configured by 2 static and 1 dynamic latch
banks. The S type contain those settings that normally do not
change for a given application, whereas the D type controls
the settings that could change during the application's lifetime.
Static Latch Values
Table 4. Device Configuration and Control Latch Descriptions
Name
Signal Description
TXCKSELA
TXCKSELB
Transmit Clock Select. The initialization value of the TXCKSELx latch = 1. TXCKSELx selects the clock
source used to write data into the Transmit Input Register. When TXCKSELx = 1, the associated input register
TXDx[9:0] is clocked by REFCLKx↑. In this mode, the phase alignment buffer in the transmit path is bypassed.
When TXCKSELx = 0, the associated TXCLKx↑ is used to clock in the input register TXDx[9:0].
TXRATEA
TXRATEB
Transmit PLL Clock Rate Select. The initialization value of the TXRATEx latch = 0. TXRATEx is used to
select the clock multiplier for the Transmit PLL. When TXRATEx = 0, each transmit PLL multiples the
associated REFCLKx± input by 10 to generate the serial bit-rate clock. When TXRATEx = 0, the TXCLKOx
output clocks are full-rate clocks and follow the frequency and duty cycle of the associated REFCLKx± input.
When TXRATEx = 1, each Transmit PLL multiplies the associated REFCLKx± input by 20 to generate the
serial bit-rate clock. When TXRATEx = 1, the TXCLKOx output clocks are twice the frequency rate of the
REFCLKx± input. When TXCLKSELx = 1 and TXRATEx = 1, the Transmit Data Inputs are captured using
both the rising and falling edges of REFCLKx. TXRATEx = 1 and SPDSELx = LOW, is an invalid state and
this combination is reserved.
TXBISTA
TXBISTB
Transmit Bist Disabled. The initialization value of the TXBISTx latch = 1. TXBISTx selects if the transmit
BIST is disabled or enabled. When TXBISTx = 1, the transmit BIST function is disabled. When TXBISTx = 0,
the transmit BIST function is enabled.
TOE2A
TOE2B
Secondary Differential Serial Data Output Driver Enable. The initialization value of the TOE2x latch = 0.
TOE2x selects if the TOUTx2± secondary differential output drivers are enabled or disabled. When TOE2x =
1, the associated serial data output driver is enabled allowing data to be transmitted from the transmit shifter.
When TOE2x = 0, the associated serial data output driver is disabled. When a driver is disabled via the
configuration interface, it is internally powered down to reduce device power. If both serial drivers for a channel
are in this disabled state, the associated internal logic for that channel is also powered down. A device reset
(RESET sampled LOW) disables all output drivers.
TOE1A
TOE1B
Primary Differential Serial Data Output Driver Enable. The initialization value of the TOE1x latch = 0.
TOE1x selects if the TOUTx1± primary differential output drivers are enabled or disabled. When TOE1x = 1,
the associated serial data output driver is enabled allowing data to be transmitted from the transmit shifter.
When TOE1x = 0, the associated serial data output driver is disabled. When a driver is disabled via the
configuration interface, it is internally powered down to reduce device power. If both serial drivers for a channel
are in this disabled state, the associated internal logic for that channel is also powered down. A device reset
(RESET sampled LOW) disables all output drivers.
PABRSTA
PABRSTB
Transmit Clock Phase Alignment Buffer Reset. The initialization value of the PABRSTx latch = 1. The
PABRSTx is used to re-center the Transmit Phase Align Buffer. When the configuration latch PABRSTx is
written as a 0, the phase of the TXCLKx input clock relative to its associated REFCLKx+/- is initialized.
PABRST is an asynchronous input, but is sampled by each TXCLKx↑ to synchronize it to the internal clock
domain. PABRSTx is a self clearing latch. This eliminates the requirement of writing a 1 to complete the
initialization of the Phase Alignment Buffer.
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
Table 4. Device Configuration and Control Latch Descriptions (continued)
Name
Signal Description
RXRATEC
RXRATED
Receive Clock Rate Select. The initialization value of the RXRATEx latch = 1. RXRATEx is used to select
the rate of the RXCLKx± clock output.
When RXRATEx = 1, the RXCLKx± clock outputs are complementary clocks that follow the recovered clock
operating at half the character rate. Data for the associated receive channels should be latched alternately
on the rising edge of RXCLKx+ and RXCLKx–.
When RXRATEx = 0, the RXCLKx± clock outputs are complementary clocks that follow the recovered clock
operating at the character rate. Data for the associated receive channels should be latched on the rising edge
of RXCLKx+ or falling edge of RXCLKx–.
SDASEL1C[1:0]
SDASEL1D[1:0]
Primary Serial Data Input Signal Detector Amplitude Select. The initialization value of the SDASEL1x[1:0]
latch = 10. SDASEL1x[1:0] selects the trip point for the detection of a valid signal for the INx1± Primary
Differential Serial Data Inputs.
When SDASEL1x[1:0] = 00, the Analog Signal Detector is disabled.
When SDASEL1x[1:0] = 01, the typical p-p differential voltage threshold level is 140 mV.
When SDASEL1x[1:0] = 10, the typical p-p differential voltage threshold level is 280 mV.
When SDASEL1x[1:0] = 11, the typical p-p differential voltage threshold level is 420 mV.
SDASEL2C[1:0]
SDASEL2D[1:0]
Secondary Serial Data Input Signal Detector Amplitude Select. The initialization value of the
SDASEL2x[1:0] latch = 10. SDASEL2x[1:0] selects the trip point for the detection of a valid signal for the INx2±
Secondary Differential Serial Data Inputs.
When SDASEL2x[1:0] = 00, the Analog Signal Detector is disabled
When SDASEL2x[1:0] = 01, the typical p-p differential voltage threshold level is 140 mV.
When SDASEL2x[1:0] = 10, the typical p-p differential voltage threshold level is 280 mV.
When SDASEL2x[1:0] = 11, the typical p-p differential voltage threshold level is 420 mV.
TRGRATEC
TRGRATED
Training Clock Rate Select. The initialization value of the TRGRATEx latch = 0. TRGRATEx is used to select
the clock multiplier for the training clock input to the associated CDR PLL. When TRGRATEx = 0, the
TRGCLKx± input is not multiplied before it is passed to the CDR PLL. When TRGRATEx = 1, the TRGCLKx±
input is multiplied by 2 before it is passed to the CDR PLL. TRGRATEx = 1 and SPDSELx = LOW is an invalid
state and this combination is reserved.
RXPLLPDC
RXPLLPDD
Receive Channel Enable. The initialization value of the RXPLLPDx latch = 0. RXPLLPDx selects if the
associated receive channel is enabled or powered-down. When RXPLLPDx = 0, the associated receive PLL
and analog circuitry are powered-down. When RXPLLPDx = 1, the associated receive PLL and analog circuitry
are enabled.
RXBISTC[1:0]
RXBISTD[1:0]
Receive Bist Disable / SMPTE Receive Enable. The initialization value of the RXBISTx[1:0] latch = 11. For
SMPTE data reception, RXBISTx[1:0] should not remain in this initialization state (11). RXBISTx[1:0] selects
if receive BIST is disabled or enabled and sets the associated channel for SMPTE data reception. When
RXBISTx[1:0] = 01, the receiver BIST function is disabled and the associated channel is set to receive SMPTE
data. When RXBISTx[1:0] = 10, the receive BIST function is enabled and the associated channel is set to
receive BIST data. RXBISTx[1:0] = 00 and RXBISTx[1:0] = 11 are invalid states.
ROE2C
ROE2D
Reclocker Secondary Differential Serial Data Output Driver Enable. The initialization value of the ROE2x
latch = 0. ROE2x selects if the ROUTx2± secondary differential output drivers are enabled or disabled. When
ROE2x = 1, the associated serial data output driver is enabled allowing data to be transmitted from the transmit
shifter. When ROE2x = 0, the associated serial data output driver is disabled. When a driver is disabled via
the configuration interface, it is internally powered down to reduce device power. If both serial drivers for a
channel are in this disabled state, the associated internal logic for that channel is also powered down. A device
reset (RESET sampled LOW) disables all output drivers.
ROE1C
ROE1D
Reclocker Primary Differential Serial Data Output Driver Enable. The initialization value of the ROE1x
latch = 0. ROE1x selects if the ROUTx1± primary differential output drivers are enabled or disabled. When
ROE1x = 1, the associated serial data output driver is enabled allowing data to be transmitted from the transmit
shifter. When ROE1x = 0, the associated serial data output driver is disabled. When a driver is disabled via
the configuration interface, it is internally powered down to reduce device power. If both serial drivers for a
channel are in this disabled state, the associated internal logic for that channel is also powered down. A device
reset (RESET sampled LOW) disables all output drivers.
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
3. Set the dynamic bank of latches for the target channel.
Enable the Receive PLLs and transmit channels. If a
receive channel is enabled, set the channel for SMPTE data
reception (RXBISTA[1:0] = 01) or BIST data reception
(RXBISTA[1:0] = 10).
4. Reset the Phase Alignment Buffer for the target channel.
[Optional if phase align buffer is bypassed.]
Device Configuration Strategy
The following is a series of ordered events needed to load the
configuration latches on a per channel basis:
1. Pulse RESET Low after device power-up. This operation
resets all four channels. Initialize the JTAG state machine
to its reset state as detailed in “JTAG Support” on page 19.
2. Set the static latch banks for the target channel.
Table 5. Device Control Latch Configuration Table
ADDR
Channel
Type
DATA6
DATA5
DATA4
DATA3
DATA2
DATA1
DATA0
Reset
Value
0
(0000b)
A
S
X
X
X
X
X
0
X
1011111
1
(0001b)
A
S
X
X
X
X
0
TXCKSELA
TXRATEA
1010110
2
(0010b)
A
D
X
X
X
TXBISTA
OE2A
OE1A
PABRSTA
1011001
3
(0011b)
B
S
X
X
X
X
X
0
X
1011111
4
(0100b)
B
S
X
X
X
X
0
TXCKSELB
TXRATEB
1010110
5
(0101b)
B
D
X
X
X
TXBISTB
OE2B
OE1B
PABRSTB
1011001
6
(0110b)
C
S
1
0
X
X
0
0
RXRATEC
1011111
7
(0111b)
C
S
SDASEL2C[1]
SDASEL2C[0]
SDASEL1C[1]
SDASEL1C[0]
X
X
TRGRATEC
1010110
8
(1000b)
C
D
RXBISTC[1]
RXPLLPDC
RXBISTC[0]
X
ROE2C
ROE1C
X
1011001
9
(1001b)
D
S
1
0
X
X
0
0
RXRATED
1011111
10
(1010b)
D
S
SDASEL2D[1]
SDASEL2D[0]
SDASEL1D[1]
SDASEL1D[0]
X
X
TRGRATED
1010110
11
(1011b)
D
D
RXBISTD[1]
RXPLLPDD
RXBISTD[0]
X
ROE2D
ROE1D
X
1011001
12
(1100b)
13
(1101b)
INTERNAL TEST REGISTERS
14
(1110b)
DO NOT WRITE TO THESE ADDRESSES
15
(1111b)
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
JTAG Support
The CYV15G0204TRB contains a JTAG port to allow system
level diagnosis of device interconnect. Of the available JTAG
modes, boundary scan, and bypass are supported. This
capability is present only on the LVTTL inputs and outputs, the
REFCLKx± clock inputs, and the TRGCLKx± clock inputs. The
high-speed serial inputs and outputs are not part of the JTAG
test chain.
To ensure valid device operation after power-up (including
non-JTAG operation), the JTAG state machine should also be
initialized to a reset state. This should be done in addition to
the device reset (using RESET). The JTAG state machine can
be initialized using TRST (asserting it LOW and de-asserting
it or leaving it asserted), or by asserting TMS HIGH for at least
5 consecutive TCLK cycles. This is necessary in order to
ensure that the JTAG controller does not enter any of the test
modes after device power-up. In this JTAG reset state, the rest
of the device will be in normal operation.
Note. The order of device reset (using RESET) and JTAG
initialization does not matter.
3-Level Select Inputs
Each 3-Level select inputs reports as two bits in the scan
register. These bits report the LOW, MID, and HIGH state of
the associated input as 00, 10, and 11 respectively
JTAG ID
The JTAG device ID for the CYV15G0204TRB is ‘0C811069’x
Table 6. Receive Character Status Bits
Description
{BISTSTx, RXDx[0], RXDx[1]}
000, 001
010
Receive BIST Status
(Receive BIST = Enabled)
BIST Data Compare. Character compared correctly.
BIST Last Good. Last Character of BIST sequence detected and valid.
011
Reserved.
100
BIST Last Bad. Last Character of BIST sequence detected invalid.
101
BIST Start. Receive BIST is enabled on this channel, but character compares have not yet
commenced. This also indicates a PLL Out of Lock condition.
110
BIST Error. While comparing characters, a mismatch was found in one or more of the
character bits.
111
BIST Wait. The receiver is comparing characters. but has not yet found the start of BIST
character to enable the LFSR.
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
Figure 2. Receive BIST State Machine
Monitor Data
Received
Receive BIST
{BISTSTx, RXDx[0], Detected LOW
RXDx[1]} =
BIST_START (101)
RX PLL
Out of Lock
{BISTSTx, RXDx[0], RXDx[1]} =
BIST_WAIT (111)
Start of
BIST Detected
No
Yes, {BISTSTx, RXDx[0], RXDx[1]} =
BIST_DATA_COMPARE (000, 001)
Compare
Next Character
Mismatch
Yes
Match
Auto-Abort
Condition
{BISTSTx, RXDx[0], RXDx[1]} =
BIST_DATA_COMPARE (000, 001)
No
End-of-BIST
State
End-of-BIST
State
Yes, {BISTSTx, RXDx[0], RXDx[1]} =
BIST_LAST_BAD (100)
Yes, {BISTSTx, RXDx[0], RXDx[1]} =
BIST_LAST_GOOD (010)
No
No, {BISTSTx, RXDx[0], RXDx[1]} =
BIST_ERROR (110)
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
Maximum Ratings
Static Discharge Voltage.......................................... > 2000 V
(per MIL-STD-883, Method 3015)
(Above which the useful life may be impaired. User guidelines
only, not tested.)
Latch-up Current..................................................... > 200 mA
Storage Temperature .................................. –65°C to +150°C
Power-up Requirements
Ambient Temperature with
Power Applied............................................. –55°C to +125°C
The CYV15G0204TRB requires one power-supply. The
Voltage on any input or I/O pin cannot exceed the power pin
during power-up.
Supply Voltage to Ground Potential ............... –0.5V to +3.8V
DC Voltage Applied to LVTTL Outputs
in High-Z State .......................................–0.5V to VCC + 0.5V
Output Current into LVTTL Outputs (LOW)..................60 mA
Operating Range
Range
Commercial
Ambient Temperature
0°C to +70°C
VCC
+3.3V ±5%
DC Input Voltage....................................–0.5V to VCC + 0.5V
CYV15G0204TRB DC Electrical Characteristics
Parameter
Description
Test Conditions
Min.
Max.
Unit
0.4
V
LVTTL-compatible Outputs
VOHT
Output HIGH Voltage
IOH = − 4 mA, VCC = Min.
VOLT
Output LOW Voltage
IOL = 4 mA, VCC = Min.
IOST
Output Short Circuit Current
VOUT = 0V[8], VCC = 3.3V
–20
–100
mA
IOZL
High-Z Output Leakage Current
VOUT = 0V, VCC
–20
20
µA
2.0
VCC + 0.3
V
–0.5
0.8
V
1.5
mA
2.4
V
LVTTL-compatible Inputs
VIHT
Input HIGH Voltage
VILT
Input LOW Voltage
IIHT
Input HIGH Current
REFCLKx Input, VIN = VCC
Other Inputs, VIN = VCC
+40
µA
IILT
Input LOW Current
REFCLKx Input, VIN = 0.0V
–1.5
mA
Other Inputs, VIN = 0.0V
–40
µA
IIHPDT
Input HIGH Current with internal pull-down
VIN = VCC
+200
µA
IILPUT
Input LOW Current with internal pull-up
VIN = 0.0V
–200
µA
LVDIFF Inputs: REFCLKx±
VDIFF[9]
Input Differential Voltage
400
VCC
mV
VIHHP
Highest Input HIGH Voltage
1.2
VCC
V
VILLP
Lowest Input LOW voltage
VCOMREF[10] Common Mode Range
0.0
VCC/2
V
1.0
VCC – 1.2V
V
VCC
V
3-Level Inputs
VIHH
Three-Level Input HIGH Voltage
Min. ≤ VCC ≤ Max.
0.87 * VCC
VIMM
Three-Level Input MID Voltage
Min. ≤ VCC ≤ Max.
0.47 * VCC
0.53 * VCC
V
VILL
Three-Level Input LOW Voltage
Min. ≤ VCC ≤ Max.
0.0
0.13 * VCC
V
IIHH
Input HIGH Current
VIN = VCC
IIMM
Input MID current
VIN = VCC/2
IILL
Input LOW current
VIN = GND
–50
200
µA
50
µA
–200
µA
Notes
8. Tested one output at a time, output shorted for less than one second, less than 10% duty cycle.
9. This is the minimum difference in voltage between the true and complement inputs required to ensure detection of a logic-1 or logic-0. A logic-1 exists when the
true (+) input is more positive than the complement (−) input. A logic-0 exists when the complement (−) input is more positive than true (+) input.
10. The common mode range defines the allowable range of REFCLKx+ and REFCLKx− when REFCLKx+ = REFCLKx−. This marks the zero-crossing between
the true and complement inputs as the signal switches between a logic-1 and a logic-0.
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
CYV15G0204TRB DC Electrical Characteristics (continued)
Parameter
Description
Test Conditions
Min.
Max.
Unit
Differential CML Serial Outputs: TOUTA1±, TOUTA2±, TOUTB1±, TOUTB2±, ROUTC1±, ROUTC2±, ROUTD1±, ROUTD2±
VOHC
VOLC
VODIF
Output HIGH Voltage
(Vcc Referenced)
100Ω differential load
VCC – 0.5
VCC – 0.2
V
150Ω differential load
VCC – 0.5
VCC – 0.2
V
Output LOW Voltage
(VCC Referenced)
100Ω differential load
VCC – 1.4
VCC – 0.7
V
150Ω differential load
VCC – 1.4
VCC – 0.7
V
Output Differential Voltage
|(OUT+) − (OUT−)|
100Ω differential load
450
900
mV
150Ω differential load
560
1000
mV
100
1200
mV
VCC
V
Differential Serial Line Receiver Inputs: INC1±, INC2±, IND1±, IND2±
VDIFFs[9]
Input Differential Voltage |(IN+) − (IN−)|
VIHE
Highest Input HIGH Voltage
VILE
Lowest Input LOW Voltage
IIHE
Input HIGH Current
VIN = VIHE Max.
IILE
Input LOW Current
VIN = VILE Min.
–700
VICOM[11]
Common Mode input range
((VCC – 2.0V)+0.5)min,
(VCC – 0.5V) max.
+1.25
+3.1
VCC – 2.0
V
1350
Power Supply
μA
μA
V
Typ.
Max.
ICC [12, 13]
Max Power Supply Current
REFCLKx = Commercial
MAX
810
990
mA
ICC [12, 13]
Typical Power Supply Current
REFCLKx = Commercial
125 MHz
770
950
mA
AC Test Loads and Waveforms
3.3V
RL = 100Ω
R1
R1 = 590Ω
R2 = 435Ω
CL
CL ≤ 7 pF
(Includes fixture and
probe capacitance)
RL
(Includes fixture and
probe capacitance)
R2
(b) CML Output Test Load
[14]
[14]
(a) LVTTL Output Test Load
3.0V
Vth = 1.4V
GND
2.0V
2.0V
0.8V
0.8V
VIHE
VIHE
Vth = 1.4V
VILE
≤ 1 ns
≤ 1 ns
[15]
(c) LVTTL Input Test Waveform
80%
80%
20%
≤ 270 ps
20%
VILE
≤ 270 ps
(d) CML/LVPECL Input Test Waveform
Notes
11. The common mode range defines the allowable range of INPUT+ and INPUT− when INPUT+ = INPUT−. This marks the zero-crossing between the true and
complement inputs as the signal switches between a logic-1 and a logic-0.
12. Maximum ICC is measured with VCC = MAX, TA = 25°C, with all channels and Serial Line Drivers enabled, sending a continuous alternating 01 pattern, and
outputs unloaded.
13. Typical ICC is measured under similar conditions except with VCC = 3.3V, TA = 25°C, with all channels enabled and one Serial Line Driver per transmit channel
sending a continuous alternating 01 pattern. The redundant outputs on each channel are powered down and the parallel outputs are unloaded.
14. Cypress uses constant current (ATE) load configurations and forcing functions. This figure is for reference only.
15. The LVTTL switching threshold is 1.4V. All timing references are made relative to where the signal edges cross the threshold voltage.
Document #: 38-02101 Rev. *C
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CYV15G0204TRB
CYV15G0204TRB AC Electrical Characteristics
Parameter
Description
Min.
Max
Unit
CYV15G0204TRB Transmitter LVTTL Switching Characteristics Over the Operating Range
fTS
TXCLKx Clock Cycle Frequency
19.5
150
MHz
tTXCLK
TXCLKx Period=1/fTS
6.66
51.28
ns
tTXCLKH[16]
TXCLKx HIGH Time
2.2
tTXCLKL[16]
tTXCLKR [16, 17, 18, 19]
tTXCLKF [16, 17, 18, 19]
TXCLKx LOW Time
2.2
TXCLKx Rise Time
0.2
1.7
ns
TXCLKx Fall Time
0.2
1.7
ns
tTXDS
Transmit Data Set-up Time to TXCLKx↑ (TXCKSELx = 0)
2.2
tTXDH
Transmit Data Hold Time from TXCLKx↑ (TXCKSELx = 0)
1.0
fTOS
TXCLKOx Clock Frequency = 1x or 2x REFCLKx Frequency
19.5
150
MHz
tTXCLKO
TXCLKOx Period=1/fTOS
6.66
51.28
ns
tTXCLKOD
TXCLKO Duty Cycle centered at 60% HIGH time
–1.9
0
ns
9.75
150
MHz
ns
ns
ns
ns
CYV15G0204TRB Receiver LVTTL Switching Characteristics Over the Operating Range
fRS
RXCLKx± Clock Output Frequency
tRXCLKP
RXCLKx± Period = 1/fRS
6.66
102.56
ns
tRXCLKD
RXCLKx± Duty Cycle Centered at 50% (Full Rate and Half Rate)
–1.0
+1.0
ns
tRXCLKR [16]
RXCLKx± Rise Time
0.3
1.2
ns
tRXCLKF [16]
RXCLKx± Fall Time
0.3
1.2
ns
tRXDv–[20]
Status and Data Valid Time to RXCLKx± (RXRATEx = 0) (Full Rate)
5UI–2.0[21]
ns
Status and Data Valid Time to RXCLKx± (RXRATEx = 1) (Half Rate)
5UI–1.3[21]
ns
Status and Data Valid Time to RXCLKx± (RXRATEx = 0)
5UI–1.8[21]
ns
Status and Data Valid Time to RXCLKx± (RXRATEx = 1)
5UI–2.6[21]
ns
tRXDv+[20]
fROS
RECLKOx Clock Frequency
19.5
150
MHz
tRECLKO
RECLKOx Period=1/fROS
6.66
51.28
ns
tRECLKOD
RECLKOx Duty Cycle centered at 60% HIGH time
-1.9
0
ns
CYV15G0204TRB REFCLKx Switching Characteristics Over the Operating Range
fREF
REFCLKx Clock Frequency
19.5
150
MHz
tREFCLK
REFCLKx Period = 1/fREF
6.6
51.28
ns
tREFH
REFCLKx HIGH Time (TXRATEx = 1)(Half Rate)
5.9
ns
REFCLKx HIGH Time (TXRATEx = 0)(Full Rate)
2.9[16]
ns
REFCLKx LOW Time (TXRATEx = 1)(Half Rate)
5.9
ns
REFCLKx LOW Time (TXRATEx = 0)(Full Rate)
2.9[16]
ns
tREFL
tREFD[22]
REFCLKx Duty Cycle
30
70
%
tREFR [16, 17, 18, 19] REFCLKx Rise Time (20%–80%)
2
ns
tREFF[16, 17, 18, 19]
REFCLKx Fall Time (20%–80%)
2
ns
tREFRX[23]
TRGCLKx Frequency Referenced to Received Clock Period
–0.15
+0.15
%
Notes
16. Tested initially and after any design or process changes that may affect these parameters, but not 100% tested.
17. The ratio of rise time to falling time must not vary by greater than 2:1.
18. For a given operating frequency, neither rise or fall specification can be greater than 20% of the clock-cycle period or the data sheet maximum time.
19. All transmit AC timing parameters measured with 1-ns typical rise time and fall time.
20. Parallel data output specifications are only valid if all outputs are loaded with similar DC and AC loads.
21. Receiver UI (Unit Interval) is calculated as 1/(fREF * 20) (when TRGRATEx = 1) or 1/(fREF * 10) (when TRGRATEx = 0). In an operating link this is equivalent to tB.
22. The duty cycle specification is a simultaneous condition with the tREFH and tREFL parameters. This means that at faster character rates the REFCLKx± duty cycle
cannot be as large as 30%–70%.
23. TRGCLKx± has no phase or frequency relationship with the recovered clock(s) and only acts as a centering reference to reduce clock synchronization time.
TRGCLKx± must be within ±1500 PPM (±0.15%) of the transmitter PLL reference (REFCLKx±) frequency. Although transmitting to a HOTLink II receiver channel
necessitates the frequency difference between the transmitter and receiver reference clocks to be within ±1500-PPM, the stability of the crystal needs to be
within the limits specified by the appropriate standard when transmitting to a remote receiver that is compliant to that standard.
Document #: 38-02101 Rev. *C
Page 23 of 31
[+] Feedback
CYV15G0204TRB
CYV15G0204TRB AC Electrical Characteristics (continued)
Parameter
tTREFDS
tTREFDH
Description
Min.
Max
Unit
Transmit Data Set-up Time to REFCLKx - Full Rate
(TXRATEx = 0, TXCKSELx = 1)
2.4
ns
Transmit Data Set-up Time to REFCLKx - Half Rate
(TXRATEx = 1, TXCKSELx = 1)
2.3
ns
Transmit Data Hold Time from REFCLKx - Full Rate
(TXRATEx = 0, TXCKSELx = 1)
1.0
ns
Transmit Data Hold Time from REFCLKx - Half Rate
(TXRATEx = 1, TXCKSELx = 1)
1.6
ns
CYV15G0204TRB TRGCLKx Switching Characteristics Over the Operating Range
fREF
TRGCLKx Clock Frequency
19.5
150
MHz
tREFCLK
TRGCLKx Period = 1/fREF
6.6
51.28
ns
tREFH
TRGCLKx HIGH Time (TXRATEx = 1)(Half Rate)
5.9
ns
TRGCLKx HIGH Time (TXRATEx = 0)(Full Rate)
2.9[16]
ns
TRGCLKx LOW Time (TXRATEx = 1)(Half Rate)
5.9
ns
TRGCLKx LOW Time (TXRATEx = 0)(Full Rate)
2.9[16]
ns
tREFL
tREFD[22]
tREFR [16, 17, 18, 19]
tREFF[16, 17, 18, 19]
tREFRX[23]
TRGCLKx Duty Cycle
30
TRGCLKx Rise Time (20%–80%)
TRGCLKx Fall Time (20%–80%)
TRGCLKx Frequency Referenced to Received Clock Frequency
–0.15
70
%
2
ns
2
ns
+0.15
%
CYV15G0204TRB Bus Configuration Write Timing Characteristics Over the Operating Range
tDATAH
Bus Configuration Data Hold
tDATAS
Bus Configuration Data Setup
10
ns
tWRENP
Bus Configuration WREN Pulse Width
10
ns
0
ns
CYV15G0204TRB JTAG Test Clock Characteristics Over the Operating Range
fTCLK
JTAG Test Clock Frequency
tTCLK
JTAG Test Clock Period
20
MHz
50
ns
30
ns
CYV15G0204TRB Device RESET Characteristics Over the Operating Range
tRST
Device RESET Pulse Width
CYV15G0204TRB Transmitter and Reclocker Serial Output Characteristics Over the Operating Range
Parameter
Description
tB
Bit Time
tRISE[16]
CML Output Rise Time 20−80% (CML Test Load)
tFALL[16]
CML Output Fall Time 80−20% (CML Test Load)
Document #: 38-02101 Rev. *C
Condition
Min.
Max.
Unit
660
5128
ps
SPDSELx = HIGH
50
270
ps
SPDSELx= MID
100
500
ps
SPDSELx =LOW
180
1000
ps
SPDSELx = HIGH
50
270
ps
SPDSELx = MID
100
500
ps
SPDSELx =LOW
180
1000
ps
Page 24 of 31
[+] Feedback
CYV15G0204TRB
PLL Characteristics
Parameter
Description
Condition
Min.
Typ.
Max.
Unit
CYV15G0204TRB Transmitter Output PLL Characteristics
tJTGENSD[16, 24]
Transmit Jitter Generation - SD Data Rate
REFCLKx = 27 MHz
200
ps
tJTGENHD[16, 24]
Transmit Jitter Generation - HD Data Rate
REFCLKx = 148.5 MHz
76
ps
tTXLOCK
Transmit PLL lock to REFCLKx±
μs
200
CYV15G0204TRB Reclocker Output PLL Characteristics
tJRGENSD[16, 25]
Reclocker Jitter Generation - SD Data Rate
TRGCLKx = 27 MHz
133
ps
tJRGENHD[16, 25]
Reclocker Jitter Generation - HD Data Rate
TRGCLKx = 148.5 MHz
107
ps
CYV15G0204TRB Receive PLL Characteristics Over the Operating Range
tRXLOCK
tRXUNLOCK
Receive PLL lock to input data stream (cold start)
376k
UI
Receive PLL lock to input data stream
376k
UI
46
UI
Receive PLL Unlock Rate
Capacitance[16]
Max.
Unit
CINTTL
Parameter
TTL Input Capacitance
Description
TA = 25°C, f0 = 1 MHz, VCC = 3.3V
Test Conditions
7
pF
CINPECL
PECL input Capacitance
TA = 25°C, f0 = 1 MHz, VCC = 3.3V
4
pF
\
CYV15G0204TRB HOTLink II Transmitter Switching Waveforms
Transmit Interface
Write Timing
TXCLKx selected
tTXCLK
tTXCLKH
tTXCLKL
TXCLKx
tTXDS
tTXDH
TXDx[9:0]
Transmit Interface
Write Timing
REFCLKx selected
TXRATEx = 0
tREFCLK
tREFH
tREFL
REFCLKx
tTREFDS
tTREFDH
TXDx[9:0],
Notes
24. While sending BIST data at the corresponding data rate, after 10,000 histogram hits, time referenced to REFCLKx± input.
25. Receiver input stream is BIST data from the transmit channel. This data is reclocked and output to a wide-bandwidth digital sampling oscilloscope. The
measurement was recorded after 10,000 histogram hits, time referenced to REFCLKx± of the transmit channel.
Document #: 38-02101 Rev. *C
Page 25 of 31
[+] Feedback
CYV15G0204TRB
CYV15G0204TRB HOTLink II Transmitter Switching Waveforms (continued)
Transmit Interface
Write Timing
REFCLKx selected
TXRATEx = 1
tREFCLK
tREFH
tREFL
REFCLKx
Note 26
tTREFDS
tTREFDH
tTREFDS
tTREFDH
TXDx[9:0]
Transmit Interface
TXCLKOx Timing
tREFCLK
tREFH
TXRATEx = 1
REFCLKx
tREFL
Note 27
tTXCLKO
Note 28
TXCLKOx
(internal)
Transmit Interface
TXCLKOx Timing
tREFCLK
tREFH
TXRATEx = 0
tREFL
Note27
REFCLKx
tTXCLKO
Note28
TXCLKOx
Notes
26. When REFCLKx± is configured for half-rate operation (TXRATEx = 1) and data is captured using REFCLKx instead of a TXCLKx clock. Data is captured using
both the rising and falling edges of REFCLKx.
27. The TXCLKOx output remains at the character rate regardless of the state of TXRATEx and does not follow the duty cycle of REFCLKx±.
28. The rising edge of TXCLKOx output has no direct phase relationship to the REFCLKx± input.
Document #: 38-02101 Rev. *C
Page 26 of 31
[+] Feedback
CYV15G0204TRB
Switching Waveforms for the CYV15G0204TRB HOTLink II Receiver
Receive Interface
Read Timing
RXRATEx = 0
tRXCLKP
RXCLKx+
RXCLKx–
tRXDV–
RXDx[9:0]
tRXDV+
Receive Interface
Read Timing
RXRATEx = 1
tRXCLKP
RXCLKx+
RXCLKx–
tRXDV–
RXDx[9:0]
tRXDV+
Bus Configuration
Write Timing
ADDR[3:0]
DATA[6:0]
tWRENP
WREN
tDATAS
tDATAH
Document #: 38-02101 Rev. *C
Page 27 of 31
[+] Feedback
CYV15G0204TRB
Table 7. Package Coordinate Signal Allocation
Ball
ID
Signal Name
Signal Type
Ball
ID
Signal Name
Signal Type
Ball
ID
Signal Name
Signal Type
A01
INC1–
CML IN
C07
ULCC
LVTTL IN PU
F17
NC
NO CONNECT
A02
ROUTC1–
CML OUT
C08
GND
GROUND
F18
NC
NO CONNECT
A03
INC2–
CML IN
C09
DATA[6]
LVTTL IN PU
F19
TXCLKOB
LVTTL OUT
A04
ROUTC2–
CML OUT
C10
DATA[4]
LVTTL IN PU
F20
NC
NO CONNECT
A05
VCC
POWER
C11
DATA[2]
LVTTL IN PU
G01
GND
GROUND
A06
IND1–
CML IN
C12
DATA[0]
LVTTL IN PU
G02
WREN
LVTTL IN PU
A07
ROUTD1–
CML OUT
C13
GND
GROUND
G03
GND
GROUND
A08
GND
GROUND
C14
NC
NO CONNECT
G04
GND
GROUND
A09
IND2–
CML IN
C15
SPDSELD
3-LEVEL SEL
G17
SPDSELB
3-LEVEL SEL
A10
ROUTD2–
CML OUT
C16
VCC
POWER
G18
NC
NO CONNECT
A11
GND
GROUND
C17
LDTDEN
LVTTL IN PU
G19
SPDSELA
3-LEVEL SEL
A12
TOUTA1–
CML OUT
C18
TRST
LVTTL IN PU
G20
NC
NO CONNECT
A13
GND
GROUND
C19
GND
GROUND
H01
GND
GROUND
A14
GND
GROUND
C20
TDO
LVTTL 3-S OUT
H02
GND
GROUND
A15
TOUTA2–
CML OUT
D01
TCLK
LVTTL IN PD
H03
GND
GROUND
A16
VCC
POWER
D02
RESET
LVTTL IN PU
H04
GND
GROUND
A17
VCC
POWER
D03
INSELD
LVTTL IN
H17
GND
GROUND
A18
TOUTB1–
CML OUT
D04
VCC
POWER
H18
GND
GROUND
A19
VCC
POWER
D05
VCC
POWER
H19
GND
GROUND
A20
TOUTB2–
CML OUT
D06
VCC
POWER
H20
GND
GROUND
B01
INC1+
CML IN
D07
SPDSELC
3-LEVEL SEL
J01
GND
GROUND
B02
ROUTC1+
CML OUT
D08
GND
GROUND
J02
GND
GROUND
B03
INC2+
CML IN
D09
DATA[5]
LVTTL IN PU
J03
GND
GROUND
B04
ROUTC2+
CML OUT
D10
DATA[3]
LVTTL IN PU
J04
GND
GROUND
B05
VCC
POWER
D11
DATA[1]
LVTTL IN PU
J17
NC
NO CONNECT
B06
IND1+
CML IN
D12
GND
GROUND
J18
NC
NO CONNECT
B07
ROUTD1+
CML OUT
D13
GND
GROUND
J19
NC
NO CONNECT
B08
GND
GROUND
D14
GND
GROUND
J20
NC
NO CONNECT
B09
IND2+
CML IN
D15
NC
NO CONNECT
K01
RXDC[4]
LVTTL OUT
B10
ROUTD2+
CML OUT
D16
VCC
POWER
K02
TRGCLKC–
PECL IN
B11
NC
NO CONNECT
D17
NC
NO CONNECT
K03
GND
GROUND
B12
TOUTA1+
CML OUT
D18
VCC
POWER
K04
GND
GROUND
B13
GND
GROUND
D19
SCANEN2
LVTTL IN PD
K17
NC
NO CONNECT
B14
NC
NO CONNECT
D20
TMEN3
LVTTL IN PD
K18
NC
NO CONNECT
B15
TOUTA2+
CML OUT
E01
VCC
POWER
K19
NC
NO CONNECT
B16
VCC
POWER
E02
VCC
POWER
K20
NC
NO CONNECT
B17
NC
NO CONNECT
E03
VCC
POWER
L01
RXDC[5]
LVTTL OUT
B18
TOUTB1+
CML OUT
E04
VCC
POWER
L02
TRGCLKC+
PECL IN
B19
NC
NO CONNECT
E17
VCC
POWER
L03
LFIC
LVTTL OUT
B20
TOUTB2+
CML OUT
E18
VCC
POWER
L04
GND
GROUND
NO CONNECT
C01
TDI
LVTTL IN PU
E19
VCC
POWER
L17
NC
C02
TMS
LVTTL IN PU
E20
VCC
POWER
L18
NC
NO CONNECT
C03
INSELC
LVTTL IN
F01
RXDC[8]
LVTTL OUT
L19
NC
NO CONNECT
Document #: 38-02101 Rev. *C
Page 28 of 31
[+] Feedback
CYV15G0204TRB
Table 7. Package Coordinate Signal Allocation (continued)
Ball
ID
Signal Name
Signal Type
Ball
ID
Signal Name
Signal Type
Ball
ID
Signal Name
Signal Type
C04
VCC
POWER
F02
RXDC[9]
LVTTL OUT
L20
TXDB[6]
LVTTL IN
C05
VCC
POWER
F03
VCC
POWER
M01
RXDC[6]
LVTTL OUT
C06
ULCD
LVTTL IN PU
F04
VCC
POWER
M02
RXDC[7]
LVTTL OUT
M03
VCC
POWER
U03
VCC
POWER
W03
LFID
LVTTL OUT
M04
REPDOC
LVTTL OUT
U04
VCC
POWER
W04
RXCLKD–
LVTTL OUT
M17
REFCLKB+
PECL IN
U05
VCC
POWER
W05
VCC
POWER
M18
REFCLKB–
PECL IN
U06
RXDD[4]
LVTTL OUT
W06
RXDD[6]
LVTTL OUT
M19
TXERRB
LVTTL OUT
U07
RXDD[3]
LVTTL OUT
W07
RXDD[0]
LVTTL OUT
M20
TXCLKB
LVTTL IN PD
U08
GND
GROUND
W08
GND
GROUND
N01
GND
GROUND
U09
TXDA[9]
LVTTL IN
W09
ADDR [3]
LVTTL IN PU
N02
GND
GROUND
U10
ADDR [0]
LVTTL IN PU
W10
ADDR [1]
LVTTL IN PU
N03
GND
GROUND
U11
TRGCLKD–
PECL IN
W11
NC
NO CONNECT
N04
GND
GROUND
U12
TXDA[1]
LVTTL IN
W12
TXERRA
LVTTL OUT
N17
GND
GROUND
U13
GND
GROUND
W13
GND
GROUND
N18
GND
GROUND
U14
TXDA[4]
LVTTL IN
W14
TXDA[2]
LVTTL IN
N19
GND
GROUND
U15
TXDA[8]
LVTTL IN
W15
TXDA[6]
LVTTL IN
N20
GND
GROUND
U16
VCC
POWER
W16
VCC
POWER
P01
RXDC[3]
LVTTL OUT
U17
NC
NO CONNECT
W17
NC
NO CONNECT
P02
RXDC[2]
LVTTL OUT
U18
TXDB[8]
LVTTL IN
W18
REFCLKA+
PECL IN
P03
RXDC[1]
LVTTL OUT
U19
NC
NO CONNECT
W19
NC
NO CONNECT
P04
RXDC[0]
LVTTL OUT
U20
NC
NO CONNECT
W20
NC
NO CONNECT
P17
TXDB[5]
LVTTL IN
V01
VCC
POWER
Y01
VCC
POWER
P18
TXDB[4]
LVTTL IN
V02
VCC
POWER
Y02
VCC
POWER
P19
TXDB[3]
LVTTL IN
V03
VCC
POWER
Y03
RXDD[9]
LVTTL OUT
P20
TXDB[2]
LVTTL IN
V04
RXDD[8]
LVTTL OUT
Y04
RXCLKD+
LVTTL OUT
R01
BISTSTC
LVTTL OUT
V05
VCC
POWER
Y05
VCC
POWER
R02
RECLKOC
LVTTL OUT
V06
RXDD[5]
LVTTL OUT
Y06
RXDD[7]
LVTTL OUT
R03
RXCLKC+
LVTTL OUT
V07
RXDD[1]
LVTTL OUT
Y07
RXDD[2]
LVTTL OUT
R04
RXCLKC–
LVTTL OUT
V08
GND
GROUND
Y08
GND
GROUND
R17
TXDB[1]
LVTTL IN
V09
BISTSTD
LVTTL OUT
Y09
RECLKOD
LVTTL OUT
R18
TXDB[0]
LVTTL IN
V10
ADDR [2]
LVTTL IN PU
Y10
NC
NO CONNECT
R19
TXDB[9]
LVTTL IN
V11
TRGCLKD+
PECL IN
Y11
TXCLKA
LVTTL IN PD
R20
TXDB[7]
LVTTL IN
V12
TXCLKOA
LVTTL OUT
Y12
NC
NO CONNECT
T01
VCC
POWER
V13
GND
GROUND
Y13
GND
GROUND
T02
VCC
POWER
V14
TXDA[3]
LVTTL IN
Y14
TXDA[0]
LVTTL IN
T03
VCC
POWER
V15
TXDA[7]
LVTTL IN
Y15
TXDA[5]
LVTTL IN
T04
VCC
POWER
V16
VCC
POWER
Y16
VCC
POWER
T17
VCC
POWER
V17
NC
NO CONNECT
Y17
REPDOD
LVTTL OUT
T18
VCC
POWER
V18
NC
NO CONNECT
Y18
REFCLKA–
PECL IN
T19
VCC
POWER
V19
NC
NO CONNECT
Y19
NC
NO CONNECT
T20
VCC
POWER
V20
NC
NO CONNECT
Y20
NC
NO CONNECT
U01
VCC
POWER
W01
VCC
POWER
U02
VCC
POWER
W02
VCC
POWER
Document #: 38-02101 Rev. *C
Page 29 of 31
[+] Feedback
CYV15G0204TRB
Ordering Information
Speed
Ordering Code
Package
Name
Operating
Range
Package Type
Standard
CYV15G0204TRB-BGC
BL256
256-Ball Thermally Enhanced Ball Grid Array
Commercial
Standard
CYV15G0204TRB-BGXC
BL256
Pb-Free 256-Ball Thermally Enhanced Ball Grid Array
Commercial
Package Diagram
Figure 3. 256-Lead L2 Ball Grid Array (27 x 27 x 1.57 mm) BL256
TOP VIEW
0.20(4X)
BOTTOM VIEW (BALL SIDE)
A
27.00±0.13
Ø0.15 M C
Ø0.30 M C
A1 CORNER I.D.
A
B
24.13
A1 CORNER I.D.
Ø0.75±0.15(256X)
14
15
12
13
10
11
8
9
6
7
4
5
27.00±0.13
R 2.5 Max (4X)
A
2
3
1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
12.065
16
17
24.13
18
19
1.27
20
W
Y
0.50 MIN.
B
A
1.57±0.175
0.97 REF.
0.15
26°
TYP.
0.60±0.10
C
0.15
C
C
0.20 MIN
TOP OF MOLD COMPOUND
TO TOP OF BALLS
SEATING PLANE
SIDE VIEW
SECTION A-A
51-85123-*E
HOTLink is a registered trademark and HOTLink II is a trademark of Cypress Semiconductor. All product and company names
mentioned in this document may be the trademarks of their respective holders.
Document #: 38-02101 Rev. *C
Page 30 of 31
© Cypress Semiconductor Corporation, 2002-2007. 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.
[+] Feedback
CYV15G0204TRB
Document History Page
Document Title: CYV15G0204TRB Independent Clock HOTLink II™ Dual Serializer and Dual Reclocking Deserializer
Document Number: 38-02101
REV.
ECN NO.
ISSUE
DATE
ORIG. OF
CHANGE
**
244348
See ECN
FRE
New Data Sheet
*A
338721
See ECN
SUA
Added Pb-Free package option availability
*B
384307
See ECN
AGT
Revised setup and hold times (tTXDH, tTREFDS, tTREFDH, tRXDv–, tRXDv+)
*C
1034060
See ECN
UKK
Added clarification for the necessity of JTAG controller reset and the
methods to implement it.
Document #: 38-02101 Rev. *C
DESCRIPTION OF CHANGE
Page 31 of 31
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