TERIDIAN 78P2351R

78P2351R
Serial 155M
NRZ to CMI Converter
DATA SHEET
AUGUST 2006
DESCRIPTION
FEATURES
The 78P2351R is Teridian’s second generation Line
Interface Unit (LIU) for 155 Mbit/s electrical SDH
interfaces (STM1e). The device is a single chip
solution that includes an integrated Clock & Data
Recovery in both the transmit and receive paths for
easy, cost efficient NRZ to CMI conversion.
•
•
•
The device interfaces to 75Ω coaxial cable through
wideband transformers and can handle over 12.7dB
of cable loss.
By eliminating the needs for
synchronous clocks, the small 78P2351R (7x7mm
MLF package) is ideal for new STM1e (ES1) Small
Form-factor Pluggable (SFP) transceiver modules.
•
•
•
•
APPLICATIONS
•
•
•
•
•
•
•
STM1e SFP modules
SDH/ATM Line Cards
Add Drop Multiplexers (ADMs)
PDH/SDH Test Equipment
Digital Microwave Radios
Multi-Service Switches
•
•
•
ITU-T G.703 compliant, adjustable cable driver
for 155.52 Mbps CMI-coded coax transmission
Integrated adaptive CMI equalizer and CDR in
receive path handles over 12.7dB of cable loss
LVPECL-compatible system interface with
integrated CDR in transmit path for flexible NRZ
to CMI conversion
Configurable via HW control pins or 4-wire serial
port interface
Compliant with ANSI T1.105.03-1994; ITU-T
G.813, G.825, G.958; and Telcordia GR-253CORE for jitter performance
Receive Loss of Signal (Rx LOS) detection
Receive Monitor Mode handles up to 20dB of
flat loss (at max 6dB cable loss)
Optional fixed backplane equalizer compensates
for up to 1.5m of trace
Operates from a single 3.3V supply
Available in a small 7x7mm 56-pin QFN
package
Industrial Temperature: -40˚C to +85˚C
BLOCK DIAGRAM
78P2351R
75ohm Coax
(CMI Encoded)
Tx Disable
CDR
Adaptive
Eq.
CMI
ENDEC
CDR
Fixed
Eq.
TD +
TD -
RD +
RD -
LVPECL Data
(NRZ Encoded)
Rx LOS
Page: 1 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
TABLE OF CONTENTS ................................................................................................ 2
FUNCTIONAL DESCRIPTION........................................................................................ 4
REFERENCE CLOCK ............................................................................................................................4
RECEIVER OPERATION .......................................................................................................................4
Receiver Monitor Mode ..................................................................................................................4
Receive Loss of Signal .................................................................................................................4
TRANSMITTER OPERATION ................................................................................................................5
Plesiochronous Mode ....................................................................................................................5
Synchronous Mode ........................................................................................................................5
Clock Synthesizer...........................................................................................................................5
Pulse Amplitude Adjustment.........................................................................................................6
Transmit Backplane Equalizer ......................................................................................................6
POWER-DOWN FUNCTION .................................................................................................................6
LOOPBACK MODES .............................................................................................................................6
POWER-ON RESET ..............................................................................................................................7
SERIAL CONTROL INTERFACE .........................................................................................................7
REGISTER DESCRIPTION............................................................................................. 8
REGISTER ADDRESSING.....................................................................................................................8
REGISTER TABLE.................................................................................................................................8
LEGEND .................................................................................................................................................9
GLOBAL REGISTERS ...........................................................................................................................9
ADDRESS 0-0: MASTER CONTROL REGISTER .........................................................................9
PORT-SPECIFIC REGISTERS ............................................................................................................10
ADDRESS 1-0: MODE CONTROL REGISTER ...........................................................................10
ADDRESS 1-1: SIGNAL CONTROL REGISTER.........................................................................11
ADDRESS 1-2: ADVANCED TX CONTROL REGISTER 1 .........................................................11
ADDRESS 1-3: ADVANCED TX CONTROL REGISTER 0 .........................................................12
ADDRESS 1-4: RESERVED.........................................................................................................12
ADDRESS 1-5: STATUS MONITOR REGISTER.........................................................................12
ADDRESS 1-6, 1-7: RESERVED...................................................................................................13
PIN DESCRIPTION ....................................................................................................... 14
LEGEND ...............................................................................................................................................14
TRANSMITTER PINS ...........................................................................................................................14
RECEIVER PINS ..................................................................................................................................14
REFERENCE AND STATUS PINS ......................................................................................................14
CONTROL PINS ..................................................................................................................................15
SERIAL-PORT PINS ............................................................................................................................16
POWER AND GROUND PINS .............................................................................................................16
Page: 2 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
TABLE OF CONTENTS (continued)
ELECTRICAL SPECIFICATIONS ................................................................................. 17
ABSOLUTE MAXIMUM RATINGS..........................................................................................................17
RECOMMENDED OPERATING CONDITIONS ......................................................................................17
DC CHARACTERISTICS.........................................................................................................................17
ANALOG PINS CHARACTERISTICS.....................................................................................................18
DIGITAL I/O CHARACTERISTICS..........................................................................................................18
Pins of type CI, CID ........................................................................................................................18
Pins of type CIT ..............................................................................................................................18
Pins of type CIS ..............................................................................................................................18
Pins of type COZ ............................................................................................................................18
Pins of type PO...............................................................................................................................19
Pins of type PI.................................................................................................................................19
Pins of type OD...............................................................................................................................19
REFERENCE CLOCK CHARACTERISTICS..........................................................................................19
SERIAL-PORT TIMING CHARACTERISTICS........................................................................................20
TRANSMITTER SPECIFICATIONS FOR CMI INTERFACE .................................................................21
TRANSMITTER OUTPUT JITTER ..........................................................................................................24
RECEIVER SPECIFICATIONS FOR CMI INTERFACE (Transformer-coupled)..................................25
RECEIVER JITTER TOLERANCE ..........................................................................................................26
RECEIVER JITTER TRANSFER FUNCTION .........................................................................................27
LOSS OF SIGNAL CONDITIONS ...........................................................................................................28
APPLICATION INFORMATION .................................................................................... 28
EXTERNAL COMPONENTS ...................................................................................................................28
TRANSFORMER SPECIFICATIONS ......................................................................................................28
THERMAL INFORMATION .....................................................................................................................28
MECHANICAL SPECIFICATIONS ............................................................................... 29
PACKAGE INFORMATION .......................................................................................... 30
ORDERING INFORMATION ............................................................................................................ 30
Revision History ........................................................................................................................................31
Page: 3 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
FUNCTIONAL DESCRIPTION
The 78P2351R contains all the necessary transmit
and receive circuitry for connection between
155.52Mbit/s NRZ data sources (STS-3/STM-1) and
CMI encoded electrical interfaces (ES1/STM-1e).
The 78P2351R system interface mimics a 3.3V
optical transceiver module and only requires a
reference clock and wideband transformer to
complete the electrical interface. The chip can be
controlled via control pins or serial port register
settings.
In hardware mode (pin control) the SPSL pin must
be low. Additionally, the following unused pins
must be set accordingly:
SDO pin must be tied low
SDI pin must be tied low
SEN pin must be tied high
In software mode (SPSL pin high), control pins set
register defaults upon power-up or reset. The
78P2351R can then be configured via the 4-wire
serial control interface. See Pin Descriptions
section for more information.
REFERENCE CLOCK
The 78P2351R requires a reference clock supplied
to the CKREFP/N pins. For reference frequencies of
19.44MHz or 77.76MHz, the device accepts a single
ended CMOS level input at CKREFP (with CKREFN
pin tied to ground). For reference frequency of
155.52MHz, the device accepts a differential
LVPECL clock input at CKREFP/N. The frequency
of this reference input is selected by either the CKSL
control pin or register bit as follows:
CKSL pin
Low
Float
High
CKSL[1:0] bits
00
10
11
Reference
Frequency
19.44MHz
77.76MHz
155.52MHz
The recovered CMI signal first enters an AGC and
an adaptive equalizer designed to overcome intersymbol interference caused by long cable lengths.
The variable gain differential amplifier automatically
controls the gain to maintain a constant voltage level
output regardless of the input voltage level.
The outputs of the data comparators are connected
to the clock recovery circuits. The clock recovery
system employs a Delay Locked Loop (DLL), which
utilizes a line-rate reference frequency derived from
the clock applied to the CKREFP/N pins. After the
clock and data have been recovered, the data is
decoded to binary by the CMI decoder.
The
SODP/N pins output the recovered NRZ data at
LVPECL levels.
Receiver Monitor Mode
The SCK_MON pin or MON register bit puts the
receiver in monitor mode and adds approximately
20dB of flat gain to the receive signal before
equalization. Rx Monitor Mode can handle 20dB of
flat loss typical of monitoring points with up to 6dB
(typical 225ft) of cable loss. Note that Loss of Signal
detection is disabled during Rx Monitor Mode.
Receive Loss of Signal Detect
The 78P2351R includes a Loss of Signal (LOS)
detector. When the peak value of the received
signal is less than approximately 19dB below
nominal for approximately 110 UI, Receive Loss of
Signal is asserted. The Rx LOS signal is cleared
when the received signal is greater than
approximately 18dB below nominal for 110 UI.
During Rx LOS conditions, the receive clock will
remain on the last phase tap of the Rx DLL
outputting a stable clock while the receive data
outputs are squelched and held at logic ‘0’.
Note: Rx Loss of Signal detection is disabled
during Local Loopback and Receive Monitor
Modes.
RECEIVER OPERATION
The receiver accepts an ITU-T G.703 compliant CMI
encoded signal at 155.52Mbit/s from the RXP/N
inputs. When properly terminated and transformercoupled to the line, the receiver can handle over
12.7dB of cable loss. The receiver’s jitter tolerance
exceeds all relevant standards even with 12.7dB
worth of cable attenuation and inter-symbol
interference (ISI). See Receiver Jitter Tolerance
section for more info.
Page: 4 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
TRANSMITTER OPERATION
The transmitter section generates an adjustable
ITU-T G.703 compliant analog signal for
transmission through a wideband transformer onto
75Ω coaxial cable. Differential NRZ data is input to
the 78P2351R on the SIDP/N pins at LVPECL levels
and passed to a low jitter clock and data recovery
circuit.
An optional clock decoupling FIFO is
provided to decouple the on chip and off chip clocks.
The NRZ data is encoded using CMI line coding to
ensure an adequate number of transitions.
Each of the transmit timing modes can be configured
in HW mode or SW mode as shown in the table
below.
HW Control
Tx Mode
00
Synchronous
(FIFO enabled)
Floating
10
Plesiochronous
High
01
n/a
11
Plesiochronous Mode
Plesiochronous mode represents a common
condition where a synchronous reference clock is
not available. In this mode, the 78P2351R will
recover the transmit clock from the plesiochronous
data and bypass the internal FIFO and re-timing
block. This mode is commonly used for mezzanine
cards, modules, and any application where the
reference clock can’t always be synchronous to the
transmit source clock/data
System
Clock
XO
CKREFP
NRZ
CMIP/N
SIDP/N
Framer/
Mapper
NRZ
TDK
78P2351R
SODP/N
CMI
XFMR
CMI
Coax
Coax
XFMR
RXP/N
Figure 1: Plesiochronous Mode
Page: 5 of 31
CKREFP/N
NRZ
CMIP/N
SIDP/N
Framer/
Mapper
NRZ
TDK
78P2351R
SODP/N
CMI
XFMR
CMI
RXP/N
Coax
Coax
XFMR
Figure 2: Synchronous
SMOD[1:0]
Low
Loop-timing
System Reference Clock
SW Control
CKMODE
Reserved
Synchronous Mode
When the NRZ transmit data is source synchronous
with the reference clock applied at CKREFP/N as
shown in Figure 2, the 78P2351R can be optionally
used in synchronous mode or re-timing mode. In
this mode, the 78P2351R will recover the clock from
the NRZ data input and re-time the data in an
integrated +/- 4-bit FIFO.
Since the reference clock and transmit clock/data go
through different delay paths, it is inevitable that the
phase relationship between the two clocks can vary
in a bounded manner due to the fact that the
absolute delays in the two paths can vary over time.
The transmit FIFO allows long-term clock phase drift
between the Tx clock and system reference clock,
not exceeding +/- 25.6ns, to be handled without
transmit error. If the clock wander exceeds the
specified limits, the FIFO will over or under flow, and
the FERR register signal will be asserted. This
signal can be used to trigger an interrupt. This
interrupt event is automatically cleared when a FIFO
Reset (FRST) pulse is applied, and the FIFO is recentered.
Notes:
1) External remote loopbacks (i.e. loopback
within framer) are not possible in
synchronous operation (FIFO enabled)
unless the data is re-justified to be
synchronous to the system reference clock
or the 78P2351R is configured for looptiming operation.
2) During IC power-up or transmit power-up,
the clocks going to the FIFO may not be
stable and cause the FIFO to overflow or
underflow. As such, the FIFO should be
manually reset using FRST anytime the
transmitter is powered-up.
Clock Synthesizer
The transmit clock synthesizer is a low-jitter PLL that
generates a 311.04 MHz clock for the CMI encoder.
A synthesized 155.52 MHz reference clock is also
used in both the receive and transmit sides for clock
and data recovery.
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
Pulse Amplitude Adjustment
Contact TDK applications for information on user
programmable registers with up to 200mV of
programmable transmit gain.
CDR
Transmit Backplane Equalizer
An optional fixed LVPECL equalizer is integrated in
the transmit path for architectures that use LIUs on
active interface cards. The fixed equalizer can
compensate for up to 1.5m of trace and can be
enabled by the TXOUT1 pin or TXEQ bit as follows:
TXOUT1 pin
Low
Float
TXEQ bit
Tx Equalizer
1
0
Enabled
Disabled
CMI
ENDEC
Line-side
Adaptive
Eq.
TD +
TD -
Fixed
Eq.
RD +
RD -
CDR
Figure 3: Remote (analog) Loopback
CDR
Adaptive
Eq.
TD +
TD -
Fixed
Eq.
CMI
ENDEC
CDR
RD +
RD -
POWER-DOWN FUNCTION
Power-down control is provided to allow the
78P2351R to be shut off. Transmit and receive
power-down can be set independently through SW
control.
Global power-down is achieved by
powering down both the transmitter and receiver.
Note: the 4-wire serial port interface and
configuration registers are not affected by powerdown.
The transmitter can also be powered down using the
TXPD control pin. The CMI outputs are tri-stated
during transmit power-down for redundancy
applications.
The TXPD pin is active in both
hardware and software modes.
In SW mode, LLBK and RLBK bits in the Signal
Control register are provided to activate the local
and remote analog loopback modes respectively.
In HW mode, the LPBK pin can be used to activate
local and remote analog loopback paths as shown in
the table below.
Low
Float
High
Page: 6 of 31
In SW mode only, a Full Remote (digital) Loopback
bit FLBK is also available in the Advanced Tx
Control register. This loopback exercises the entire
Rx and Tx paths of the 78P2351 including the Tx
clock recovery unit. As such, the user must enable
either Plesiochronous or Loop-timing transmit modes
to utilize the Full Remote (digital) Loopback.
CDR
Adaptive
Eq.
TD +
TD -
Fixed
Eq.
CMI
ENDEC
Line-side
LOOPBACK MODES
LPBK pin
Figure 4: Local (analog) Loopback
RD +
RD -
CDR
Figure 5: Remote (Digital) Loopback
Loopback Mode
Normal operation
Remote (analog) Loopback:
Recovered receive clock and data
looped back directly to the transmit
driver. The CMI decoder and most of
transmit path is bypassed (including the
redundant Tx monitor output)
Local (analog) Loopback:
Transmit clock and data looped back to
receiver at the analog media interface.
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
SERIAL CONTROL INTERFACE
INTERNAL POWER-ON RESET
Power-On Reset (POR) function is provided on chip.
Roughly 50 µs after Vcc reaches 2.4V at power up,
a reset pulse is internally generated. This resets all
registers to their default values as well as all state
machines within the transceiver to known initial
values. The reset signal is also brought out to the
PORB pin. The PORB pin is a special function
analog pin that allows for the following:
• Override the internal POR signal by driving in
an external active low reset signal;
• Use the internally generated POR signal to
trigger other resets;
• Add external capacitor to slow down the
release of power-on reset (approximately 8µs
per nF added).
NOTE: Do not pull-up the PORB pin to Vcc or drive
this pin high during power-up. This will prevent the
internal reset generator from resetting the entire chip
and may result in errors.
The serial port controlled register allows a generic
controller to interface with the 78P2351R. It is used
for mode settings, diagnostics and test, retrieval of
status and performance information, and for on-chip
fuse trimming during production test. The SPSL pin
must be high in order to use the serial port.
The serial interface consists of 4 pins:
Serial Port Enable (SEN),
Serial Clock (SCK_MON),
Serial Data In (SDI),
Serial Data Out (SDO).
The SEN pin initiates the read and write operations.
It can also be used to select a particular device
allowing SCK_MON, SDI and SDO to be bussed
together.
SCK_MON is the clock input that times the data on
SDI and SDO. Data on SDI is latched in on the
rising-edge of SCK_MON, and data on SDO is
clocked out using the falling edge of SCK_MON.
SDI is used to insert mode, address, and register
data into the chip. Address and Data information
are input least significant bit (LSB) first. The mode
and address bit assignment and register table are
shown in the following section.
SDO is a tristate capable output. It is used to output
register data during a read operation. SDO output is
normally high impedance, and is enabled only during
the duration when register data is being clocked out.
Read data is clocked out least significant bit (LSB)
first.
If SDI coming out of the micro-controller chip is also
tristate capable, SDI and SDO can be connected
together to simplify connections.
The maximum clock frequency for register access is
20MHz.
Page: 7 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
REGISTER DESCRIPTION
REGISTER ADDRESSING
Address Bits
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Port Address
Assignment
PA[3]
PA[2]
Bit 1
Bit 0
Read/
Write
Sub-Address
PA[1]
PA[0]
SA[2]
SA[1]
SA[0]
R/W*
REGISTER TABLE
a) PA[3:0] = 0 : Global Registers
Sub
Addr
0
1
2
Reg.
Name
MSCR
(R/W)
-(R/W)
-(R/W)
Description
Master Control
Reserved
Reserved
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
-<0>
-<0>
-<X>
-<0>
-<0>
-<X>
-<0>
-<1>
-<X>
CKSL[1]
<X>
-<0>
-<X>
CKSL[0]
<X>
-<0>
-<X>
-<X>
-<0>
-<X>
-<X>
-<1>
-<X>
SRST
<0>
-<1>
-<0>
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
MON
<0>
-<0>
-<0>
BST[1]
<0>
-<0>
-<X>
-<0>
-<0>
TPK
<0>
BST[0]
<0>
-<0>
TXLOS
<X>
-<1>
FRST
<0>
TXEQ
<0>
FLBK
<0>
-<0>
FERR
<X>
--
--
--
b) PA[3:0] = 1 : Port-Specific Registers
Sub
Addr
0
1
2
3
4
5
6-7
Reg.
Name
MDCR
(R/W)
SGCR
(R/W)
ACR1
(R/W)
ACR0
(R/W)
-(R/W)
STAT
(R/C)
--
Page: 8 of 31
Description
Mode Control
Signal Control
Advanced Tx
Control 1
Advanced Tx
Control 0
Reserved
Status Monitor
Reserved
Bit 7
PDTX
PDRX
-<0>
<0>
<0>
TCMIINV RCMIINV LOSOR
<0>
<0>
<0>
---<0>
<0>
<0>
---<1>
<0>
<1>
---<1>
<X>
<X>
---<X>
<X>
<X>
--
--
--
SMOD[1] SMOD[0]
<X>
<X>
RLBK
LLBK
<0>
<0>
--<0>
<0>
--<0>
<1>
--<0>
<0>
RXLOS
-<X>
<X>
--
2006 Teridian Semiconductor Corporation
--
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
REGISTER DESCRIPTION (continued)
LEGEND
TYPE
DESCRIPTION
R/O
Read only
R/C
Read and Clear
TYPE
R/W
DESCRIPTION
Read or Write
GLOBAL REGISTERS
ADDRESS 0-0: MASTER CONTROL REGISTER
BIT
NAME
TYPE
DFLT
VALUE
7:5
--
R/W
0X0
DESCRIPTION
Reserved.
4:3
CKSL
[1:0]
R/W
X
Reference Clock Frequency Select:
Selects the reference clock frequency input at CKREFP/N pins.
11: 155.52 MHz (differential LVPECL input)
10: 77.76 MHz (single-ended CMOS input) – Tie CKREFN to ground.
00: 19.44 MHz (single-ended CMOS input) – Tie CKREFN to ground.
Note: Default values depend on the CKSL pin setting upon reset or
power up.
2:1
--
R/W
X0
Reserved.
0
SRST
R/W
0
Register Soft-Reset:
When this bit is set, all registers are reset to their default values. This
register bit is self-clearing.
ADDRESS 0-1: RESERVED
BIT
NAME
TYPE
DFLT
VALUE
7:0
--
R/W
00100X11
DESCRIPTION
Reserved.
ADDRESS 0-2: RESERVED
BIT
NAME
TYPE
DFLT
VALUE
7:0
--
R/W
XXXXXXX0
Page: 9 of 31
DESCRIPTION
Reserved.
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
REGISTER DESCRIPTION (continued)
PORT-SPECIFIC REGISTERS
For PA[3:0] = 1 only. Accessing a register with port address greater than 1 constitutes an invalid command, and
the read/write operation will be ignored.
ADDRESS 1-0: MODE CONTROL REGISTER
BIT
NAME
TYPE
DFLT
VALUE
DESCRIPTION
7
PDTX
R/W
0
Transmitter Power-Down:
0 : Normal Operation
1 : Power-Down. CMI Transmit output is tri-stated.
6
PDRX
R/W
0
Receiver Power-Down:
0 : Normal Operation
1 : Power-Down
5
--
R/W
0
Reserved.
Serial Mode Interface Selection:
SMOD[1] SMOD[0]
0
0
Reserved
4
SMOD[1]
R/W
X
1
0
Synchronous data is passed through the CDR and
then through the FIFO.
0
1
Plesiochronous data is passed through the CDR to
recover a clock, but the FIFO is bypassed because
the data is not synchronous with the reference clock.
1
1
Loop Timing Mode Enable: The recovered receive
clock is used as the reference for the transmit DLL
and FIFO.
Note: Default values depend on the CKMODE pin setting upon reset or
power up.
3
SMOD[0]
R/W
X
2
MON
R/W
0
Receive Monitor Mode Enable:
0: Normal Operation
1: Adds 20dB of flat gain to the receive signal before equalization.
1:0
--
R/W
01
Reserved.
Page: 10 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
REGISTER DESCRIPTION (continued)
ADDRESS 1-1: SIGNAL CONTROL REGISTER
BIT
7
6
5
NAME
TCMIINV
RCMIINV
LOSOR
TYPE
R/W
R/W
R/W
DFLT
VALUE
DESCRIPTION
0
Transmit CMI Inversion:
This bit will flip the polarity of the transmit CMI data outputs at CMIP/N.
For debug use only.
0: Normal
1: Invert
0
Receive CMI Inversion:
This bit will flip the polarity of the receive CMI data inputs at RXP/N. For
debug use only.
0: Normal
1: Invert
0
Receive Loss of Signal Override/Disable:
When set, the LOS signal will always remain low.
0: Normal
1: Forces LOS output to be low and resets counter
Analog Loopback Selection:
RLBK LLBK
0
0
Normal operation
1
0
Remote Loopback Enable: Recovered receive data
is looped back to the transmit driver for retransmission.
0
1
Local Loopback Enable: The transmit data is
looped back and used as the input to the receiver.
4
RLBK
R/W
0
3
LLBK
R/W
0
2:1
--
R/W
00
Reserved.
0
FIFO Reset:
0: Normal operation
1: Reset FIFO pointers to default locations.
This reset should be initiated anytime the transmitter or IC powers up to
ensure the FIFO is centered after internal VCO clocks and external
transmit clocks are stable.
NOTE: FIFO reset not required for Plesiochronous Mode
0
FRST
R/W
ADDRESS 1-2: ADVANCED TRANSMIT CONTROL REGISTER 1
BIT
NAME
TYPE
DFLT
VALUE
DESCRIPTION
7:1
--
R/W
000000
0
Reserved.
0
TXEQ
Page: 11 of 31
R/W
0
Transmit Fixed Equalizer Enable:
When enabled, compensates for between 0.75m and 1.5m of FR4 trace
to the LVPECL data inputs SIDP/N
0: Normal Operation
1: Enable equalizer
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
REGISTER DESCRIPTION (continued)
ADDRESS 1-3: ADVANCED TRANSMIT CONTROL REGISTER 0
BIT
NAME
TYPE
DFLT
VALUE
7:3
--
R/W
10101
2:1
BST[1:0]
R/W
00
0
FLBK
R/W
0
DESCRIPTION
Reserved.
Transmit Driver Amplitude Boost:
Adds 5% or 10% of boost to the CMI output.
00 : Normal amplitude
01 : 5% boost
10 : Reserved
11 : 10% boost
Full Remote (digital) Loopback Enable:
When enabled the recovered receive data is decoded and looped back
to the transmit clock recovery unit exercising the entire receive and
transmit paths.
NOTE: Must be used in conjunction with Plesiochronous Mode or LoopTiming Mode.
ADDRESS 1-4: RESERVED
BIT
NAME
TYPE
DFLT
VALUE
7:0
--
R/W
1XX00000
DESCRIPTION
Reserved.
ADDRESS 1-5: STATUS MONITOR REGISTER
BIT
NAME
TYPE
DFLT
VALUE
7:5
--
R/C
XXX
DESCRIPTION
Reserved.
4
RXLOS
R/C
X
Receive Loss of Signal Indication:
0: Normal operation
1: Loss of signal condition detected at CMI inputs
3:2
--
R/C
X
Reserved.
X
Transmit Loss of Signal Indication:
0: Valid transmit input signal detected at SIDP/N
1: No valid signal detected at SIDP/N
X
Transmit FIFO Error Indication:
This bit is set whenever the internal FERR signal is asserted, indicating
that the FIFO is operating at its depth limit. It is reset to 0 when the
FRST bit is asserted.
0: Normal operation
1: Transmit FIFO phase error
1
0
TXLOS
FERR
Page: 12 of 31
R/C
R/C
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ADDRESS 1-6: TRANSMIT GAIN REGISTER
BIT
NAME
TYPE
DFLT
VALUE
7:0
RSVD
R/O
0
DESCRIPTION
Reserved for pulse amplitude programmability. Contact Teridian
applications support for more information.
ADDRESS 1-7: RESERVED
BIT
NAME
TYPE
DFLT
VALUE
7:0
RSVD
R/O
0
Page: 13 of 31
DESCRIPTION
Reserved for test.
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
PIN DESCRIPTION
LEGEND
TYPE
DESCRIPTION
TYPE
DESCRIPTION
A
Analog Pin
PO
LVPECL-Compatible Differential Output
CIT
3-State CMOS Digital Input
OD
Open-drain Output
CI
CMOS Digital Input
PI
LVPECL-Compatible Differential Input
CID
CMOS Digital Input w/ Pull-down
S
Supply
CIS
CMOS Schmitt Trigger Input
G
Ground
COZ
CMOS Tristate Digital Output
TRANSMITTER PINS
NAME
PIN
TYPE
SIDP
SIDN
4
5
PI
Transmit Serial Data Input:
Differential NRZ data input. See Transmitter Operation section for more info
on different timing modes.
53
54
A
Transmit Serial CMI Data Output:
A CMI encoded data signal conforming to the relevant ITU-T G.703 pulse
templates when properly terminated and transformer coupled to 75ohm
cable.
Notes: 1) Pins are tri-stated during transmit power-down. 2) Pins are
active, but undefined during reset.
NAME
PIN
TYPE
SODP
SODN
13
14
PO
RXP
RXN
50
51
A
CMIP
CMIN
DESCRIPTION
RECEIVER PINS
DESCRIPTION
Receive Serial NRZ Data Output:
Recovered serial data decoded into NRZ format and output at LVPECL levels.
Notes: 1) Outputs are squelched during LOS and held low. 2) Pins are active,
but undefined during reset.
Receive Serial CMI Input:
Receive inputs that should be differentially terminated and transformer
coupled to the coaxial cable.
REFERENCE AND STATUS PINS
NAME
PIN
TYPE
DESCRIPTION
CKREFP
CKREFN
45
44
PI/
CI
Reference Clock Input: (Required)
A reference clock input used for clock/data recovery and generation. Can be
a differential 155.52MHz differential LVPECL Input (Type PI) at CKREFP/N
or a single-ended 19.44MHz or 77.78MHz CMOS Input (Type CI) at
CKREFP (tie CKREFN to ground when unused).
LOS
33
OD
Loss of Signal (active-high):
Standards compatible loss of signal indicator.
PORB
36
A
Page: 14 of 31
Power-On Reset (active low):
See Power-On Reset description on use of this pin. Do not pull-up to Vcc.
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
PIN DESCRIPTION (continued)
CONTROL PINS
NAME
LPBK
CKMODE
TXOUT1
PIN
10
9
56
TYPE
DESCRIPTION
CIT
Loopback Selection:
Low: Normal operation
Float: Remote Loopback Enable: Recovered receive data and clock are
looped back to the transmitter for retransmission.
High: Local Loopback Enable: The transmit data is looped back and used
as the input to the receiver.
CIT
Clock Mode Selection:
Low: Reserved
Float: Reference clock is synchronous to transmit data. Clock is recovered
with a CDR and data is passed through a FIFO
High: Reference clock is plesiochronous to transmit data. Clock is
recovered with a CDR and the FIFO is bypassed
CIT
Advanced Tx Control 1:
Low: Enables fixed LVPECL equalizer at the transmit inputs SIDP/N (for
FR4 trace lengths up to 1.5m).
Float: Normal operation
High: Normal operation
TXOUT0
1
CIT
Advanced Tx Control 0:
Low: Nominal amplitude
Float: 5% amplitude boost
High: 10% amplitude boost
TXPD
8
CID
Transmitter Power Down:
When high, powers down and tri-states the transmit driver.
SPSL
32
CID
Serial Port Selection:
When high, chip is software controlled through the 4-wire serial port.
CIT
Reference Clock Frequency Selection:
Selects the reference frequency that is supplied at the CKREFP/N pins. Its level
is read in at power-up or on the rising edge of a reset signal at the PORB pin.
Low: 19.44MHz
Float: 77.76MHz
High: 155.52MHz
CKSL
Page: 15 of 31
34
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
PIN DESCRIPTION (continued)
SERIAL-PORT PINS
NAME
SEN
SCK_MON
SDI
SDO
PIN
TYPE
CIU
[SPSL=1] Serial-Port Enable:
High during read and write operations. Low disables the serial port.
While SEN is low, SDO remains in high impedance state, and SDI and
SCK activities are ignored.
[SPSL=0] Reserved. Must be tied high
CIS
[SPSL=1] Serial Clock:
Controls the timing of SDI and SDO.
[SPSL=0] Receive Monitor Mode Enable:
When high, adds 20dB of flat gain to the incoming signal before
equalization.
CI
[SPSL=1] Serial Data Input:
Inputs mode and address information. Also inputs register data during
a Write operation. Both address and data are input least significant bit
first.
[SPSL=0] Reserved. Must be tied low
COZ
[SPSL=1] Serial Data Output:
Outputs register information during a Read operation. Data is output
least significant bit first
[SPSL=0] Must be tied low
41
42
40
39
DESCRIPTION
POWER AND GROUND PINS
It is recommended that all supply pins be connected to a single power supply plane and all ground pins be
connected to a single ground plane.
NAME
PIN
TYPE
VCC
2, 6, 11, 31, 38,
43, 48, 52
S
Power Supply (Vdd)
GND
3, 7, 12, 30, 35,
37, 46, 47, 49, 55
G
Ground
Page: 16 of 31
DESCRIPTION
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS
ABSOLUTE MAXIMUM RATINGS
Operation beyond these limits may permanently damage the device.
PARAMETER
RATING
Supply Voltage (Vdd)
-0.5 to 4.0 VDC
Storage Temperature
-65 to 150 °C
Junction Temperature
-40 to 150 °C
Pin Voltage (CMIP,CMIN)
Vdd + 1.5 VDC
Pin Voltage (all other pins)
-0.3 to (Vdd+0.6) VDC
Pin Current
±100 mA
RECOMMENDED OPERATING CONDITIONS
Unless otherwise noted all specifications are valid over these temperatures and supply voltage ranges.
PARAMETER
RATING
DC Voltage Supply (Vdd)
3.15 to 3.45 VDC
Ambient Operating Temperature
-40 to 85°C
Junction Temperature
-40 to 125°C
DC CHARACTERISTICS:
PARAMETER
SYMBOL
CONDITIONS
MIN
NOM
MAX
UNIT
Supply Current
(including transmitter current
through transformer)
Idd
Max cable length
160
180
mA
Receive-only Supply Current
Iddr
Transmitter disabled
(PDTX=1)
92
106
mA
Power down Current
Iddq
PDTX=1, PDRX=1
7
10
mA
Page: 17 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
ANALOG PINS CHARACTERISTICS:
The following table is provided for informative purpose only. Not tested in production.
PARAMETER
RXP and RXN
Common-Mode Bias Voltage
RXP and RXN Differential
Input Impedance
Analog Input/Output
Capacitance
SYMBOL
Vblin
PORB Input Impedance
CONDITIONS
MIN
Ground Reference
1.9
NOM
MAX
UNIT
2.6
V
Rilin
20
kΩ
Cin
8
pF
--
5
kΩ
DIGITAL I/O CHARACTERISTICS:
Pins of type CI, CID:
PARAMETER
SYMBOL
CONDITIONS
MIN
NOM
MAX
UNIT
0.8
V
Input Voltage Low
Vil
Input Voltage High
Vih
2.0
Input Current
Iil, Iih
-1
0
1
µA
Pull-down Resistance
Rpd
40
58
120
kΩ
Input Capacitance
Cin
Type CID only
V
8
pF
Pins of type CIT:
PARAMETER
SYMBOL
CONDITIONS
MIN
NOM
MAX
UNIT
0.4
V
Input Voltage Low
Vtil
Input Voltage High
Vtih
Vcc-0.6
V
Minimum impedance to be
considered as “float” state
Rtiz
30
kΩ
Pins of type CIS:
PARAMETER
SYMBOL
CONDITIONS
MIN
NOM
MAX
UNIT
Low-to-High Threshold
Vt+
1.3
1.7
V
High-to-Low Threshold
Vt-
0.8
1.2
V
Iil, Iih
-1
1
µA
Input Current
Input Capacitance
Cin
8
pF
Pins of type COZ:
PARAMETER
SYMBOL
CONDITIONS
Output Voltage Low
Vol
Iol = 8mA
Output Voltage High
Voh
Ioh = -8mA
Output Transition Time
Effective Source Impedance
Tri-state Output Leakage
Current
Page: 18 of 31
Tt
MIN
NOM
0.4
V
V
2
Rscr
2006 Teridian Semiconductor Corporation
UNIT
2.4
CL = 20pF, 10-90%
Iz
MAX
Ω
30
-1
ns
1
µA
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
DIGITAL I/O CHARACTERISTICS: (continued)
Pins of type PO:
PARAMETER
SYMBOL
Signal Swing
Vpk
Common Mode Level
Vcm
Effective Source Impedance
Reff
CONDITIONS
Vdd referenced
MIN
NOM
MAX
UNIT
0.5
0.8
1.1
V
-1.55
-1.2
-1.1
V
Ω
20
Rise Time
Tr
10-90%
0.8
1.2
ns
Fall Time
Tf
10-90%
0.8
1.2
ns
Pins of type PI:
PARAMETER
Signal Swing
Common Mode Level
SYMBOL
Vpki
CONDITIONS
MIN
0.3
NOM
MAX
UNIT
V
Vcm
Vdd referenced
-1.6
-1.2
-0.8
V
SYMBOL
Vol
CONDITIONS
Iol = 8mA
MIN
NOM
MAX
0.4
UNIT
V
1
nA
10
kΩ
Pins of type OD
PARAMETER
Output Voltage Low
Pull-down Leakage Current
Ipd
Pull-up Resistor
Rpu
Logic high output
4.7
REFERENCE CLOCK CHARACTERISTICS:
PARAMETER
SYMBOL
CKREF Duty Cycle
--
CKREF Frequency Stability
--
CONDITIONS
MIN
NOM
MAX
UNIT
40
60
%
Synchronous mode
-20
+20
Plesiochronous or Loop-timing
mode. (see Note 1)
-75
+75
ppm
Note 1: In Plesiochronous mode, the transmit data source (i.e. framer) must still be of +/-20ppm quality in
order to meet SONET/SDH bit rate requirements.
Page: 19 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
SERIAL-PORT TIMING CHARACTERISTICS:
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNIT
SDI to SCK setup time
tsu
4
ns
SDI to SCK hold time
th
4
ns
SCK to SDO propagation
delay
tprop
10
ns
SCK Frequency
SCK
20
MHz
CS
tsu
th
SCK
tsu th
SDI
X
1
SA0
tprop
SA1
SA2
SDO
PA0
PA1
PA2
PA3
X or Z
Z
D0
D1
D2
D3
D4
D5
D6
D7
Z
Figure 6: Read Operation
CS
tsu
th
SCK
tsu th
SDI
X
0
SDO
SA0
SA1
SA2
PA0
PA1
PA2
PA3
D0
D1
D2
D3
D4
D5
D6
D7
X
Z
Figure 7: Write Operation
Page: 20 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
TRANSMITTER SPECIFICATIONS FOR CMI INTERFACE
Bit Rate: 155.52Mbits/s ± 20ppm
Code: Coded Mark Inversion (CMI)
Relevant Specification: ITU-T G.703, Telcordia GR-253, ANSI T1.102
With the coaxial output port driving a 75Ω load, the output pulses conform to the templates in Figures 8 and 9.
These specifications are tested during production test. Consult application note for reference schematic, layout
guidelines, and recommended transformers.
PARAMETER
CONDITION
MIN
NOM
MAX
UNIT
Peak-to-peak Output Voltage
(Fuse-trimmed to nominal target at
final test)
Template, steady state
0.9
1.04
1.1
V
Rise/ Fall Time
10-90%
2
ns
Transition Timing Tolerance
Negative Transitions
-0.1
0.1
Positive Transitions at Interval
Boundaries
-0.5
0.5
Positive Transitions at midinterval
-0.35
0.35
ns
The following specifications are not tested during production test. They are included for information only.
Note that the return loss depends on the board layout and the particular transformer used.
PARAMETER
CONDITION
Output Impedance
Driver is open drain
Return Loss
7MHz to 240MHz
Page: 21 of 31
2006 Teridian Semiconductor Corporation
MIN
NOM
1
8
15
MAX
UNIT
MΩ
pF
dB
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
V
0.60
0.55
T = 6.43ns
(Note 1)
(Note 1)
0.50
0.45
0.40
1.608ns
1ns
0.1ns
1ns
0.1ns
-0.05
1.608ns
1ns
0.1ns
0.35ns
0.05
Nominal
Pulse
0.1ns
0.35ns
Nominal
Zero Level
(Note 2)
-0.40
1ns
-0.45
1ns
1.608ns
-0.50
-0.55
1.608ns
(Note 1)
-0.60
1ns
(Note 1)
Note 1 – The maximum “steady state” amplitude should not exceed the 0.55V limit. Overshoots and other transients are permitted to fall into
the shaded area bounded by the amplitude levels 0.55V and 0.6V, provided that they do not exceed the steady state level by more than
0.05V.
Note 2 – For all measurements using these masks, the signal should be AC coupled, using a capacitor of not less than 0.01 µF, to the input of
the oscilloscope used for measurements. The nominal zero level for both masks should be aligned with the oscilloscope trace with no input
signal. With the signal then applied, the vertical position of the trace can be adjusted with the objective of meeting the limits of the masks. Any
such adjustment should be the same for both masks and should not exceed ±0.05V. This may be checked by removing the input signal again
and verifying that the trace lies with ±0.05V of the nominal zero level of the masks.
Note 3 – Each pulse in a coded pulse sequence should meet the limits of the relevant mask, irrespective of the state of the preceding or
succeeding pulses, with both pulse masks fixed in the same relation to a common timing reference, i.e. with their nominal start and finish
edges coincident. The masks allow for HF jitter caused by intersymbol interference in the output stage, but not for jitter present in the timing
signal associated with the source of the interface signal. When using an oscilloscope technique to determine pulse compliance with the mask,
it is important that successive traces of the pulses overlay in order to suppress the effects of low frequency jitter. This can be accomplished by
several techniques [e.g. a) triggering the oscilloscope on the measured waveform or b) providing both the oscilloscope and the pulse output
circuits with the same clock signal].
Note 4 – For the purpose of these masks, the rise time and decay time should be measured between –0.4V and 0.4V, and should not exceed
2ns.
Figure 8 – Mask of a Pulse corresponding to a binary Zero.
Page: 22 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
V
0.60
0.55
6.43ns
(Note 1)
(Note 1)
0.50
0.45
0.40
1ns
0.1ns
1ns
0.5ns
0.1ns
0.5ns
Nominal
Pulse
0.05
-0.05
Nominal
Zero Level
(Note 2)
3.215ns
3.215ns
1.2ns
-0.40
1.2ns
1ns
-0.45
1ns
1.608ns
-0.50
-0.55
1.608ns
(Note 1)
-0.60
Note 1 – The maximum “steady state” amplitude should not exceed the 0.55V limit. Overshoots and other transients are permitted to fall into
the shaded area bounded by the amplitude levels 0.55V and 0.6V, provided that they do not exceed the steady state level by more than
0.05V.
Note 2 – For all measurements using these masks, the signal should be AC coupled, using a capacitor of not less than 0.01 µF, to the input of
the oscilloscope used for measurements. The nominal zero level for both masks should be aligned with the oscilloscope trace with no input
signal. With the signal then applied, the vertical position of the trace can be adjusted with the objective of meeting the limits of the masks. Any
such adjustment should be the same for both masks and should not exceed ±0.05V. This may be checked by removing the input signal again
and verifying that the trace lies with ±0.05V of the nominal zero level of the masks.
Note 3 – Each pulse in a coded pulse sequence should meet the limits of the relevant mask, irrespective of the state of the preceding or
succeeding pulses, with both pulse masks fixed in the same relation to a common timing reference, i.e. with their nominal start and finish
edges coincident. The masks allow for HF jitter caused by intersymbol interference in the output stage, but not for jitter present in the timing
signal associated with the source of the interface signal. When using an oscilloscope technique to determine pulse compliance with the mask,
it is important that successive traces of the pulses overlay in order to suppress the effects of low frequency jitter. This can be accomplished by
several techniques [e.g. a) triggering the oscilloscope on the measured waveform or b) providing both the oscilloscope and the pulse output
circuits with the same clock signal].
Note 4 – For the purpose of these masks, the rise time and decay time should be measured between –0.4V and 0.4V, and should not exceed
2ns.
Note 5 –The inverse pulse will have the same characteristics, noting that the timing tolerance at the level of the negative and positive
transitions are ± 0.1ns and ±0.5ns respectively.
Figure 9 – Mask of a Pulse corresponding to a binary One
Page: 23 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
TRANSMITTER OUTPUT JITTER
The transmit jitter specification ensures compliance with ITU-T G.813, G.823, G.825 and G.958; ANSI T1.1021993 and T1.105.03-1994; and GR-253-CORE for all supported rates. Transmit output jitter is not tested during
production test.
Jitter
Detector
Measured Jitter
Amplitude
20dB/decade
Transmitter
Output
f1
f2
PARAMETER
CONDITION
Transmitter Output Jitter
200 Hz to 3.5 MHz, measured
with respect to CKREF for 60s
Page: 24 of 31
2006 Teridian Semiconductor Corporation
MIN
NOM
MAX
UNIT
0.075
UIpp
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
RECEIVER SPECIFICATIONS FOR CMI INTERFACE (Transformer-coupled)
Consult application notes for reference schematic, layout guidelines, and recommended transformers.
PARAMETER
CONDITION
Peak Differential Input
Amplitude, RXP and RXN
Peak Differential Input
Amplitude, RXP and RXN
Flat-loss Tolerance
MIN
TYP
UNIT
MON=0. 12.7dB of cable loss
70
550
mVpk
MON=1. 20dB flat loss with 6dB
cable loss (max)
25
80
mVpk
MON=0. All valid cable lengths.
-2
4
dB
10
10
UI
Latency
PLL Lock Time
5
1
Return Loss
MAX
7MHz to 240MHz
15
µs
dB
The input signal is assumed compliant with ITU-T G.703 and can be attenuated by the dispersive loss of a
cable. The minimum cable loss is 0dB and the maximum is –12.7dB at 78MHz.
The “Worst Case” line corresponds to the ITU-T G.703 recommendation. The “Typical” line corresponds to a
typical installation referred to in ANSI T1.102-1993. The receiver is tested using the cable model. It is a lumped
element approximation of the “Worst Case” line.
30
Attenuation (dB)
25
20
15
10
5
0
1.00E+05
1.00E+06
1.00E+07
1.00E+08
1.00E+09
Frequency (Hz)
Worst Case
Typical
Figure 10: Typical and worst-case Cable attenuation
Page: 25 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
RECEIVER JITTER TOLERANCE
The 78P2351R exceeds all relevant jitter tolerance specifications shown in Figure 11. STM-1e (electrical) jitter
tolerance specifications are in ITU-T G.825. Receive jitter tolerance is not tested during production test.
100
155Mbps Electrical (CMI) Interfaces
G.825 - STM-1e Tolerance
(for 2048 kbps networks)
G.825 - STM-1e Tolerance
(for 1544 kbps networks)
Jitter Tolerance ( UIpp )
10
1
0.1
0.01
1.E+00
10Hz
100Hz
1kHz
10kHz
100kHz
1MHz
10MHz
Jitter Frequency
Figure 11: Jitter Tolerance - electrical (CMI) interfaces
PARAMETER
CONDITION
MIN
10Hz to 19.3Hz
38.9
19.3Hz to 500Hz
STM-1e Jitter Tolerance
500Hz to 6.5kHz
1.5
Page: 26 of 31
2006 Teridian Semiconductor Corporation
UNIT
µs
UIpp
9800 f-1
0.15
MAX
UIpp
750 f-1
6.5kHz to 65kHz
65kHz to 1.3MHz
NOM
µs
UIpp
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
RECEIVER JITTER TRANSFER FUNCTION
The receiver clock recovery loop filter characteristics such that the receiver has the following transfer function.
The corner frequency of the Rx DLL is approximately 120 kHz. Receiver jitter transfer function is not tested
during production test.
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
1.00E+03
1.00E+04
1.00E+05
1.00E+06
1.00E+07
Figure 12: Jitter Transfer
PARAMETER
CONDITION
Receiver Jitter transfer function
below 120 kHz
Jitter transfer function roll-off
Page: 27 of 31
MIN
NOM
20
2006 Teridian Semiconductor Corporation
MAX
UNIT
0.1
dB
dB per
decade
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
ELECTRICAL SPECIFICATIONS (continued)
LOSS OF SIGNAL CONDITION
PARAMETER
CONDITION
LOS threshold
LOS timing
MIN
TYP
MAX
UNIT
-35
10
-19
110
-15
255
dB
UI
Nominal value
Maximum
cable loss
3 dB
15dB
Loss of Signal must be cleared
Tolerance range
LOS can be detected or cleared
35dB
Loss of Signal must be declared
APPLICATION INFORMATION
EXTERNAL COMPONENTS:
COMPONENT
PIN(S)
RXP
RXN
CMIP
CMIN
Receiver Termination Resistor
Transmitter Termination Resistor
VALUE
UNITS
TOLERANCE
75
Ω
1%
75
Ω
1%
VALUE
UNITS
TOLERANCE
TRANSFORMER SPECIFICATIONS:
COMPONENT
Turns Ratio for the Receiver
1:1
Turns Ratio for the Transmitter (center-tapped)
Suggested Manufacturers: Halo, MiniCircuits, Tamura, Belfuse
1:1CT
THERMAL INFORMATION:
PACKAGE
Standard 56-pin JEDEC QFN
CONDITIONS
No forced air;
4-layer JEDEC test board
No forced air;
4-layer JEDEC test board
Die attach pad soldered to PCB
ΘJA ( ˚C/W)
ΘJC ( ˚C/W)
46.8
16.6
23.5
15.6
SCHEMATICS
For reference schematics, layout guidelines, suggested transformer part numbers, etc. please check Teridian
Semiconductor's website or contact your local sales representative for the latest application note(s) and/or
evaluation boards.
Page: 28 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
MECHANICAL SPECIFICATIONS
7.000
0.90 MAX
3.500
6.750
0.05 MAX
3.375
SEATING
PLANE
1
0.40
6.750
6.750
3.375
3.500
0.23 ± 0.05
0 =12
TOP VIEW
SIDE VIEW
5.200
5.10 ± 0.15
0.25 MIN.
2.55 ± 0.075
1
2.55 ± 0.075
5.10 ± 0.15
5.200
0.400 ± 0.100
BOTTOM VIEW
56-pin Quad Flat No-lead package (QFN)
(All dimensions in mm)
Page: 29 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
PACKAGE INFORMATION
TXOU1
GND
CMIN
CMIP
VCC
RXN
RXP
GND
VCC
GND
GND
CKREFP
CKREFN
VCC
(Top View)
56 55 54 53 52 51 50 49 48 47 46 45 44 43
TXOUT0
VCC
GND
SIDP
SIDN
VCC
GND
TXPD
CKMODE
LPBK
VCC
GND
SODP
SODN
1
42
2
41
3
40
4
39
5
38
6
37
7
36
78P2351R-IM
8
35
9
34
10
33
11
32
12
31
13
30
14
29
15
SCK_MON
SEN
SDI
SDO
VCC
GND
PORB
GND
CKSL
LOS
SPSL
VCC
GND
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
28
ORDERING INFORMATION
PART DESCRIPTION
56-pin QFN; Revision A06
ORDER NUMBER
78P2351R-IM
Tape & Reel option
append ‘R’
Lead-free option
append ‘/F’
Page: 30 of 31
2006 Teridian Semiconductor Corporation
PACKAGE MARK
78P2351R-IM
xxxxxxxxxxP6
n/a
xxxxxxx-xxx
xxxxxxxxxxP6F
Rev. 2.1
78P2351R
Serial 155M
NRZ to CMI Converter
--
v2-0
v2-1
Revision History
Contact Teridian for revision history of earlier releases
August 15, 2005: Final Datasheet Release
Updated Ordering Numbers to reflect production silicon revision A06
Improved/modified Functional Descriptions
Improved/modified Register Descriptions
Added FLBK bit
Removed Rx LOL bit
Improved/modified Pin Descriptions
Updated Electrical Specification min/max limits for:
DC Characteristics,
CID, CIU, CIT, and PO pin types
CMI Loss of Signal Conditions
Changed name and logo from TDK to Teridian
August 15, 2006:
Updated Ordering Numbers to remove silicon revision A06
Updated Package Mark from C6 to P6
If and when manufactured and sold, this product is sold subject to the terms and conditions of sale supplied at the time of order
acknowledgment, including those pertaining to warranty, patent infringement and limitation of liability. Teridian Semiconductor Corporation
(TSC) reserves the right to make changes in specifications at any time without notice. Accordingly, the reader is cautioned to verify that a
data sheet is current before placing orders. TSC assumes no liability for applications assistance.
Teridian Semiconductor Corp., 6440 Oak Canyon Rd., Irvine, CA 92618
TEL (714) 508-8800, FAX (714) 508-8877, http://www.teridian.com
Page: 31 of 31
2006 Teridian Semiconductor Corporation
Rev. 2.1