300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
REFERENCE DOCUMENT FOR 300 PIN 10Gb TRANSPONDER
Description
This technical document has been created by the 300PIN MSA group. This document is offered to
transponder users and suppliers as a basis for a technical agreement. However it is not a warranted
document, each transponder supplier will have their own datasheet. If the user wishes to find a warranted
document they should consult the datasheet of the chosen transponder supplier.
The MSA group reserves the rights at any time to add, amend or withdraw technical data contained in this
document.
MSA Group Contacts
Agere Systems
Agilent
Alcatel Optronics
Ericsson Optoelectronics
AB
ExceLight
Fujitsu Quantum Devices
JDS Uniphase
Mitsubishi Electric
NEC
Nortel Networks
OpNext
Nuri Dagdeviren
Dan Rausch
Arnaud Fardoit
Elisabeth Söderlund
nuri@agere.com
dan_rausch@agilent.com
arnaud.fardoit@alcatel.fr
elisabeth.soderlund@mic.ericsson.se
Gregg Cockroft
Masahiru Kobayashi
Jeff Rollman
Toshiyuki Hirai
Tetsuyuki Suzaki
Peter Dartnell
Atsushi Takai
gcockroft@excelight.com
m.kabayashi@fqd.fujitsu.com
jeff.rollman@us.jdsuniphase.com
Toshiyuki.Hirai@kama.melco.co.jp
tet-suzaki@cj.jp.nec.com
dartnell@nortelnetworks.com
atsushi.takai@opnext.com
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10
Public Document Edition 4
REFERENCE DOCUMENT FOR 300PIN 10Gb TRANSPONDER
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A printed version of this document is an uncontrolled copy
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14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
CAUTION :
Components within the scope of this 10 Gbit/s SERDES TRANSCEIVER MULTI SOURCE are
electrostatically sensitive and should not be handled except at a static free workstation.
Invisible laser radiation, avoid direct exposure to beam.
TABLE OF CONTENTS
HISTORY ................................................................................................................................................................ 3
TABLES LIST ........................................................................................................................................................... 4
REFERENCE DOCUMENTS.................................................................................................................................... 6
GLOSSARY ............................................................................................................................................................. 6
1
1.1
1.2
1.3
1.4
1.5
1.6
1.7
OPTICAL CHARACTERISTICS ....................................................................................................................... 7
INTERCONNECTION / VERY SHORT REACH : I-64.1R/VSR-1................................................................................................... 7
INTRA-OFFICE / SHORT-REACH : I-64.1/SR-1ANDI-64.2/SR-2 .............................................................................................. 7
SHORT-HAUL / INTERMEDIATE-REACH : S-64.1/IR-1ANDS-64.2/IR-2.................................................................................. 7
65 KM APPLICATION : MSA PROPOSAL .................................................................................................................................. 7
LONG HAUL / LONG REACH : FFS ........................................................................................................................................... 7
D-WDM APPLICATION ............................................................................................................................................................. 7
OPTICAL MEASUREMENT CONDITIONS .................................................................................................................................... 9
2
QUALIFICATION REFERENCE ....................................................................................................................... 9
3
ELECTRICAL CHARACTERISTICS............................................................................................................... 10
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
4
4.1
4.2
4.3
OPERATING TEMPERATURE..................................................................................................................................................... 10
ELECTRICAL POWER SUPPLIES ................................................................................................................................................ 10
FRAMER TO TRANSCEIVER INTERFACE .................................................................................................................................. 13
DIAGNOSTIC SIGNALS ............................................................................................................................................................. 15
TUNABLE LASER MONITOR : LSWAVEMON ...................................................................................................................... 21
ELECTRICAL INPUT & OUTPUT SIGNALS ................................................................................................................................ 22
ALARMS.................................................................................................................................................................................... 27
JITTER CHARACTERISTICS ........................................................................................................................................................ 28
MECHANICAL DIMENSION....................................................................................................................... 28
TRANSCEIVER PACKAGE DRAWING (FROM UNDERNEATH TO SHOW ELECTRICAL CONNECTOR) .................................... 28
TRACE AREA AND FIBER KEEP OUT ZONE FOR CUSTOMER BOARD ..................................................................................... 30
CONNECTOR DESCRIPTION .................................................................................................................................................... 32
5
FIRMWARE INTERFACE WITH I2C BUS ................................................................................................... 32
6
PIN ASSIGNMENT ...................................................................................................................................... 33
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.1
6.2
6.3
6.4
TOP VIEW FROM CUSTOMER LINE CARD ............................................................................................................................... 33
TRUTH TABLES ......................................................................................................................................................................... 34
INPUT & OUTPUT TERMINATION DESCRIPTION ................................................................................................................... 36
DETAILED PIN DESCRIPTION ................................................................................................................................................... 38
HISTORY
Edition 1: April 16, 2001
Edition 2: August 1, Incorporate changes made at the Atlanta MSA meeting
– Never Released
Edition 3: February 11, 2002 - Incorporate changes made at the Kamakura MSA meeting
Edition 4: August 14, 2002 - Incorporate changes made at the Melbourne, FL MSA meeting.
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
TABLES LIST
Table 1 – 1.5µ 65 km application ...................................................................................................................................................... 7
Table 2 : Available wavelengths ......................................................................................................................................................... 9
Table 3 - Electrical power supplies ................................................................................................................................................ 10
Table 4 - Resistor Values for R1*.................................................................................................................................................... 11
Table 5 - Recommended Tolerances (+/-) ................................................................................................................................. 12
Table 6 - APS Tolerances (+/-) ........................................................................................................................................................ 12
Table 7 - Input Data/Clock phase in 622 MHz mode............................................................................................................. 14
Table 8 - Input Data/Clock phase in 311 MHz mode............................................................................................................. 15
Table 9 - Output Data/Clock phase .............................................................................................................................................. 15
Table 10 : Line Loopback : LLOOPENB ......................................................................................................................................... 16
Table 11 - Diagnostic Loopback : DLOOPENB .......................................................................................................................... 17
Table 12 - : TxLINETIMSEL ............................................................................................................................................................... 19
Table 13 : Simultaneous solutions ................................................................................................................................................. 19
Table 14 : Scale factor versus applications ................................................................................................................................. 21
Table 15 - Digital signal characteristics ....................................................................................................................................... 22
Table 16 - Analog signal characteristics ...................................................................................................................................... 25
Table 17 - Alarms and Control response time .......................................................................................................................... 28
Table 18 –Cooled and Uncooled Transceiver connector and holes position dimensions ....................................... 29
Table 19 -Cooled and Uncooled Transceiver module size dimensions .......................................................................... 29
Table 20 – Uncooled and Cooled SFF Transceiver connector and holes position dimensions ............................. 29
Table 21 –Uncooled and Cooled SFF Transceiver module size dimensions ................................................................. 30
Table 22 – Cooled and Uncooled Transceiver trace area dimensions on user’s PCB ................................................ 31
Table 23 – Cooled and Uncooled Transceiver module area and fibers zone dimensions on user’s PCB .......... 31
Table 24 – Uncooled and Cooled SFF Transceiver trace area dimensions on user’s PCB ........................................ 31
Table 25 – Uncooled and Cooled SFF Transceiver module area and fibers zone dimensions on user’s PCB .. 31
Table 26 - Top view from customer line card ........................................................................................................................... 33
Table 27 - Truth tables ....................................................................................................................................................................... 35
Table 28 - Input & output termination description ................................................................................................................ 37
Table 29 - “Row A” description ....................................................................................................................................................... 39
Table 30 - “Row B” description ....................................................................................................................................................... 40
Table 31 - “Row C” description ....................................................................................................................................................... 41
Table 32 - “Row D” description....................................................................................................................................................... 42
Table 33 - “Row E” description ....................................................................................................................................................... 43
Table 34 - “Row F” description........................................................................................................................................................ 44
Table 35 - “Row G” description ....................................................................................................................................................... 45
Table 36 - “Row H” description....................................................................................................................................................... 46
Table 37 - “Row J” description ........................................................................................................................................................ 47
Table 38 - “Row K” description ....................................................................................................................................................... 48
Figure 1 - APS Conceptual Implementation .............................................................................................................................. 11
Figure 2 - Proposed APS Implementation for 1.8A supply. ................................................................................................. 13
Figure 3 - Schematic Diagram of Framer to Transceiver Interface ................................................................................... 14
Figure 4 - Input Data/Clock phase in 622 MHz mode ........................................................................................................... 14
Figure 5 - Input Data/Clock phase in 311 MHz mode ........................................................................................................... 15
Figure 6 - Output Data/Clock phase............................................................................................................................................. 15
Figure 7 : Line Loopback ................................................................................................................................................................... 17
Figure 8 - Diagnostic Loopback ..................................................................................................................................................... 18
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Figure 9 – Line Timing Select control ........................................................................................................................................... 19
Figure 10 – DLOOPENB + LLOOPENB.......................................................................................................................................... 20
Figure 11 – LLOOPENB + TxLINETIMSEL..................................................................................................................................... 20
Figure 12 – DLOOPENB + TxLINETIMSEL ................................................................................................................................... 21
Figure 13 - Receiver Decision Threshold definition ................................................................................................................ 25
Figure 14 – Transceiver package drawing .................................................................................................................................. 28
Figure 15 - Trace area and fiber keep out zone for customer board .............................................................................. 30
Figure 16 - LVTTL with pull-up termination ............................................................................................................................... 37
Figure 17 - LVTTL with pull-down termination ......................................................................................................................... 38
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
REFERENCE DOCUMENTS
[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
[9]
[10]
[11]
Telcordia GR-253 edition 3
ITU-T G.957
ITU-T G.783
ITU-T G.691
ITU-T G.692
ITU-T G.693
OIF Implementation Agreement: OIF-SFI4-01.0 26 September 2000
IEEE 802.3ae Draft 4.0
Telcordia GR-63-CORE NEBS
Telcordia GR-468-CORE
MSA_10G_40G_TRX_I2C_Public Document
GLOSSARY
ITU-T
SONET
SDH
WDM
OIF
EDFA
PRBS
TEC
FFS
APS
International Telecommunication Union - Telecommunication
Synchronous Optical Digital Network
Synchronous Digital Hierarchy
Wavelength Division Multiplexed
Optical Internetworking Forum
Erbium Doped Fiber Amplifier
Pseudo Random Binary Sequence
Thermo Electric Cooler
For Future Study
Adaptable Power Supply
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Public
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
1
OPTICAL CHARACTERISTICS
The specifications these transponders will address can be found in reference documents for Telcordia GR253, IEEE 802.3ae Draft4.0, ITU-T G.691, ITU-T G.692 and ITU-T G.693.
All min and max. parameters are specified End-of-Life within the overall relevant operating case
temperature range 0…+65°C unless otherwise stated.
The typical values are referenced to +25°C, nominal power supply, beginning of life.
1.1
Interconnection / Very Short Reach : I-64.1r / VSR-1
1.2
Intra-Office / Short-Reach : I-64.1 / SR-1 and I-64.2 / SR-2
1.3
Short-Haul / Intermediate-Reach : S-64.1 / IR-1 and S-64.2 / IR-2
1.4
65 km application : MSA proposal
Parameter
10Gb MSA l
Target distance
Optical budget
Dispersion
Transmitter
Center wavelength
Optical output power
Spectral width
Extinction ratio
Receiver
Receiver sensitivity
Receiver overload
Path penalty
Cond.
Symb
Min
Typ
Max
Unit
11
17
1300
Km
dB
ps/nm
c
Snom

Er
1530
-2
1565
+2
Rnom
Rnom
- 21
-9
65

TBD
10
2
nm
dBm
nm
dB
dBm
dBm
dB
Table 1 – 1.5µ 65 km application
Specifications may change in near future. These values are suggested due to the APD-Preamp sensitivity
guaranteed by the module suppliers today.
1.5
Long Haul / Long Reach : FFS
1.6
D-WDM application
The definition of grid is based on the ITU-T grid from 1528.77 nm to 1563.86 nm with 50 GHz spacing L and
S band are for further study.
Nominal
Wavelength
nm
Optical
Frequency
THz
Nominal
Wavelength
nm
Optical
Frequency
THz
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
1528.77
196.10
1546.92
193.80
1529.16
196.05
1547.32
193.75
1529.55
196.00
1547.72
193.70
1529.94
195.95
1548.11
193.65
1530.33
195.90
1548.51
193.60
1530.72
195.85
1548.91
193.55
1531.12
195.80
1549.32
193.50
1531.51
195.75
1549.72
193.45
1531.90
195.70
1550.12
193.40
1532.29
195.65
1550.52
193.35
1532.68
195.60
1550.92
193.30
1533.07
195.55
1551.32
193.25
1533.47
195.50
1551.72
193.20
1533.86
195.45
1552.12
193.15
1534.25
195.40
1552.52
193.10
1534.64
195.35
1552.93
193.05
1535.04
195.30
1553.33
193.00
1535.43
195.25
1553.73
192.95
1535.82
195.20
1554.13
192.90
1536.22
195.15
1554.54
192.85
1536.61
195.10
1554.94
192.80
1537.00
195.05
1555.34
192.75
1537.40
195.00
1555.75
192.70
1537.79
194.95
1556.15
192.65
1538.19
194.90
1556.55
192.60
1538.58
194.85
1556.96
192.55
1538.98
194.80
1557.36
192.50
1539.37
194.75
1557.77
192.45
1539.77
194.70
1558.17
192.40
1540.16
194.65
1558.58
192.35
1540.56
194.60
1558.98
192.30
1540.95
194.55
1559.39
192.25
1541.35
194.50
1559.79
192.20
1541.75
194.45
1560.20
192.15
1542.14
194.40
1560.61
192.10
1542.54
194.35
1561.01
192.05
1542.94
194.30
1561.42
192.00
1543.33
194.25
1561.83
191.95
1543.73
194.20
1562.23
191.90
1544.13
194.15
1562.64
191.85
1544.53
194.10
1563.05
191.80
1544.92
194.05
1563.45
191.75
1545.32
194.00
1563.86
191.70
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
1545.72
193.95
1546.12
193.90
1546.52
193.85
Table 2 : Available wavelengths
The channels are listed by increasing wavelength (decreasing frequency). That means that if channel n is
1545.32 nm, channel n+1 is 1545.72nm.
In case of tunable transponders :
For 100 GHz spacing transponders with
two tunable wavelenghts, the nominal channel n and the second greater n+2 are used.
- three tunable wavelengths, the nominal channel n, the second greater n+2 and the lower n-2 are
used.
- four tunable wavelengths, the nominal channel n, the second greater n+2, the lower n-2 and the
greater n+4 are used.
For 50 GHz spacing transponders with
two tunable wavelenghts, the nominal channel n and the second greater n+1 are used.
- three tunable wavelengths, the nominal channel n, the second greater n+1 and the lower n-1 are
used.
- four tunable wavelengths, the nominal channel n, the second greater n+1, the lower n-1 and the
greater n+2 are used. Etc…
1.7
Optical measurement conditions
1.7.1 Extinction ratio measurement conditions
Extinction ratio measurement should be per TIA OFSTP4A (Optical Fibre Standard Test Procedure). This
requires testing with a fourth order Bessel-Thompson filter at OC-192 bit rate (9.95Gb/sec) with a PRBS of
223-1 data pattern.
1.7.2 Sensitivity measurement conditions
Sensitivity measurements should ideally be conducted with a BERT transmitter that matches the type of
transmitter inside the Transponder module. Golden transmitters with high extinction ratios used for receiver
sensitivity measurements can give misleading results if the device will receive a low extinction ratio
transmitted signal when used in the field.
1.7.3 Eye mask measurement conditions
Transmitter module should pass OC192 SONET Tx eye mask test per ITU-G.691 and G.693 using PRBS
pattern of 2E23-1 and 200 waveforms minimum.
2
QUALIFICATION REFERENCE
All optoelectronic devices used within the 10Gbit/s SERDES transceiver shall meet the reliability
requirements as specified per Telcordia GR-468-CORE (Generic Reliability Assurance Requirements for
Optoelectronic Devices Used in Telecommunications Equipment).
In addition, the SERDES transceivers are intended for use in equipment to be qualified per Telcordia GR-63CORE Network Equipment-Building System (NEBS) Requirements for Physical Protection.
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Public
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
3
3.1
ELECTRICAL CHARACTERISTICS
Operating temperature
All min and max parameters are specified End-of-Life within the overall relevant operating case temperature
range 0…+65°C unless otherwise stated.
The typical values are referenced to +25°C, nominal power supply, beginning of life.
Customer must use the appropriate heat sink to make the case temperature within the recommended
operating limits.
3.2
Electrical power supplies
Transponder should work regardless of the power up sequence. This means that the -5.2V, APS, +3.3V, and
+5.0V power supplies may be turned on in any sequence and the transponder should still function correctly.
Parameters
Cond
Symb
Min
Typ
Max
Unit
Positive supply 1 voltage
VCC
4.75
5.0
5.25
V
Positive supply 1 current
ICC
200
800
mA
Positive supply 2 voltage
VDD1
3.13
3.3
3.47
V
Positive supply 2 current
IDD1
1400
3000
mA
Negative supply voltage
VEE
- 4.94
- 5.2
- 5.45
V
Negative supply current
IEE
1200
1800
mA
APS Supply voltage
Note 1
VAPS
0.9
2.5
V
APS Supply current
Note 1
IAPS
1800
mA
Power dissipation
8
14
W
Note 1 – These APS power supplies are not required at present. The default value is assumed to be a fixed
1.8V supply unless APS is implemented. They have been listed as a reminder that overall voltage
levels for Ics are likely to decrease in the future. See Section 3.2.1 for a description of the
adaptable power supply.
Table 3 - Electrical power supplies
3.2.1 Adaptable Power Supply
This section describes the implementation of the adaptable power supply (APS) on the transponder. The
power supply will replace the existing 1.8V supplies for the transmitter and the receiver with a single
adaptable supply. The APS will be capable of adjusting from a high of 2.5 volts to a low of 0.9 volts. The
transponder module shall support a voltage sense pin for the APS on the “APS Sense” pin (Pin No. J10). This
will be tied to the APS power supply rail inside the transponder. The receiver side (F1 and F2) and the
transmitter side (F16 and F17) APS supply pins shall be connected inside the transponder module to a
common supply rail. The transponder module shall also incorporate an “APS Set” pin (Pin No. J11), with a
resistor R1 between the APS set pin and ground. Resistor values, for R1 that are necessary to produce the
required APS supply voltage, are indicated in Table 1. If the pin used for APS SET is shorted to ground on
the module, the APS will default to a fixed value of 2.5 volts.
The APS sense does not compensate for voltage drops on the ground plane and ground pins of the
connector. A maximum voltage drop of 8 mV is allowable in the ground return path to meet the specified
tolerances.
The host will provide < 200 mV to the adaptable voltage rail when no transponder module is installed or
when the APS set pin is an open circuit. The APS is intended to default to a low voltage output if any single
pin makes a poor connection, specifically:
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
• If the APS SET connection is open, the APS supply will put out near zero volts due to the 500 ohm pull-up
resistor to 3.3 volts (see
Figure 1).
• If the APS Sense pin is open, the supply defaults to low voltage.
R2=470 , R3=1000 
Resistor R1 ()
Vout (V)
7530
0.9
1530
1.2
672
1.5
330
1.8
0
2.5
Table 4 - Resistor Values for R1*
* These values may need to be adjusted slightly to compensate for increased voltage drop in the ground
return path.
Power Module
OUT
0.9 to 2.5
Volts
0.2 to 1.8
Amps
APS Digital
3.3v
APS Sense
Jumper
500 ohm
LOAD
APS Sense
1 K ohm
470 ohm
Vfeedback
of 0.8 v
APS Set
APS Set
Jumper
0 ohm -> 2.5 V
7530 ohm -> 0.9 V
330 ohm
RUN/SS
GND
Optional Host
Control
Figure 1 - APS Conceptual Implementation
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Adaptable Power Supply Reference
The APS supply on the host will regulate the APS voltage such that the voltage on the network labeled
"Vfeedback" in
Figure 1 remains nominally 0.8 volts unless an APS voltage or current limiting condition takes priority. The
resistors in Table 4 are calculated using 1% values. For tolerance purposes, it is recommended that 0.1%
resistors be used to provide additional tolerance margin. Recommended tolerances are shown in Table 5.
Supply precision
1.5%
Supply load regulation
0.3%
Ground plane and ground connector drop
1.0%
Resistor tolerances using 0.1% parts
0.3%
Margin
0.9%
Total APS tolerance (+/-)
4.0%
Table 5 - Recommended Tolerances (+/-)
3.2.2 Voltage calculation
The circuit shown in Figure 2 depicts one possible design that can be used to generate the APS voltage.
Exact implementation and component values are not mandatory on the host. The APS implementer is
responsible for ensuring that the transponder module is supplied in a manner which conforms to the
voltage values in Table 4 and the APS tolerances stated in Table 6 for any given resistance between the
module set pin and module ground.
Current capability of the APS
The APS will provide from 0.2 to 1.8 amperes and will current limit between 2 and 3 amperes.
Adaptable Power Supply Specs/Requirements
The host PCB will provide a steady state voltage on the adaptable voltage power conforming to the
specifications given in Table 6.
APS steady state peak to peak ripple
APS tolerance for a given resistance from APS set to
ground.
APS max overshoot after host power up
APS min rated current
APS maximum rated current for any voltage
APS current limit
TRANSPONDER total capacitance of transceiver APS
power pins
2%
+/- 3%
3% of V steady state
0.2 Amps
1.8 Amps
2 -> 3 Amps
<200 uF
Table 6 - APS Tolerances (+/-)
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Figure 2 - Proposed APS Implementation for 1.8A supply.
3.2.3 Non-APS Compliant Transponders
For compatibility with transponders that do not have an APS implementation the host board must
incorporate a pair of jumpers for the set and sense signals and a 330 ohm resistor which will configure the
host APS supply for a fixed 1.8V output. When a non-APS compliant transponder is installed the SET and
SENSE jumpers will be shorted. The SENSE jumper connects the APS SENSE signal directly to the APS output
power supply. This provides the feedback loop for the regulator. The SET jumper connects the APS SET
signal to a 330 ohm SET resistor which selects the 1.8V output level. For standard operation with an APS
compliant transponder both of the SET and SENSE jumpers must be open. Note that for non-APS compliant
transponders the receive side and transmit side power supplies need not be connected inside the
transponder module.
3.2.4 Potential Licensing Issues
It should be noted that there is a possibility that part or all of the APS circuitry is covered by patents or
patent applications owned by Agere. It is suggested that potential users of the APS contact Agere directly
to determine the status of such patents.
3.3
Framer to Transceiver Interface
The framer to Transceiver electrical interface should conform to guidelines outlined in Optical
Internetworking Forum document OIF-SFI4-01.0 26 September 2000 : Common electrical interface between
framers and serializer/deserializer parts for OC-192/STM-64 interfaces.
Note : IEEE P802.3 ae Clause 51 defines 10GbE LAN/WAN application as follows : Tx_Data_Group bit 0
directly maps into Bit 15 of the XSBI Physical Interface into the Transponder. This implies that both the SFI-4
and the XSBI Bit 15 is the MSB and the first to be serialized onto the fiber.
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
TxREFCLK
SONET Framer
STM-64 / OC-192
SERDES
TxDin
TxPICLK
TxMCLK
TxPCLK
RxDout
RxPOCLK
RxMCLK
RxREFCLK
Figure 3 - Schematic Diagram of Framer to Transceiver Interface
TxMCLK can be used to substitute for RxREFCLK if required.
3.3.1
Input Data/Clock phase in 622 MHz mode
Figure 4 - Input Data/Clock phase in 622 MHz mode
Parameter
T0
TW/T0
Tr, Tf
Tsetup, Thold
Description
Min
Clock period
Duty cycle
0.4
20-80% rise/fall times 100
Setup time, hold time
Typ
1.608
Max
Unit
ns
0.6
300
300, 300
ps
ps
Table 7 - Input Data/Clock phase in 622 MHz mode
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
3.3.2
Input Data/Clock phase in 311 MHz mode
Figure 5 - Input Data/Clock phase in 311 MHz mode
Parameter
T0
TW/T0
Tr, Tf
Tsetup
Thold
T_dib, T_dia
Description
Clock period
Duty cycle
20-80% rise/fall times
Setup time
Hold time
Define data invalid window
Min
Typ
3.215
Max
Unit
ns
0.48
100
0.52
300
1100
500
500, 500
ps
ps
ps
ps
Table 8 - Input Data/Clock phase in 311 MHz mode
3.3.3
Output Data/Clock phase
T0
TW
RxPOCLKP
Vcross
Tcq_min
Vcross
Vcross
Tcq_max
Vswing
RxDoutP/N
Data invalid window
Figure 6 - Output Data/Clock phase
Parameter
T0
TW/T0
Tr, Tf
Tcq-min, Tcq-max
Description
Clock period
Duty cycle
20-80% rise/fall times
Data/Clock skew
Min
Typ
Max
1.608
0.45
Unit
ns
0.55
300
250/250
ps
ps
Table 9 - Output Data/Clock phase
3.4
Diagnostic signals
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
3.4.1
Line Loopback : LLOOPENB
Line Loopback Enable control input. When active, the Rx optical input will be routed directly to the TX
outputs. It allows 10 Gbit/s loopback as well as parallel data loopback (Table 10, Figure 7).
Signal
Status
TxPo: Tx Optical Output
RxPr: Rx Optical Input
TxDin
TxPICLK
TxPCLK/ TxMCLK
TxREFCLK
RxDout[0:15]
RxPOCLK
RxMCLK
= RxPr
Active
Don’t Care
Don’t Care
Active
Don’t Care
Active when RxMUTEDout is inactivate
Active
Active
Table 10 : Line Loopback : LLOOPENB
Active
SERDES Transceiver
Don’t Care
16
Tx
TxDin
Tx
TxPICLK
Tx Optical Out
TxPCLK
TxREFCLK
16
RxDout
RxPOCLK
Rx
Rx Optical In
RxMCLK
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
SERDES Transceiver
16
Tx
TxDin
Tx
TxPICLK
Tx Optical Out
TxPCLK
TxREFCLK
*1
*1: Depends on
Design
LLOOPENB
16
Rx
RxDout
Rx Optical In
RxPOCLK
RxMCLK
Figure 7 : Line Loopback
3.4.2
Diagnostic Loopback : DLOOPENB
Diagnostic Loopback Enable control input. When active, the MUX output will be routed directly to the
DMUX inputs. It allows 10 Gbit/s loopback as well as parallel data loopback (Table 11, Figure 8).
Signal
Status
TxPo: Tx Optical Output
RxPr: Rx Optical Input
TxDin
TxPICLK
TxPCLK/ TxMCLK
Don’t Care
Don’t Care
Active
Active
Active
TxREFCLK
RxDout[0:15]
RxPOCLK
RxMCLK
Active
Active when RxMUTEDout is inactivate
Active
Active
Table 11 - Diagnostic Loopback : DLOOPENB
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Active
SERDES Transceiver
Don’t Care
16
Tx
TxDin
Tx
TxPICLK
Tx Optical Out
TxPCLK
TxREFCLK
16
RxDout
Rx
Rx Optical In
RxPOCLK
RxMCLK
SERDES Transceiver
16
Tx
TxDin
Tx
TxPICLK
Tx Optical Out
TxPCLK
TxREFCLK
RxDout
16
Rx
RxPOCLK
Rx Optical In
RxMCLK
DLOOPENB
Figure 8 - Diagnostic Loopback
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
3.4.3 Line Timing Select control : TxLINETIMSEL
Line Timing Select control is an input signal. When active, the Rx clock out will be routed directly to the TX
REF inputs (Table 12, Figure 9).
Signal
Status
TxPo: Tx Optical Output
Active
RxPr: Rx Optical Input
Active
TxDin
Active
TxPICLK
Active
TxPCLK/ TxMCLK
Active
TxREFCLK
Don’t Care
RxDout[0:15]
Active when RxMUTEDout is inactivate
RxPOCLK
Active
RxMCLK
Active
Table 12 - : TxLINETIMSEL
Active
SERDES Transceiver
Do not Care
16
Tx
TxDin
Tx
TxPICLK
Tx Optical Out
TxPCLK
TxREFCLK
TxLINETIMSEL
16
RxDout
Rx
Rx Optical In
RxPOCLK
RxMCLK
Figure 9 – Line Timing Select control
3.4.4 Simultaneous Operation
The Table 15 shows the possible simultaneous solutions :
LLOOPENB
DLOOPENB
TxLINETIMSEL
LLOOPENB
DLOOPENB
Figure 10
Figure 11= Line
Loopback
Figure 12
TxLINETIMSEL
Table 13 : Simultaneous solutions
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
SERDES Transceiver
16
Tx
TxDin
Tx
TxPICLK
Tx Optical Out
TxPCLK
TxREFCLK
LLOOPENB
16
RxDout
Rx
RxPOCLK
Rx Optical In
RxMCLK
RxDLOOPENB
Figure 10 – DLOOPENB + LLOOPENB
SERDES Transceiver
16
Tx
TxDin
Tx
TxPICLK
Tx Optical Out
TxPCLK
TxREFCLK
TxLINETIMSEL
LLOOPENB
16
RxDout
Rx
Rx Optical In
RxPOCLK
RxMCLK
Figure 11 – LLOOPENB + TxLINETIMSEL
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
SERDES Transceiver
16
Tx
TxDin
Tx
TxPICLK
Tx Optical Out
TxPCLK
TxREFCLK
TxLINETIMSEL
16
RxDout
Rx
RxPOCLK
Rx Optical In
RxMCLK
RxDLOOPENB
Figure 12 – DLOOPENB + TxLINETIMSEL
3.5
Tunable Laser Monitor : LsWAVEMON
The Tunable laser monitor signal is the buffered wavelocker output or temperature monitor (for nonwavelocked units). The linearity is determined by the wavelocker characteristic curve. The WDM systems
require high wavelength resolution, more gain is required to get the required improved sensitivity. An
increased range accommodates both wavelocker and non-wavelocker tunable transponder
implementations. Temperature Monitor can be used for non-wavelocked units. Most non-wavelocked
versions won’t need a wavelength monitor.
Applica tion
Multicha nnel/
Wide
Wa velockers/
Temp monitor
DWDM/
eta lon
wa velocker
Wa velocker FSR
Sca le Fa ctor
> 1.6nm
> 200GHz
1 V/ nm
8mV/ GHz
1.6 nm
200GHz
6.25 V/ nm
50 mV/ GHz
0.8 nm
100GHz
12.5 V/ nm
100 mV/ GHz
0.4 nm
50GHz
25 V/ nm
200 mV/ GHz
0.2 nm
25 GHz
50 V/ nm
400 mV/ GHz
Table 14 : Scale factor versus applications
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
3.6
3.6.1
Electrical input & output signals
Digital signal characteristics
Parameters
Alarm output high level
Alarm output low level
Cond
Symb
Control input high level
Control input low level
Min
2 400
Typ
2 000
GND
Max
VDD1
400
Unit
mV
mV
VDD1
800
mV
mV
Table 15 - Digital signal characteristics
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
3.6.2
Analog signal characteristics
Parameters
Input power monitor voltage slope for PIN
Input power monitor voltage slope for APD
Cond
Note 2
Symb
RxPOWMON
Min
0.8
Note 2, Note RxPOWMON
3
Typ
Max
1.26
Unit
V/mW
1
V
Input signal monitor voltage slope for PIN
Note 2
RxSIGMON
TBD
TBD
Input signal monitor voltage slope for APD
Note 2
RxSIGMON
TBD
TBD
Normalized laser power monitor voltage BOL
50% variation of laser power
Laser disable mode
LsPOWMON
Linear slope
LsBIASMON
Normalized laser temperature monitor voltage
Normalized laser temperature monitor slope
Note 7
Normalized APD temperature monitor voltage
Normalized APD temperature monitor slope
25°C
APDTEMPMON
DC control
ModBIASMON
17.8
-20
LsTEMPMON
20
20
2.5
25
0.56
+20
V
V
mV
22.5
+20
mV/mA
mV
30
V
mV/°C
1
25
0
ModBIASMON
Laser fine tuning of DWDM wavelength Input
Impedance
Laser fine tuning of DWDM wavelength :
Nominal voltage for nominal wavelength
(factory set)
Laser fine tuning of DWDM wavelength slope
Laser fine tuning of DWDM wavelength range
Low frequency receiver output Impedance
0.5
0.25
-20
Laser monitor bias voltage slope
Laser monitor bias offset voltage
Normalized external MZM modulator slope
Monitor voltage output resistor
0.44
LsTWEAK :
V
mV/°C
2
1
V
k
10
PF
k
V
10
Note 5, Note
6
LsTWEAK :
Vnom
1.25
LsTWEAK
LsTWEAK
0.2
+/0.25
RxTRACE
Low frequency receiver modulation intensity
Low frequency receiver output slope
Low frequency receiver frequency range
Note 4
Note 6
RxTRACE
RxTRACE
RxTRACE
Low frequency transmitter input Impedance
Note 6
TxTRACE
10
20
TBD
10
nm/V
nm
1
k
10
25
%
V/mA
kHz
10
PF
k
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Low frequency transmitter modulation intensity
TxTRACE
10
%
Low frequency transmitter modulation voltage
TxTRACE
Vpp
TxTRACE
2.5
V
1000
kHz
-30
dBm
10
ms
1
ms
-40
dBm
60
s
5
s
1
ms
Low frequency transmitter frequency range
Note 6
Optical output power
Single
channel
Single
channel
Single
channel
LsENABLE =
high level
D-WDM
LsENABLE=
high level
Criteria : +/10% of the
grid
Criteria : +/10% of the
grid
Laser enable : switch-on time
Laser enable : switch-off time
Optical output power
Laser enable : switch-on time
D-WDM : at
any
temperature
D-WDM : at
TEC
temperature
D-WDM : to
–40dBm
Laser enable : switch-on time
Laser enable : switch-off time
Tunable Laser Monitor voltage
10
Nominal
LsWAVEMON
wavelength,
BOL
1.25
Tunable Laser Monitor output impedance
Receiver Decision Threshold Input voltage
range
Decision level min
Decision level max
50% Decision level Input voltage
Receiver Decision Threshold Input lmpedance
Figure 13
Figure 13
Figure 13
Figure 13
RxDTV
Vnom
–1.25
V
100

Vnom
+1.25
20
V
80
Vcenter
RxDTV
Vnom
10
10
%
%
V
pF
k
Note 2 – range of optical power over which these specifications remain valid are for further study
Note 3 Set at Room Temperature
Set the unit for 1.0V +/- 0.1V at –9dBm Optical Input Power, allows for higher power capable
APDs assuming a 2 Volt A/D input.
Intercept set for 0V
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Note 4 – Fix transimpedance Gain based on Maximum Modulation Depth of 10%
Note 5 – Consistent with an Op Amp
Note 6 - AC couple inside the transponder
Note 7 – LsTEMP MON is typically required for laser modules that uses TECs (thermo electric coolers)
Table 16 - Analog signal characteristics
Decision Level, DTV
100%
max
50%
min
0%
Vnom -1.25
Vcenter
Vnom +1.25
Decision Level, DTV
RxDTV Voltage (V)
100%
Logic “1” Level
(high optical power)
50%
0%
Logic “0” Level
0
Time (UI)
1
Figure 13 - Receiver Decision Threshold definition
3.6.3
Clock and data input & output signal characteristics
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10Gb TRANSPONDER
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
The framer to Transceiver electrical interface should conform to guidelines outlined in Optical
Internetworking Forum document OIF-SFI4-01.0 26 September 2000 : Common electrical interface between
framers and serializer/deserializer parts for OC-192/STM-64 interfaces.
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
3.7
Alarms
3.7.1
Alarms chronology behavior : FFS
3.7.2
Alarms and Control response time
Parameters
Tx Laser bias current alarm activation time
Tx Laser bias current alarm deactivation time
Cond
Symb
Min
LsBIASALM
Typ
Max
10
10
Unit
ms
ms
10
10
ms
ms
Tx Laser temperature alarm activation time
Tx Laser temperature alarm deactivation time
LsTEMPALM
Tx Mux FIFO error indicator pulse width
TxFIFO ERR
100
ns
Tx Mux FIFO reset control pulse width
TxFIFO RES
30
ns
Tx RESET
10
ms
Module Reset indicator pulse width
MOD RESET
10
ms
Tx error indicator activation time
Tx error indicator deactivation time
TxALM INT
10
10
ms
ms
RxPOWALM
Rx Loss of average optical power alarm activation time
Rx Loss of average optical power alarm deactivation time
Rx Loss of average optical power alarm deviation
Note 8
±1
10
10
±2
ms
ms
dB
±1
FFS
FFS
±2
ms
ms
dB
RxALM INT
10
10
ms
ms
ALM INT
10
10
ms
ms
Tx Reset indicator pulse width
Rx Loss of a.c. optical power alarm activation time
Rx Loss of a.c. optical power alarm deactivation time
Rx Loss of a.c. optical power alarm deviation
Rx error indicator activation time
Rx error indicator deactivation time
Module error indicator activation time
Module error indicator deactivation time
RxSIGALM
Note 8
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10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Parameters
Cond
Optical output power alarm
Symb
Min
Typ
LsPOWALM
Max
Unit
10
ms
External MZM modulator Bias alarm activation time
ModBIASALM
10
ms
Note 8: The minimum value represents a +/- 1dB hysteresis on the alarm. The max value indicates a +/-1dB
hysteresis and a +/-1dB tolerance allowed for the RxPOWMON slope
Table 17 - Alarms and Control response time
3.8
Jitter Characteristics
Jitter transfer, generation, and tolerance should conform to GR-253, ITU-T G.783 and IEEE 802.3ae Draft 4.0
specifications.
4
MECHANICAL DIMENSION
4.1
Transceiver package drawing (from underneath to show electrical connector)
N
Side View
x
Recess area
D
F
4 x M2.5 Threaded bolt holes
3 (0.118) max deep
Optical Transmitter Output
2x B
K30
A30
y
2x M
G
K1
E
2x L
A1
Optical Receiver Input
J
300pin MegArray receptacle
Connector
K
C
H
Q
A
z
P
Bottom View
Figure 14 – Transceiver package drawing
Note 9: Mechanical bolt holes used for securing the transceiver to the customer board will be electrically
connected to the transceiver case. This allows the bolt holes to be used for frame ground connections in
conjunction with, or without, pins H1, H2, H4, H5, H25, H26, H28, H29
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10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Symbol
Minimum
mm
Typical
45.7
46.7
9.4
23.37
Maximum
D
E
F
G
H
12.2
K
3.0
N
0.38
Note 10: Fit for the circuit board layout (see section4.2)
Minimum
inch
Typical
1.80
1.84
0.37
0.92
Note
Maximum
0.48
0.12
Note 10
Note 10
Note 10
Note 10
Note 10
Note 10
0.015
Table 18 –Cooled and Uncooled Transceiver connector and holes position dimensions
Symbol
Minimum
mm
Typical
Maximum
127.0
127.0
18.0
A
2x B
C
J
12.4
2x L
49.6
2x M
42.5
P
900
1000
1100
Q
30
Note 11: Fit for the circuit board layout (see section4.2)
Minimum
0.49
1.96
1.68
35.4
inch
Typical
Note
Maximum
5.0
5.0
0.7
Note 11
Note 11
Note 11
39.4
43.4
1.2
Table 19 -Cooled and Uncooled Transceiver module size dimensions
Symbol
Minimum
mm
Typical
45.7
46.7
9.4
23.37
Maximum
D
E
F
G
H
6.0
K
3.0
N
0.38
Note 12: Fit for the circuit board layout (see section4.2)
Minimum
inch
Typical
1.80
1.84
0.37
0.92
Note
Maximum
0.24
0.12
Note 12
Note 12
Note 12
Note 12
Note 12
Note 12
0.015
Table 20 – Uncooled and Cooled SFF Transceiver connector and holes position dimensions
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Symbol
mm
Typical
Minimum
Maximum Minimum
A
76.2
2x B
55.9
C
16
J
12.4
0.49
2x L
49.6
1.96
2x M
42.5
1.68
P
900
1000
1100
35.4
Q
30
Note 13: Fit for the circuit board layout (see section4.2)
inch
Typical
Note
Maximum
3.0
2.2
0.63
Note 13
Note 13
Note 13
39.4
43.4
1.2
Table 21 –Uncooled and Cooled SFF Transceiver module size dimensions
4.2
Trace area and fiber keep out zone for customer board
Trace area on user’s PCB
Fiber keep out zone
x
d
f
4 x R1.2
(0.05)
4 x 3.0
2x b
Optical Receiver Input
K1
y
A1
2x m
g
K30
e
u
2x l
v
A30
Optical Transmitter Output
j
k
300pin MegArray plug Connector
h
i
q
a
Top View of the customer board
Figure 15 - Trace area and fiber keep out zone for customer board
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10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Symbol
mm
Typical
45.7
46.7
9.4
23.37
Minimum
d
e
f
g
h
k
Maximum
12.2
2.5
Minimum
inch
Typical
1.80
1.84
0.37
0.92
Maximum
0.48
0.1
Table 22 – Cooled and Uncooled Transceiver trace area dimensions on user’s PCB
Symbol
Minimum
a
2x b
j
2x l
2x m
q
30.5
u
33.0
v
33.0
Note 14: defined as the module size
mm
Typical
Note 14
Note 14
Maximum
Minimum
inch
Typical
Note 14
Note 14
12.0
49.3
42.0
Maximum
0.47
1.94
1.64
1.2
1.3
1.3
Table 23 – Cooled and Uncooled Transceiver module area and fibers zone dimensions on user’s PCB
Symbol
mm
Typical
45.7
46.7
9.4
23.37
Minimum
d
e
f
g
h
k
Maximum
6.0
2.5
Minimum
inch
Typical
1.80
1.84
0.37
0.92
Maximum
0.24
0.1
Table 24 – Uncooled and Cooled SFF Transceiver trace area dimensions on user’s PCB
Symbol
Minimum
a
2x b
j
2x l
2x m
q
30.5
u
33.0
v
33.0
Note 15: defined as the module size
mm
Typical
Note 15
Note 15
Maximum
Minimum
inch
Typical
Note 15
Note 15
12.0
49.3
42.0
Maximum
0.47
1.94
1.64
1.2
1.3
1.3
Table 25 – Uncooled and Cooled SFF Transceiver module area and fibers zone dimensions on user’s PCB
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REFERENCE DOCUMENT
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
4.3
Connector description
Meg-Array ® 300 Position Receptacle, 1.27 mm x 1.27 mm (0.050 in. x 0.050 in.) ball to ball pitch. Customer
connector is Berg 300 pin plug part number #84500-102.
5
FIRMWARE INTERFACE WITH I2C BUS
The material in this section is published in a separate document entitled,
300 PIN MSA : I²C protocol for 10G and 40G Transponder Public Document
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REFERENCE DOCUMENT
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300PIN 10Gb
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6
PIN ASSIGNMENT
6.1
Top view from customer line card
K
J
H
G
F
E
D
C
B
A
Frame GND
RxDout12P
APS Digital
RxDout8P
Digital GND
RxDout4P
Digital GND
RxDout0P
5.0VAnalog
FFU
Frame GND
RxDout12N
Digital GND
RxDout4N
Digital GND
RxDout0N
RxRATESEL1
APDTEMPMON
Digital GND
APS Digital
RxPOWMON
RxDout8N
RxRATESEL0
Digital GND
I2CAD0
Digital GND
RxDTV
Digital GND
3.3VAnalog
NUC
FrameGND
RxDout13P
3.3VDigital
RxDout9P
Digital GND
RxDout5P
Digital GND
RxDout1P
3.3VAnalog
NUC
FrameGND
RxDout13N
3.3VDigital
RxDout9N
Digital GND
RxDout5N
Digital GND
RxDout1N
RxRESET
NUC
DLOOPENB
Digital GND
RxPOWALM
Digital GND
I2CAD1
Digital GND
RxMUTE Dout
Digital GND
3.3VAnalog
FFU
Analog GND
RxDout14P
3.3VDigital
RxDout10P
Digital GND
RxDout6P
Digital GND
RxDout2P
3.3VAnalog
FFU
Analog GND
RxDout14N
3.3VDigital
RxDout10N
Digital GND
RxDout6N
Digital GND
RxDout2N
RxMUTEPOCLK
NUC
FFU
Digital GND
RxSIGMON
Digital GND
I2CAD2
Digital GND
RxLCKREF
Digital GND
-5.2VAnalog
APS Sense
Analog GND
RxDout15P
-5.2VDigital
RxDout11P
Digital GND
RxDout7P
Digital GND
RxDout3P
-5.2VAnalog
APS Set
Analog GND
RxDout15N
-5.2VDigital
RxDout11N
Digital GND
RxDout7N
Digital GND
RxDout3N
RxMUTEMCLK
NUC
FFU
Digital GND
RxSIGALM
Digital GND
MOD_RESET
Digital GND
RxMCLKSEL
Digital GND
-5.2VAnalog
FFU
Analog GND
FFU
-5.2VDigital
RxPOCLKP
Digital GND
RxMCLKP
Digital GND
RxREFCLKP
-5.2VAnalog
RxALM INT
Analog GND
FFU
-5.2VDigital
RxPOCLKN
Digital GND
RxMCLKN
Digital GND
RxREFCLKN
I2CCLOCK
NUC
ALM INT
Digital GND
RxREFSEL
Digital GND
FFU
Digital GND
RxLOCKERR
Digital GND
5.0VAnalog
TxALM INT
Analog GND
TxDin12P
APS Digital
TxDin8P
Digital GND
TxDin4P
Digital GND
TxDin0P
5.0VAnalog
FFU
Analog GND
TxDin12N
APS Digital
TxDin8N
Digital GND
TxDin4N
Digital GND
TxDin0N
I2CDATA
NUC
LsTUNE0
Digital GND
LsBIASMON
Digital GND
LsPOWMON
Digital GND
TxSKEWSEL0
Digital GND
3.3VAnalog
ModBIASMON
Analog GND
TxDin13P
3.3VDigital
TxDin9P
Digital GND
TxDin5P
Digital GND
TxDin1P
3.3VAnalog
ModBIASALM
Analog GND
TxDin13N
3.3VDigital
TxDin9N
Digital GND
TxDin5N
Digital GND
TxDin1N
TxRATESEL0
TxRATESEL1
LsTUNE1
Digital GND
LsENABLE
Digital GND
LsTEMPMON
Digital GND
TxSKEWSEL1
Digital GND
3.3VAnalog
FFU
Analog GND
TxDin14P
3.3VDigital
TxDin10P
Digital GND
TxDin6P
Digital GND
TxDin2P
3.3VAnalog
FFU
Analog GND
TxDin14N
3.3VDigital
TxDin10N
Digital GND
TxDin6N
Digital GND
TxDin2N
TxRESET
NUC
LsTUNE2
Digital GND
LsBIASALM
Digital GND
TxPHSADJ0
Digital GND
LsTWEAK
Digital GND
-5.2VAnalog
NUC
Frame GND
TxDin15P
-5.2VDigital
TxDin11P
Digital GND
TxDin7P
Digital GND
TxDin3P
-5.2VAnalog
NUC
Frame GND
TxDin15N
-5.2VDigital
TxDin11N
Digital GND
TxDin7N
Digital GND
TxDin3N
TxFIFO RES
NUC
LLOOPENB
Digital GND
LsTEMPALM
Digital GND
TxPHSADJ1
Digital GND
TxPICLKSEL
Digital GND
-5.2VAnalog
LsWAVEMON
Frame GND
TxPICLKP
-5.2VDigital
TxPCLKP
Digital GND
TxMCLKP
Digital GND
TxREFCLKP
-5.2VAnalog
TxTRACE
Frame GND
TxPICLKN
-5.2VDigital
TxPCLKN
Digital GND
TxMCLKN
Digital GND
TxREFCLKN
TxFIFO ERR
NUC
TxLINETIMSEL
Digital GND
TxREFSEL
Digital GND
LsPOWALM
Digital GND
TxLOCKERR
Digital GND
Receiver power & GND supplies
Receiver d.c. signals
622 differential signals
Transmitter power & GND supplies
Transmitter d.c. signals
NUC: no user connection
FFU: reserved for future use
Italics: optional feature
Table 26 - Top view from customer line card
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Public
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REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
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Transmitter
RxTRACE
Receiver
5.0VAnalog
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.2
Truth tables
RxRATESEL1 RxRATESEL0
0
0
10Gb Ethernet rate of 10.3Gb/s selected
0
1
to be determined
1
0
FEC rate of 10.7Gb/s selected
1
1
normal SONET rate of 9.9Gb/s selected
n.b. SONET rate of 9.9Gb/s is the MSA standard
RxRESET
0
1
asynchronous DeMux system reset
normal operation
RxMUTEPOCLK
0
1
RxREFSEL
0
selects an RxREFCLK frequency of 155MHz
1
selects an RxREFCLK frequency of 622MHz
n.b. RxREFCLK frequency of 155MHz is the MSA standard
LsENABLE
0
normal operation
1
laser disabled
n.b. if the LsENABLE function is not used then this pin should be tied to ground.
LsBIASALM
0
1
mutes the RxPOCLK
laser bias alarm active
normal operation
normal operation
LsTEMPALM
RxMUTEMCLK
0
1
0
1
mutes the RxMCLK
normal operation
laser temperature alarm active
normal operation
TxREFSEL
TxRATESEL1 TxRATESEL0
0
0
10Gb Ethernet rate of 10.3Gb/s selected
0
1
to be determined
1
0
FEC rate of 10.7Gb/s selected
1
1
normal SONET rate of 9.9Gb/s selected
n.b. SONET rate of 9.9Gb/s is the MSA standard
TxRESET
0
1
asynchronous Mux system reset
normal operation
TxFIFORES
0
1
Mux FIFO reset
normal operation
0
selects a TxREFCLK frequency of 155MHz
1
selects a TxREFCLK frequency of 622MHz
n.b. TxREFCLK frequency of 622MHz is the MSA standard
RxMUTE Dout
0
1
TxPHSADJ1
0
0
1
1
Mutes the RxDout[0:15]
normal operation
TxPHSADJ0
0
1
0
1
adjusts
adjusts
adjusts
adjusts
the
the
the
the
phase
phase
phase
phase
of
of
of
of
the
the
the
the
TxPCLK
TxPCLK
TxPCLK
TxPCLK
by
by
by
by
0o
90o
180o
270o
RxLCKREF
TxFIFOERR
0
1
indicates a Mux FIFO error
normal operation
0
1
Locks RxPOCLK to RxREFCLK
normal operation
RxMCLKSEL
RxALMINT
0
1
TxALMINT
0
1
0
1
indicates alarm active
normal operation
RxLOCKERR
0
1
indicates alarm active
normal operation
selects the RxMCLK frequency of 155MHz
selects the RxMCLK frequency of 622MHz
indicates loss of PLL lock
normal operation
TxSKEWSEL1 TxSKEWSEL0
DLOOPENB
0
1
enables diagnostic loopback (10GbMux to 10GbDemux)
normal operation
ALMINT
0
1
indicates alarm active
normal operation
0
0
delays the TxPICLK
0
1
delays the TxPICLK
1
0
delays the TxPICLK
1
1
delays the TxPICLK
n.b. TxSKEWSEL only applies when TxPICLK=311MHz
by
by
by
by
915pseconds
1015pseconds
715pseconds
815pseconds
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
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300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
LsTUNE2
0
0
0
0
1
1
1
1
LLOOPENB
0
1
LsTUNE1
0
0
1
1
0
0
1
1
LsTUNE0
0
1
0
1
0
1
0
1
selects
selects
selects
selects
selects
selects
selects
TBD
ITU
ITU
ITU
ITU
ITU
ITU
ITU
wavelength
wavelength
wavelength
wavelength
wavelength
wavelength
wavelength
grid
grid
grid
grid
grid
grid
grid
n-3
n-2
n-1
n
n+1
n+2
n+3
enables line loopback (10GbRx to 10GbTx)
normal operation
TxPICLKSEL
0
selects the TxPICLK frequency of 622MHz
1
selects the TxPICLK frequency of 311MHz
n.b. TxPICLK frequency of 622MHz is the MSA standard. If the TxPICLK function is not
used then it should be tied to ground.
TxLOCKERR
0
1
LsPOWALM
0
TxLINETIMSEL
0
1
selects line timing mode (TxREFCLK=RxPOCLK)
normal operation
RxPOWALM
0
1
indicates alarm active
normal operation
indicates loss of PLL lock
normal operation
1
MOD_RESET
0
1
indicates alarm active : the laser output power degrades
3dB below the nominal output power
normal operation
Reset both transmitter and Receiver part including digital
control circuit
normal operation
normal operation
ModBIASALM
0
1
indicates that the modulator is approaching reset condition : less than
5% and greater than 95% of Control Range
normal operation
RxSIGALM
0
1
indicates alarm active
normal operation
LsWAVEALM (available through the I2C)
0
1
this alarm is active when the locker is out of +/-20% of the grid
normal operation
Table 27 - Truth tables
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
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4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
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14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.3
Input & output termination description
Function
RxRATESEL0
RxRESET
RxMUTEPOCLK
RxMUTEMCLK
I2CCLOCK
Input/Output
I
I
I
I
I/O
Analog/Digital
D
D
D
D
D
Internal Transponder Termination
LVTTL with pull-up resistor
LVTTL with pull-up resistor
LVTTL with pull-up resistor
LVTTL with pull-up resistor
open drain/collector
I/O
I
I
I
O
O
I
D
D
D
D
D
A
D
open drain/collector
LVTTL with pull-up resistor
LVTTL with pull-up resistor
LVTTL with pull-up resistor
LVTTL
buffered analog
LVTTL with pull-up resistor
O
O
I
I
I
O
I
I
I
I
I
O
O
O
O
I
O
I
O
O
I
O
O
I
I
D
D
D
A
D
D
D
D
D
D
D
A
D
A
D
D
A
D
D
D
D
A
A
D
D
open drain/collector
open drain/collector
LVTTL with pull-up resistor
buffered analog
LVTTL with pull-up resistor
open drain/collector
LVTTL with pull-up resistor
LVTTL with pull-up resistor
LVTTL with pull-down resistor
LVTTL with pull-up resistor
LVTTL with pull-up resistor
buffered analog
LVTTL
buffered analog
LVTTL
LVTTL with pull-down resistor
buffered analog
LVTTL with pull-down resistor
LVTTL
LVTTL
LVTTL with pull-up resistor
buffered analog
buffered analog
LVTTL with pull-up resistor
LVTTL with pull-up resistor
I2CDATA
TxRATESEL0
TxRESET
TxFIFO RES
TxFIFO ERR
RxTRACE
RxRATESEL1
RxALM INT
TxALM INT
TxRATESEL1
TxTRACE
DLOOPENB
ALM INT
LsTUNE0
LsTUNE1
LsTUNE2
LLOOPENB
TxLINETIMSEL
RxPOWMON
RxPOWALM
RxSIGMON
RxSIGALM
RxREFSEL
LsBIASMON
LsENABLE
LsBIASALM
LsTEMPALM
TxREFSEL
LsPOWMON
LsTEMPMON
TxPHSADJ0
TxPHSADJ1
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
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03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
Function
RxMUTE Dout
RxLCKREF
RxMCLKSEL
RxLOCKERR
TxSKEWSEL0
TxSKEWSEL1
TxPICLKSEL
TxLOCKERR
RxDTV
LsWAVEMON
LsPOWALM
I2CAD0
I2CAD1
I2CAD2
LsTWEAK
MOD_RESET
ModBIASALM
ModBIASMON
APDTEMPMON
APS Sense
APS Set
LsWAVEALM
Input/Output
I
I
I
O
I
I
I
O
I
O
O
I
I
I
I
I
O
O
O
O
O
O
Analog/Digital
Internal Transponder Termination
D
LVTTL with pull-up resistor
D
LVTTL with pull-up resistor
D
LVTTL with pull-up resistor
D
LVTTL
D
LVTTL with pull-up resistor
D
LVTTL with pull-up resistor
D
LVTTL with pull-down resistor
D
LVTTL
A
buffered analog
A
buffered analog
D
LVTTL
D
LVTTL with pull-down resistor
D
LVTTL with pull-down resistor
D
LVTTL with pull-down resistor
A
laser fine tuning of DWDM wavelength
D
LVTTL with pull-up resistor
D
LVTTL, pulled high internally
A
buffered analog
A
buffered analog
A
buffered analog
A
buffered analog
D
Available through the I²C
Table 28 - Input & output termination description
LVTTL with pull-up resistor termination:
Customer board
Berg Connector
Transponder
Vcc=3.3V
R>10k
Internal circuitry
No user
connection
NUC
I/O
standard LVTTL levels must
be maintained at I/O of
internal circuitry
Figure 16 - LVTTL with pull-up termination
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
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03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
LVTTL with pull-down resistor termination:
Customer board
Berg Connector
Transponder
GND
R>10k
Internal circuitry
I/O
standard LVTTL levels must
be maintained at I/O of
internal circuitry
Figure 17 - LVTTL with pull-down termination
Pull-up and pull-down resistors are required to ensure that different transponders from different vendors
will always function properly when plugged into the same customer’s board. LVDS data input and output
terminations are to be d.c. coupled within the transponders. Input and output clock signals are to be a.c.
coupled within the transponders.
6.4
Detailed pin description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
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Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
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14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.1
“Row A” description
Pin #
A1
A2
A3
A4
A5
RxDout0P
RxDout0N
Digital GND
RxDout1P
RxDout1N
I/O
O
O
I
O
O
Logic
LVDS
LVDS
Supply
LVDS
LVDS
Receiver
Receiver
Receiver
Receiver
Receiver
Description
Parallel Data Output
Parallel Data Output
Digital Ground
Parallel Data Output
Parallel Data Output
A6
A7
A8
A9
A10
A11
A12
Digital GND
RxDout2P
RxDout2N
Digital GND
RxDout3P
RxDout3N
Digital GND
I
O
O
I
O
O
I
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
Receiver
Receiver
Receiver
Receiver
Receiver
Receiver
Receiver
Digital Ground
Parallel data Output
Parallel Data Output
Digital Ground
Parallel Data Output
Parallel Data Output
Digital Ground
A13
A14
A15
A16
A17
A18
A19
A20
A21
A22
A23
A24
A25
A26
A27
A28
A29
A30
RxREFCLKP
RxREFCLKN
Digital GND
TxDin0P
TxDin0N
Digital GND
TxDin1P
TxDin1N
Digital GND
TxDin2P
TxDin2N
Digital GND
TxDin3P
TxDin3N
Digital GND
TxREFCLKP
TxREFCLKN
Digital GND
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
ac coupled
ac coupled
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
ac coupled
ac coupled
Supply
Symbol
Receiver Reference Clock
Receiver Reference Clock
Receiver Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Reference Clock
Transmitter Reference Clock
Transmitter Digital Ground
Table 29 - “Row A” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
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03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.2
“Row B” description
Pin #
B1
B2
B3
B4
B5
Symbol
Digital GND
Digital GND
Rx DTV
Digital GND
Digital GND
B6
B7
B8
B9
B10
B11
B12
RxMUTE Dout
B13
B14
B15
B16
B17
B18
B19
B20
B21
B22
B23
B24
B25
B26
B27
B28
B29
B30
Digital GND
Digital GND
RxLOCKERR
Digital GND
Digital GND
Digital GND
Digital GND
RxLCKREF
Digital GND
Digital GND
RxMCLKSEL
TxSKEWSEL0
Digital GND
Digital GND
TxSKEWSEL1
Digital GND
Digital GND
LsTWEAK
Digital GND
Digital GND
TxPICLKSEL
Digital GND
Digital GND
TxLOCKERR
I/O
I
I
I
I
I
Logic
Supply
Supply
Analog
Supply
Supply
Description
Digital Ground
Digital Ground
Decision Threshold
Digital Ground
Digital Ground
Receiver
Receiver
Receiver
Receiver
Receiver
I
I
I
I
I
I
I
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Mutes the data outputs of the DeMux
Receiver Digital Ground
Receiver Digital Ground
Locks RxPOCLK to RxREFCLK
Receiver Digital Ground
Receiver Digital Ground
Selects speed of output RxMCLK
I
I
O
I
I
I
I
I
I
I
I
I
I
I
I
I
I
O
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
Analog
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Receiver Digital Ground
Receiver Digital Ground
Loss of lock of RxPOCLK (active low)
Transmitter Digital Ground
Transmitter Digital Ground
Adjusts skew of TxPICLK (LSB)
Transmitter Digital Ground
Transmitter Digital Ground
Adjusts skew of TxPICLK (MSB)
Transmitter Digital Ground
Transmitter Digital Ground
laser fine tuning of DWDM wavelength
Transmitter Digital Ground
Transmitter Digital Ground
Selects speed of input TxPICLK
Transmitter Digital Ground
Transmitter Digital Ground
Indicates loss of TxPLL lock
Table 30 - “Row B” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
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document is
A
is an
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03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.3
“Row C” description
Pin #
C1
C2
C3
C4
C5
C6
C7
C8
C9
C10
C11
C12
C13
C14
C15
C16
C17
C18
C19
C20
C21
C22
C23
C24
C25
C26
C27
C28
C29
C30
Symbol
RxDout4P
RxDout4N
Digital GND
RxDout5P
RxDout5N
Digital GND
RxDout6P
RxDout6N
Digital GND
RxDout7P
RxDout7N
Digital GND
RxMCLKP
RxMCLKN
Digital GND
TxDin4P
TxDin4N
Digital GND
TxDin5P
TxDin5N
Digital GND
TxDin6P
TxDin6N
Digital GND
TxDin7P
TxDin7N
Digital GND
TxMCLKP
TxMCLKN
Digital GND
I/O
O
O
I
O
O
I
O
O
I
O
O
I
O
O
I
I
I
I
I
I
I
I
I
I
I
I
I
O
O
I
Logic
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
Description
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
VCO derived output Rx clock
VCO derived output Rx clock
Receiver Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
VCO derived output Tx clock
VCO derived output Tx clock
Transmitter Digital Ground
Table 31 - “Row C” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
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03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.4
“Row D” description
Pin #
I/O
Logic
Digital GND
I
Supply
Receiver Digital Ground
D2
Digital GND
I
Supply
Receiver Digital Ground
D3
I2CAD0
I
LVTTL
I2C address input for module addressing (LSB)
D4
Digital GND
I
Supply
Receiver Digital Ground
D5
Digital GND
I
Supply
Receiver Digital Ground
D6
I2CAD1
I
LVTTL
I2C address input for module addressing
D7
Digital GND
I
Supply
Receiver Digital Ground
D8
Digital GND
I
Supply
Receiver Digital Ground
D1
Symbol
Description
D9
I2CAD2
I
LVTTL
I2C address input for module addressing (MSB)
D10
Digital GND
I
Supply
Receiver Digital Ground
D11
Digital GND
I
Supply
Receiver Digital Ground
D12
MOD_RESET
I
LVTTL
Module asynchronous system reset
D13
Digital GND
I
Supply
Receiver Digital Ground
D14
Digital GND
I
Supply
Receiver Digital Ground
Reserved for future use
D15
—
—
D16
Digital GND
FFU
I
Supply
Transmitter Digital Ground
D17
Digital GND
I
Supply
Transmitter Digital Ground
D18
LsPOWMON
O
Analog
Laser output power monitor
D19
Digital GND
I
Supply
Transmitter Digital Ground
D20
Digital GND
I
Supply
Transmitter Digital Ground
D21
LsTEMPMON
O
Analog
Laser temperature monitor*
D22
Digital GND
I
Supply
Transmitter Digital Ground
D23
Digital GND
I
Supply
Transmitter Digital Ground
D24
TxPHSADJ0
I
LVTTL
Adjust phase of Tx PCLK (LSB)
D25
Digital GND
I
Supply
Transmitter Digital Ground
D26
Digital GND
I
Supply
Transmitter Digital Ground
D27
TxPHSADJ1
I
LVTTL
Adjusts phase of Tx PCLK (MSB)
D28
Digital GND
I
Supply
Transmitter Digital Ground
D29
Digital GND
I
Supply
Transmitter Digital Ground
D30
LsPOWALM
0
LVTTL
Loss of laser average power alarm
* this feature is only required on lasers using thermo-electric coolers
Table 32 - “Row D” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
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03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.5
“Row E” description
Pin #
E1
E2
E3
E4
E5
E6
E7
E8
E9
E10
E11
E12
E13
E14
E15
E16
E17
E18
E19
E20
E21
E22
E23
E24
E25
E26
E27
E28
E29
E30
Symbol
RxDout8P
RxDout8N
Digital GND
RxDout9P
RxDout9N
Digital GND
RxDout10P
RxDout10N
Digital GND
RxDout11P
RxDout11N
Digital GND
RxPOCLKP
RxPOCLKN
Digital GND
TxDin8P
TxDin8N
Digital GND
TxDin9P
TxDin9N
Digital GND
TxDin10P
TxDin10N
Digital GND
TxDin11P
TxDin11N
Digital GND
TxPCLKP
TxPCLKN
Digital GND
I/O
O
O
I
O
O
I
O
O
I
O
O
I
O
O
I
I
I
I
I
I
I
I
I
I
I
I
I
O
O
I
Logic
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
Description
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver parallel output clock
Receiver parallel output clock
Receiver Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter parallel output clock
Transmitter parallel output clock
Transmitter Digital Ground
Table 33 - “Row E” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
an uncontrolled
uncontrolled copy
copy
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03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.6
“Row F” description
Pin #
F1
F2
F3
F4
F5
F6
F7
F8
F9
F10
F11
F12
F13
F14
F15
F16
F17
F18
F19
F20
F21
F22
F23
F24
F25
F26
F27
F28
F29
F30
* : For the
I/O
Logic
Description
APS Digital
I
Supply
APS digital *
APS Digital
I
Supply
APS digital *
RxPOWMON
O
Analog
Receiver power monitor (a.c. +d.c.)
3.3V Digital
I
Supply
Receiver Digital Power
3.3V Digital
I
Supply
Receiver Digital Power
RxPOWALM
O
LVTTL
Loss of receiver average power alarm
3.3V Digital
I
Supply
Receiver Digital Power
3.3V Digital
I
Supply
Receiver Digital Power
RxSIGMON
O
Analog
Receiver signal monitor (a.c. only)
-5.2VDigital
I
Supply
Receiver Digital Power
-5.2VDigital
I
Supply
Receiver Digital Power
RxSIGALM
O
LVTTL
Loss of receiver a.c. power alarm
-5.2VDigital
I
Supply
Receiver Digital Power
-5.2VDigital
I
Supply
Receiver Digital Power
RxREFSEL
I
LVTTL
Selects RxREFCLK frequency
APS Digital
I
Supply
APS digital *
APS Digital
I
Supply
APS digital *
LsBIASMON
O
Analog
Laser bias current monitor
(+)3.3V Digital
I
Supply
Transmitter Digital Power
(+)3.3V Digital
I
Supply
Transmitter Digital Power
LsENABLE
I
LVTTL
Laser enable (disable is inverse)
(+)3.3V Digital
I
Supply
Transmitter Digital Power
(+)3.3V Digital
I
Supply
Transmitter Digital Power
LsBIASALM
O
LVTTL
Laser bias current alarm
-5.2VDigital
I
Supply
Transmitter Digital Power
-5.2VDigital
I
Supply
Transmitter Digital Power
LsTEMPALM
O
LVTTL
Laser temperature alarm
-5.2VDigital
I
Supply
Transmitter Digital Power
-5.2VDigital
I
Supply
Transmitter Digital Power
TxREFSEL
I
LVTTL
Selects TxREFCLK frequency
APS, the receiver part and the transmitter part are tied together in the module
Symbol
Table 34 - “Row F” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
an uncontrolled
uncontrolled copy
copy
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03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.7
“Row G” description
Pin #
G1
G2
G3
G4
G5
G6
G7
G8
G9
G10
G11
G12
G13
G14
G15
G16
G17
G18
G19
G20
G21
G22
G23
G24
G25
G26
G27
G28
G29
G30
Symbol
RxDout12P
RxDout12N
Digital GND
RxDout13P
RxDout13N
Digital GND
RxDout14P
RxDout14N
Digital GND
RxDout15P
RxDout15N
Digital GND
FFU
FFU
Digital GND
TxDin12P
TxDin12N
Digital GND
TxDin13P
TxDin13N
Digital GND
TxDin14P
TxDin14N
Digital GND
TxDin15P
TxDin15N
Digital GND
TxPICLKP
TxPICLKN
Digital GND
I/O
O
O
I
O
O
I
O
O
I
O
O
I
—
—
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
Logic
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
—
—
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
LVDS
LVDS
Supply
Description
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Receiver Parallel Data Output
Receiver Parallel Data Output
Receiver Digital Ground
Reserved for future use
Reserved for future use
Receiver Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter Parallel Data Input
Transmitter Parallel Data Input
Transmitter Digital Ground
Transmitter parallel input clock
Transmitter parallel input clock
Transmitter Digital Ground
Table 35 - “Row G” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
an uncontrolled
uncontrolled copy
copy
Page
48
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45/48
03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.8
“Row H” description
Pin #
H1
H2
H3
H4
H5
H6
H7
H8
H9
H10
H11
H12
H13
H14
H15
H16
H17
H18
H19
H20
H21
H22
H23
H24
H25
H26
H27
H28
H29
H30
Symbol
Frame GND
Frame GND
APDTEMPMON
FrameGND
FrameGND
DLOOPENB
Analog GND
Analog GND
FFU
Analog GND
Analog GND
FFU
Analog GND
Analog GND
ALM INT
Analog GND
Analog GND
LsTUNE0
Analog GND
Analog GND
LsTUNE1
Analog GND
Analog GND
LsTUNE2
Frame GND
Frame GND
LLOOPENB
Frame GND
Frame GND
TxLINETIMSEL
I/O
I
I
O
I
I
I
I
I
—
I
I
—
I
I
O
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
Logic
Supply
Supply
Analog
Supply
Supply
LVTTL
Supply
Supply
—
Supply
Supply
—
Supply
Supply
open drain/collector
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Description
Frame GND tied to Chassis GND
Frame GND tied to Chassis GND
APD output Temperature Monitor
Frame GND tied to Chassis GND
Frame GND tied to Chassis GND
Diagnostic Loopback enable
Receiver Analog GND
Receiver Analog GND
Reserved for future use
Receiver Analog GND
Receiver Analog GND
Reserved for future use
Receiver Analog GND
Receiver Analog GND
Electrical "OR" of all Rx and Tx alarms
Transmitter Analog GND
Transmitter Analog GND
Wavelength select pin0 (LSB)
Transmitter Analog GND
Transmitter Analog GND
Wavelength select pin1
Transmitter Analog GND
Transmitter Analog GND
Wavelength select pin2 (MSB)
Frame GND tied to Chassis GND
Frame GND tied to Chassis GND
Line Loopback enable
Frame GND tied to Chassis GND
Frame GND tied to Chassis GND
Line Timing select
Table 36 - “Row H” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
an uncontrolled
uncontrolled copy
copy
Page
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46/48
03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.9
“Row J” description
Pin #
J1
J2
J3
J4
J5
J6
J7
J8
J9
J10
J11
J12
J13
J14
J15
J16
J17
J18
J19
J20
J21
J22
J23
J24
J25
J26
J27
J28
J29
J30
Symbol
RxTRACE
FFU
RxRATESEL1
NUC
NUC
NUC
FFU
FFU
NUC
APS Sense
APS Set
NUC
FFU
RxALM INT
NUC
TxALM INT
FFU
NUC
ModBIASMON
ModBIASALM
TxRATESEL1
FFU
FFU
NUC
NUC
NUC
NUC
LsWAVEMON
TxTRACE
NUC
I/O
O
—
I
—
—
—
—
—
—
O
O
—
—
O
—
O
—
—
O
O
I
—
—
—
—
—
—
O
I
—
Logic
Analog
—
LVTTL
—
—
—
—
—
—
Analog
Analog
—
—
open drain/collector
—
open drain/collector
—
—
Analog
LVTTL
LVTTL
—
—
—
—
—
—
Analog
Analog
—
Description
Low frequency photo-diode output
To be determined (spare pin)
Receiver Bit Rate select (MSB)
no user connection
no user connection
no user connection
Reserved for future use
Reserved for future use
no user connection
Sense Line for APS signal
Set Line for APS signal
no user connection
Reserved for future use
Electrical "OR" of all Rx alarms
no user connection
Electrical "OR" of all Tx alarms
To be determined (spare pin)
no user connection
Modulator Bias monitor
Modulator Bias Alarm
Transmitter Bit Rate select (MSB)
Reserved for future use
Reserved for future use
no user connection
no user connection
no user connection
no user connection
Laser Wavelength Monitor
Low frequency transmitter input
no user connection
Table 37 - “Row J” description
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
an uncontrolled
uncontrolled copy
copy
Page
48
Page 47/
47/48
03/08/16
14-Aug-02
300 pin Multi Source Agreement for 10 and 40 Gigabit Transponders (SERDES Transceivers)
6.4.10 “Row K” description
Pin #
K1
K2
K3
K4
K5
K6
K7
K8
K9
K10
K11
K12
K13
K14
K15
K16
K17
K18
K19
K20
K21
K22
K23
K24
K25
K26
K27
K28
K29
K30
Symbol
5.0V Analog
5.0V Analog
RxRATESEL0
3.3V Analog
3.3V Analog
RxRESET
3.3VAnalog
3.3VAnalog
RxMUTEPOCLK
-5.2VAnalog
-5.2VAnalog
RxMUTEMCLK
-5.2VAnalog
-5.2VAnalog
I2CCLOCK
5.0V Analog
5.0V Analog
I2CDATA
3.3V Analog
3.3V Analog
TxRATESEL0
3.3V Analog
3.3V Analog
TxRESET
-5.2VAnalog
-5.2VAnalog
TxFIFO RES
-5.2VAnalog
-5.2VAnalog
TxFIFO ERR
I/O
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I/O
I
I
I/O
I
I
I
I
I
I
I
I
I
I
I
O
Logic
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
open drain/collector
Supply
Supply
open drain/collector
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Supply
Supply
LVTTL
Description
Receiver Analog Power
Receiver Analog Power
Receiver Bit Rate select (LSB)
Receiver Analog Power
Receiver Analog Power
Receiver asynchronous system reset
Receiver Analog Power
Receiver Analog Power
Mutes the RxPOCLK
Receiver Analog Power
Receiver Analog Power
Mutes the RxMCLK
Receiver Analog Power
Receiver Analog Power
I2C clock/output input for remote access
Transmitter Analog Power
Transmitter Analog Power
I2C data input/output for remote access
Transmitter Analog Power
Transmitter Analog Power
Transmitter Bit Rate select (LSB)
Transmitter Analog Power
Transmitter Analog Power
Transmitter asynchronous system reset
Transmitter Analog Power
Transmitter Analog Power
Mux FIFO reset
Transmitter Analog Power
Transmitter Analog Power
Mux FIFO error indicator
Table 38 - “Row K” description
END OF DOCUMENT
10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA 10 Giga MSA
Public
Public Document
Document Edition
Edition 3
4
REFERENCE
10Gb TRANSPONDER
TRANSPONDER
REFERENCE DOCUMENT
DOCUMENT FOR
FOR 300PIN
300PIN 10Gb
No changes
No
changes are
are allowed
allowed to
to this
this document
document
A printed
printed version
version of
of this
this document
document is
A
is an
an uncontrolled
uncontrolled copy
copy
Page
48
Page 48/
48/48
03/08/16
14-Aug-02