- 1 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Features
z Diplexer Single Mode Single Fiber 2x5 SFF SC
Receptacle connector
z Wavelength Tx 1310 nm/Rx 1530 nm
(B-13/15-155(C)-F-SSC3x)
z Wavelength Tx 1530 nm/Rx 1310 nm
(B-15/13-155(C)-F-SSC3x)
z SONET OC-3 SDH STM-1 Compliant
z Single +3.3V Power Supply
z LVPECL Differential Inputs and Outputs
(B-1x/1x-155-F-SSC3x)
z LVTTL Differential Inputs and Outputs
(B-1x/1x-155C-F-SSC3x)
z Wave Solderable and Aqueous Was hable
z Class 1 Laser Int. Safety Standard IEC-825 Compliant
z Uncooled Laser diode with MQW structure
z Complies with Telcordia (Bellco re) GR-468-CORE
z EMI Shielding Finger Optional
z RoHS compliance available
Table 1 – Absolute Maximum Rating
Parameter Symbol Min. Typical Max. Unit Notes
Power Supply Voltage Vcc 0 - 3.6 V
Output Current Iout - - 30 mA
Soldering Temperature - - - 260 ºC 1
Storage Temperature Tstg 0 - 70 ºC 2
Storage Temperature Tstg -40 - 85 ºC 3
Note 1: 10 senconds on leads only
Note 2: B-1x/1x-155(C)-F-SSC3(S)
Note 3: B-1x/1x-155(C)-F-SSC3A(S)
Table 2 – Recommended Operating Condition
Parameter Symbol Min. Typical Max. Unit Notes
Power Supply Voltage Vcc 3.1 3.3 3.5 V 4
Operating Temperature (Case) Topr 0 - 70 ºC
Data Rate DR - 155 - Mbps
Note 4: please refer to ordering information
- 2 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Table 3 – Transmitter Specification s (Optical)
Parameter Symbol Min. Typical Max. Unit Notes
Optical Transmit Power Po -14 - -8 dBm 5
Output Center Wavelength λc 1260 1310 1360 nm 6
Output Center Wavelength λc 1480 1530 1580 nm 7
Output Spectrum Width Δλ - - 3 nm 8
Extinction Ratio ER 8.2 - - dB
Output Eye Compliant with ITU-T recommendation G.957/STM-1
Optical Rise/Fall Time tr /tf - - 2 ns 9
Optical Isolation - 30 - - dB 10
Relative Intensity Noise RIN - - -116 dB/Hz
Total Jitter TJ - - 1.0 ns 11
Note 5: Output power is coupled into a 9/125 µm single mode fiber
Note 6: B-13/15-155(C)-F-SSC3x
Note 7: B-15/13-155(C)-F-SSC3x
Note 8: RMS (σ)
Note 9: 10% to 90% Values
Note 10: Tx: 1310 nm/ Rx: 1550 nm
Note 11: Measured with 223-1 PRBS with 72 ones and 72 zeros.
Table 4 – Transmitter Specification s (Electrical)
Parameter Symbol Min. Typical Max. Unit Notes
Power Supply Current ICC - - 140 mA 12
Data Input Current-Low IIL -350 - - μA
Data Input Current-High IIH - - 350
μA
Differential Input Voltage VIH-VIL 300 - - mV
Data Input Voltage-Low VIL-VCC -2.0 - -1.58 mV
Data Input Voltage-High VIH-VCC -1.1 - -0.74 mV 13
Note 12: Maximum current is specified at Vcc=Maximum @ maximum temperature
Note 13: These inputs are compatible with 10K, 10KH and 100K ECL and PECL inputs
- 3 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Table 5 – Receiver Specifications (Optical)
Parameter Symbol Min. Typical Max. Unit Notes
Sensitivity - - - -33 dBm 14
Maximum Input Power Pin -3 - - dBm
Signal Detect-Asserted Pa - - -33 dBm 15
Signal Detect-Deasserted Pd -45 - - dBm 16
Signal Detect-Hysteresis - 1.0 - 4.0 dB
Cross Talk - - - -33 dB
Wavelength of Operation 1480 - 1600 nm 17
Wavelength of Operation 1260 - 1360 nm 18
Note 14: Measured with 223-1 PRBS, BER = 10-10.
Note 15: Measured on transition: low to high, The SD level should be deasserted when fiber disconnected
Note 16: The SD level should be deasserted when fiber is disconnected
Note 17: B-13/15-155(C)-F-SSC3x
Note 18: B-15/13-155(C)-F-SSC3x
Table 6 – Receiver Specifications (Electrical)
Parameter Symbol Min. Typical Max. Unit Notes
Power Supply Current ICC - - 100 mA
19
Data Output Voltage-Low VOL-VCC -2.0 - -1.58 V
Data Output Voltage-High VOH-VCC -1.1 - -0.74 V 20
Signal Detect Output Voltage-Low VSDL-VCC -2.0 - -1.58 V
Signal Detect Output Voltage-High VSDH-VCC -1.1 - -0.74 V
21
Signal Detect Output Voltage-Low VSDL-VCC - - 0.5 V
Signal Detect Output Voltage-High VSDH-VCC 2.0 - - V
22
Note 19: The current excludes the output load current
Note 20: These outputs are compatible with 10K, 10KH and 100KECL and LVPECL outputs.
Note 21: LVPECL, B-1x/1x-155-F-SLC3x
Note 22: LVPECL, B-1x/1x-155C-F-SLC3x
- 4 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Connection Diagram
Table 7 – Pin Definitions
Pin Unit Notes
1 RxGND
Directly connect this pin to the receiver ground plane
2 RxVcc
+3.3V dc power for the receiver section
3 SD
Active high on this indicates a received optical signal(LVPECL/LVTTL)
4 RD-
Receiver Data Out Bar(LVPECL)
5 RD+
Receiver Data Out (LVPECL)
6 TxVcc
+3.3V dc power for the transmitter section
7 TxGND
Directly connect this pin to the tranmitter ground plane
8 TxDIS
Transmitter disable(LVTTL)
9 TD+
Transmitter Data In (LVPECL)
10 TD-
Transmitter Data In Bar (LVPECL)
- 5 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Recommended Circuit Schematic
B-1x/1x-155-F-SSC3x(-G5)
Tx
Rx
TERMINATE AT
TRANSCEIVER INPUTS Z=50Ω
Z=50Ω
100Ω
TD-
TD+
130Ω
82Ω
Vcc(+3.3V)
100Ω
RD+
RD-
SD
Z=50Ω
Z=50Ω
Z=50Ω
130Ω130Ω
Vcc(+3.3V)
Vcc(+3.3V)
PHY DEVICE
LVPECL
LVPECL
10μF
C3C2
1μH
67810 9
12 3 4 5
1μH
C1
TERMINATE AT
DEVICE INPUTS
NOTE:C1=C2=C3=100nF
RxGND
RxVcc
SD
RD-
RD+ TxVcc
TxGND
TD+
TD-
TxDIS
Vcc(+3.3V)
130Ω
130Ω
LVTTL
Tx Disable
LVPECL
The split-loaded terminations for ECL signals need to be located at the input of devices receiving those ECL signals.
The power supply filtering is required for good EMI performance. Use short tracks from the inductor L1/L2 to the module Rx Vcc.
A GND plane under the module is required for good EMI and sensitivity performance.
- 6 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Recommended Circuit Schematic
B-1x/1x-155C-F-SSC3x(-G5)
Tx
Rx
TERMINATE AT
TRANSCEIVER INPUTS Z=50Ω
Z=50Ω
100Ω
TD-
TD+
130Ω
Vcc(+3.3V)
100Ω
RD+
RD-
SD
Z=50Ω
Z=50Ω
Z=50Ω
Vcc(+3.3V)
Vcc(+3.3V)
PHY DEVICE
LVPECL
LVPECL
10μF
C3C2
1μH
67810 9
12 3 4 5
1μH
C1
TERMINATE AT
DEVICE INPUTS
NOTE:C1=C2=C3=100nF
RxGND
RxVcc
SD
RD-
RD+ TxVcc
TxGND
TD+
TD-
TxDIS
Vcc(+3.3V)
130Ω
LVTTL
Tx Disable
LVTTL
The split-loaded terminations for ECL signals need to be located at the input of devices receiving those ECL signals.
The power supply filtering is required for good EMI performance. Use short tracks from the inductor L1/L2 to the module Rx Vcc.
A GND plane under the module is required for good EMI and sensitivity performance.
- 7 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Recommended Board Layout Hole Pattern
DIMENSION IN MILLIMETER (INCHES)
NOTES:
3.THE MOUNTING STUDS SHOULD BE SOLDERED TO CHASSIS GROUND FOR MECHANICAL INTEGRITY.
TRACES OR GROUND CONNECTION IN KEEP-OUT AREAS.
2.THE HATCHED AREAS ARE KEEP-OUT AREAS RESERVED FOR HOUSING STANDOFF. NO METAL
1.THIS FIGURE DESCRIBE THE RECOMMAND CIRCUIT BOARD LAYOUT FOR THE SFF TRANSCEIVER.
- 8 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Package Diagram
B-1x/1x-155(C)-F-SSC3(A)
PIN 6
PIN 5
Stud Stand-off PIN 10
Housing Lead
PIN 1
Stand-off
Stand-off
Housing Lead
Unit s: mm
- 9 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Package Diagram
B-1x/1x-155(C)-F-SSC3S
B-1x/1x-155(C)-F-SSC3AS
Housing Lead
Stud PIN 10
Housing Lead
PIN 6 Stand-off
PIN 1
Matel Finger
Stand-off
Stand-off
PIN 5
Unit s: mm
- 10 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Order Information
Table 8 – Order Information
Part No. Part No.
B-13/15-155-F-SSC3 B-13/15-155C-F-SSC3
B-15/13-155-F-SSC3 B-15/13-155C-F-SSC3
B-13/15-155-F-SSC3A B-13/15-155C-F-SSC3A
B-15/13-155-F-SSC3A B-15/13-155C-F-SSC3A
B-13/15-155-F-SSC3S B-13/15-155C-F-SSC3S
B-15/13-155-F-SSC3S B-15/13-155C-F-SSC3S
B-13/15-155-F-SSC3AS B-13/15-155C-F-SSC3AS
B-15/13-155-F-SSC3AS B-15/13-155C-F-SSC3AS
B-13/15-155-F-SSC3-G5 B-13/15-155C-F-SSC3-G5
B-15/13-155-F-SSC3-G5 B-15/13-155C-F-SSC3-G5
B-13/15-155-F-SSC3A-G5 B-13/15-155C-F-SSC3A-G5
B-15/13-155-F-SSC3A-G5 B-15/13-155C-F-SSC3A-G5
B-13/15-155-F-SSC3S-G5 B-13/15-155C-F-SSC3S-G5
B-15/13-155-F-SSC3S-G5 B-15/13-155C-F-SSC3S-G5
B-13/15-155-F-SSC3AS-G5 B-13/15-155C-F-SSC3AS-G5
B-15/13-155-F-SSC3AS-G5 B-15/13-155C-F-SSC3AS-G5
- 11 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Part Numbering Definition:
B - 1x/1x - 155(C) - F - S SC 3 Operating Temperature Shielding Finger -RoHS
Wavelength :
13/15 =
Tx Wavelength = 1310nm
Rx Wavelength = 1530nm
15/13 =
Tx Wavelength = 1530nm
Rx Wavelength = 1310nm
Communication Protocol
(155Mbps)
+3.3V SFF Transceiver
Single mode fiber
Connector options
Intermediate Reach
Operating Temperature
Blank = Commercial temper ature (0 to 70oC)
A = Commercial temperatur e (-40 to 85oC)
Shielding Finger Option
Blank = No shielding finger
S = with Shielding finger
RoHS compliance available
G5 = RoHS 5/6-compl iant product (lead exemption)
- 12 -
P/N: B-1x/1x-155(C)-F-SSC3x(-G5)
155 Mbps Bi-directional Receptacle Single Fiber Transceiver
DS-5750 Rev 0.0 2009-09-04
Warnings
Handling Precautions: This device is susceptible to damage as a result of electrostatic discharge (ESD). A static
free environment is highly recommended. Follow guidelines according to proper ESD procedures.
Laser Safety: Radiation emitted by laser devices can be dangerous to human eyes. Avoid eye exposure to direct or
indirect radiation.
Legal Notice
IMPORTANT NOTICE !
All information contained in this document is subject to change without notice, at Source Photonics’ sole and
absolute discretion. Source Photonics warrants performance of its products to current specifications only in
accordance with the company’s standard one-year warranty; however, specifications designated as “preliminary”
are given to describe components only, and Source Photonics expressly disclaims any and all warranties for said
products, including express, implied, and statutory warranties, warranties of merchantability, fitness for a particular
purpose, and non-infringement of proprietary rights. Please refer to the company’s Terms and Conditions of Sale for
further warranty information.
Source Photonics assumes no liability for applications assistance, customer product design, software performance,
or infringement of patents, services, or intellectual property described herein. No license, either express or implied,
is granted under any patent right, copyright, or intellectual property right, and Source Photonics makes no
representations or warranties that the product(s) described herein are free from patent, copyright, or intellectual
property rights. Products described in this document are NOT intended for use in implantation or other life support
applications where malfunction may result in injury or death to persons. Source Photonics customers using or
selling products for use in such applications do so at their own risk and agree to fully defend and indemnify Source
Photonics for any damages resulting from such use or sale.
THE INFORMATION CONTAINED IN THIS DOCUMENT IS PROVIDED ON AN “AS IS” BASIS. Customer agrees
that Source Photonics is not liable for any actual, consequential, exemplary, or other damages arising directly or
indirectly from any use of the information contained in this document. Customer must contact Source Photonics to
obtain the latest version of this publication to verify, before placing any order, that the information contained herein is
current.
Contact
U.S.A. Headquarters
20550 Nordhoff Street
Chatsworth, CA 91311
USA
Tel: +1-818-773-9044
Fax: +1-818-773-0261
sales@sourcephotonics.com
China
Building #2&5, West Export Processing Zone
No. 8 Kexin Road, Hi-Tech Zone
Chengdu, 611731, China
Tel: +86-28-8795-8788
Fax: +86-28-8795-8789
sales@sourcephotonics.com.cn
Taiwan
9F, No 81, Shui Lee Rd.
Hsinchu, 300, Taiwan
R.O.C.
Tel: +886-3-5169222
Fax: +886-3-5169213
sales@sourcephotonics.com.tw
© Copyright Source Photonics, Inc. 2007~2008
All rights reserved