DATA SHEET d FEATURES: SC ROSA PIN-1310-10LR-SC includes flex circuit High performance InGaAs PIN photodiode with separate transimpedance amplifier Low electrical parasitic TO46 package Data rates up to 11.3Gbps Separate PD supply for power monitoring Low bias currents and voltages Low power dissipation IEEE 10G-BASE-LR applications 10 GBPS 1310NM PIN + PREAMP SC AND LC ROSA PACKAGE PIN-1310-10LR-SC The PIN-1310-10LR-SC uses a high-performance InGaAs PIN photo-detector packaged with a transimpedance amplifier designed to meet performance requirements for data rates up to 11.3Gbps data communication over singlemode and multi-mode optical fiber at 1310nm. Applications include Ethernet, Fiber Channel and ATM protocols. The optical assembly is designed to interface to single mode optical fiber. The PIN-1310-10LR-SC is designed to be paired with AOC FP and DFB TOSA products (see data sheets for FP-1310 and DFB-1310 and products). Part Number PIN-1310-10LR-SC Description 5 pin SC ROSA, with separate PD bias, with flex circuit PIN-1310-10LR-SC 10 GBPS 1310NM PIN + PREAMP ABSOLUTE MAXIMUM RATINGS Parameter Rating Storage Temperature -40 to +85°C Case Operating Temperature -10 to +85°C Lead Solder Temperature Power Supply Voltage Incident Optical Power 260°C, 10 sec. -0.5V to 4V +3 dBm average, +5 dBm peak Storage Temperature -40 to +85°C Notice Stresses greater than those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operations section for extended periods of time may affect reliability. Notice The inherent design of this component causes it to be sensitive to electrostatic discharge (ESD). To prevent ESD-induced damage and/or degradation to equipment, take normal ESD precautions when handling this product PIN-1310-10LR-SC 10 GBPS 1310NM PIN + PREAMP ELECTRO-OPTICAL CHARACTERISTICS 3.0V<Vcc<3.6V, AC coupled to 50Ω (100Ωdifferential), -10°C<T<85°C unless otherwise specified, with flex circuit VCSEL Parameters Data Rate Test Condition Symbol DR Min. 0.1 Typ. Max. 11.3 Units Gbps 3.0 3.3 3.6 V 35 60 mA Supply Voltage Supply Current PR =0μW, RL=50ΩAC coupled Optical Return Loss Input Optical Wavelength PD Responsivity PR =-12dBm ICC 1 ORL λP Resp 12 1260 0.8 0.85 PD Bias VPD 3.0 3.3 Maximum Average Input Power before Overload PMAX +1 +3 λ = 1310nm Differential Output Voltage Swing PR,OMA= -12Bm, AC Coupled to RL=50Ω Vo(pk-pk) 100 Differential Responsivity PR,OMA = -12dBm, AC Coupled to RL=50Ω T 3000 -3dB Optical/Electrical Bandwidth Low Frequency –3dB Cutoff Output Impedance Output Return Loss Sensitivity Stressed Sensitivity Rise/Fall Time Differential Power Supply Rejection Ratio Group Delay R0=50Ω, DC 10≤GHZ DR = 10.3125Gbps Circadiant Test PR,OMA =-12dBm, (20%80%), PR =0μW (Dark), 5MHz<F<2GHz PR,OMA = -12dBm, AC Coupled to RL=50Ω 2MHz<F<6GHz 1620 dB nm A/W 1 1 3.6 dBm 600 mV 1,2 V/W 1,2 BW TA = 25°C Notes 7.5 BWLF ZOUT S22 S SSTRESS TR/TF 40 PSRR 20 Delay -50 50 30 60 -7 -16.5 -12 45 50 GHz 1,2,3 KHz Ω dB dBm dBm ps 1,2,3 dB 1,6 ps 7 4 4 2,5 NOTES: 1. 2. PR is the average optical power at the fiber face. PR,OMA is the peak to peak optical power at the fiber face (Optical Modulation Amplitude) PR ,OMA ≡ 2 PR (ER − 1) ER + 1 where ER is the extinction ratio (linear) of the optical source. 3. 4. Bandwidth and Low Frequency Cutoff are measured with a small signal sinusoidal light source with –10dBm average power Sensitivity is measured with an optical source with an extinction ratio of 6dB. For sensitivity measurements at 10.3125, 10.51875, 10.70923, 11.09573, 11.31764 Gb/s, PRBS 2^31-1, ER=6dB, BER < 10-12and with limiting of the TIA is assumed to be implemented at the front end of the post amplifier. Stress testing is done using a Circadiant test system 5. Rise/Fall times are corrected for optical source Rise/Fall times. 6. 7. Value shown is with no external power supply filtering. Group delay is a sensitive measurement to package interface, and includes the effects of PD, TIA and package. Measurement is made with TO leads as short as possible. 8. DJTIA is specified as contributed DJ by the TIA, obtained from 9. RJTIA is specified as contributed RJby the TIA, obtained from 10. The electrical performance of the ROSA is dependent upon the quality of the electrical connection between the TO can and the circuit board. AOC cannot guarantee all performance specifications for parts without the flex circuit attached. 2 2 2 TTIA = TMEASURED − TOPTICAL 2 2 2 DJ TIA = DJ TOTAL − DJ OPTICAL 2 2 2 RJ TIA = RJ TOTAL − RJ OPTICAL PIN-1310-10LR-SC 10 GBPS 1310NM PIN + PREAMP PINOUT: PIN 1 2 3 4 5 6 Pin 6 Vpd Case OUTN OUTP Case Vcc Description Vcc CASE OUTP OUTN CASE VPD 50Ω Case Pin 1 PIN-1310-10LR-XX INTERFACE EXAMPLE VPD 100Ω 20x VCC VPD 100nF OUTN 50Ω OUTP 50Ω Case 100Ω Limiting Amp RSSI ~ 1V/mW VCC Note: 100Ω resistor only needed with high impedance limiting amplifiers Optional 100Ω differential termination for high impedance limiting amplifiers is shown in red. RECOMMENDED BIAS NETWORK Note, better performance will be obtained if a ferrite bead is used in place of the inductor. IN 22uH 100uF OUT 100nF PIN-1310-10LR-SC 10 GBPS 1310NM PIN + PREAMP MECHANICAL DIMENSIONS (mm) PIN-1310-LR-SC PIN-1310-10LR-SC 10 GBPS 1310NM PIN + PREAMP ADVANCED OPTICAL COMPONENTS AOC CAPABILITIES Finisar’s ADVANCED OPTICAL COMPONENTS division was formed through strategic acquisition of key optical component suppliers. The company has led the industry in high volume Vertical Cavity Surface Emitting Laser (VCSEL) and associated detector technology since 1996. VCSELs have become the primary laser source for optical data communication, and are rapidly expanding into a wide variety of sensor applications. VCSELs’ superior reliability, low drive current, high coupled power, narrow and circularly symmetric beam and versatile packaging options (including arrays) are enabling solutions not possible with other optical technologies. ADVANCED OPTICAL COMPONENTS is also a key supplier of Fabrey-Perot (FP) and Distributed Feedback (DFB) Lasers, and Optical Isolators (OI) for use in single mode fiber data and telecommunications networks ADVANCED OPTICAL COMPONENTS’ advanced capabilities include: 1, 2, 4, 8, and 10Gbps serial VCSEL solutions 1, 2, 4, 8, and 10Gbps serial SW DETECTOR solutions VCSEL and detector arrays 1, 2, 4, 8, and 10Gbps FP and DFB solutions at 1310 and 1550nm 1, 2, 4, 8, and 10Gbps serial LW DETECTOR solutions Optical Isolators from 1260 to 1600nm range Laser packaging in TO46, TO56, and Optical subassemblies with SC, LC, and MU interfaces for communication networks VCSELs operating at 670nm, 780nm, 980nm, and LOCATION Allen, TX - Business unit headquarters, VCSEL wafer growth, wafer fabrication and TO package assembly. Fremont, CA – Wafer growth and fabrication of 1310 to 1550nm FP and DFB lasers. Shanghai, PRC – Optical passives assembly, including optical isolators and splitters. 1310nm in development Sensor packages include surface mount, various plastics, chip on board, chipscale packages, etc. Custom packaging options SALES AND SERVICE Finisar’s ADVANCED OPTICAL COMPONENTS division serves its customers through a worldwide network of sales offices and distributors. For application assistance, current specifications, pricing or name of the nearest Authorized Distributor, contact a nearby sales office or call the number listed below. Phone: 1-866-MY-VCSEL USA (toll free) 1-214-509-2700 USA (Direct dial) Fax: 1-2140509-3709 USA 44 (0) 174 336 5533 Europe 886-935-409898 China & Taiwan 81-90-4437-1130 Japan 82-11-220-6153 Asia Pacific & Korea Email: [email protected] WEB: www.finisar.com/aoc.php ©2008 Finisar Corporation. All rights reserved. Finisar is a registered trademark of Finisar Corporation. Features and specifications are subject to change without notice. 02/09 Rev. C