OPV300

Vertical Cavity Surface Emitting Laser in TO-18 Package • • • • • • • • • • Features 850nm VCSEL Technology Data rates up to 2.5 Gbps High thermal stability Low drive current/high output density Narrow and concentric beam angle Recommended for multimode fiber applications Flat Window Burned in for communication level reliability Recommended for external lens applications Suitable for sensing applications Absolute Maximum Ratings (TA = 25° C unless otherwise noted) Storage Temperature Operating Temperature Soldering Lead Temperature Maximum Forward Peak Current Maximum Reverse Voltage Max. Continuous Optical Power at 70°C -40° C to +100° C 0° C to +70° C 260° C for 10 Seconds 20 mA 10 V 1.1 mW Description The OPV300 is a high performance 850nm VCSEL packaged for high speed communication links. This product’s combination of features including high speed, high output power and concentric beam makes it an ideal transmitter for integration into all types of data communications equipment. Applications include: ♦ ♦ ♦ ♦ ♦ ♦ Fibre Channel Gigabit Ethernet ATM VSR (Very Short Reach) Intra-system links Optical backplane interconnects. Additional laser safety information can be found on the Optek website. See application #221. Classification is not marked on the device due to space limitations. See package outline for centerline of optical radiance. Operating devices beyond maximum rating may cause devices to exceed rated classification September 2003 Issue 3.3 Optek Technology, Inc. Carrollton, Texas 75006 (972) 323-2200 sensor@optekinc.com www.optekinc.com Page 1 of 4 OPV300 Technical Data Electrical/Optical Characteristics (at 25 C unless otherwise specified) SYMBOL POT ITH VF IR RS PARAMETER Total Power Out Threshold Current Forward Voltage Reverse Current Series Resistance Slope Efficiency Linearity MIN 1.50 0.80 1.60 TYP MAX 3.00 2.20 35 UNITS mW mA V nA ohms mW/mA TEST CONDITIONS IF = 7 mA Note1 IF = 7 mA VR = 5 V Note 2 Note 3 Note 4 20 0.28 0.00 840 850 55 η λ ∆λ θ tr/tf NRI ∆lTH/∆T ∆λ/∆T ∆VF/∆T ∆η/∆T NOTES: (1) (2) (3) (4) W avelength Optical Bandwidth Beam Divergence Rise and Fall Time Relative Intensity Noise Temp Coefficient of Threshold Current Temp Coefficient of Wavelength Temperature Coefficient for VF Temperature Coefficient for Efficiency 860 0.85 nm nm Degree ps db/Hz mA %/° C mV/° C %/C 0° - 70° C, Note 1 0° - 70° C, IF = 7 mA 0° - 70° C, IF = 7 mA 0° - 70° C, Note 3 IF = 7 mA 20% to 80% 24 100 -123 ±1.0 0.06 -2.5 -0.5 Threshold Current is based on the two line intersection method specified in Telcordia GR-468-Core. Line 1 from 4 mA to 6 mA. Line 2 from 0 mA to 0.5 mA. Series Resistance is the slope of the Voltage-Current line from 5 to 8 mA. Slope efficiency, is the slope of the best fit LI line from 5 mA to 8 mA using no larger than 0.25 mA test interval points. Using data points taken for slope efficiency above, delta L/delta I shall be calculated for each adjacent pair of points. Optek reserves the right to make changes at any time, without notice, in order to improve design and provide the best product possible. September 2003 Issue 3.3 www.optekinc.com Optek Technology, Inc. Carrollton, Texas 75006 (972) 323-2200 sensor@optekinc.com Page 2 of 4 OPV300 Technical Data Normalized Output Power vs. Forward Current Normalized Output Power (7mA, 25 Forward Current (mA) Optek reserves the right to make changes at any time, without notice, in order to improve design and provide the best product possible. September 2003 Issue 3.3 www.optekinc.com Optek Technology, Inc. Carrollton, Texas 75006 (972) 323-2200 sensor@optekinc.com Page 3 of 4 OPV300 Technical Data Invisible Light emits from this surface OPV300 Pin 1 2 3 Connection VCSEL Anode VCSEL Cathode N/C Optek reserves the right to make changes at any time, without notice, in order to improve design and provide the best product possible. September 2003 Issue 3.3 www.optekinc.com Optek Technology, Inc. Carrollton, Texas 75006 (972) 323-2200 sensor@optekinc.com Page 4 of 4