The PL-FP-940-1-A81 -PA-FBG is 940 nm pump laser modules uses a number of revolutionary design steps and the very latest material technologies to significantly improve scalability of the production process. The semicooled 45°C laser diode operation provides for a significant reduction in TEC and overall power consumption. The module meets the stringent requirements of the telecommunications industry including Telcordia GR-468-CORE for hermetic 940 nm pump modules.The LD-PD Series pump module, which uses Fiber Bragg grating stabilization to lock the emission wavelength, provides a noise-free, narrowband spectrum even under changes in temperature, drive current, and optical feedback. Wavelength selection is available for applications requiring the highest performance in spectrum control with the highest power available.
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● Optical output: Up to 100mW
● FC-APC connector
● 14-PIN butterfly package
● Fiber Bragg grating stabilization
● Wavelength selection available
● Integrated thermoelectric cooler, thermistor, and monitor diode
● High dynamic range
● Excellent low power stability
Electrical/Optical Characteristics (Tsub=25°C, CW bias unless stated otherwise)
1. The tracking ratio is a measure of the front-to-back tracking when the output power is varied. On a plot of optical power versus back-face photocurrent, a straight line is drawn between the minimum power (30 mW) and the operating power (Pop) points. The tracking ratio is defined as the ratio between measured optical power (shown as data points on the plot) to the value derived from the straight line.
2. The tracking error is defined as the normalized change of output power relative to Pf at 25°C, that is, (Pf – Pf_25)/Pf_25, over case temperature range of 0 to 75°C, at constant back face monitor current corresponding to the lowest back face monitor current at Pf= Pop of 0°C, 25°C, 75°C.
3. Datasheet for Calculating Temperature from the resistance of the Thermistor is available now. You can contact us for details.
Thermoelectric Cooler (+)
PD Monitor Anode (-)
laser Anode (+)
PD Monitor Cathode (+)
Laser Cathode (–)
Thermoelectric Cooler (–)
HI 1060 Fiber Nominal Characteristics and Tolerances
Cut off wavelength
Core Cladding Concentricity
Mode Field diameter
Absolute Maximum Ratings
● Pump Laser
● Dense wavelength division multiplexing (DWDM)
● EDFAs for small package designs
● High bit-rate, high channel-count EDFAs
● CATV distribution
☆: Output Power
▽: Wavelength Tolerance
XX: Fiber and Connector Type
PP=PM 980 Fiber+ FC/PC
PA=PM 980 Fiber+ FC/APC
The LD-PD pump laser module emits hazardous invisible laser radiation.The pump laser module emits hazardous invisible laser radiation.Due to the small size of the pump module, the box packaging is labeled with the laser radiation hazard symbol and safety warning labels shown below
Safety and Operating Considerations
The laser light emitted from this laser diode is invisible and may be harmful to the human eye. Avoid looking directly into the fiber when the device is in operation.
CAUTION: THE USE OF OPTICAL INSTRUMENTS WITH THIS PRODUCT INCREASES EYE HAZARD.
Operating the laser diode outside of its maximum ratings may cause device failure or a safety hazard. Power supplies used with this component cannot exceed maximum peak optical power.
CW laser diodes may be damaged by excessive drive current or switching transients. When using power supplies, the laser diode should be connected with the main power on and the output voltage at zero. The current should be increased slowly while monitoring the laser diode output power and the drive current. Careful attention to heatsinking and proper mounting of this device is required to ensure specified performance over its operating life. To maximize thermal transfer to the heatsink, the heatsink mounting surface must be flat to within .001inch and the mounting screws must be torqued down to 1.5 in/lb.
ESD PROTECTION—Electrostatic discharge (ESD) is the primary cause of unexpected laser diode failure. Take extreme precaution to prevent ESD. Use wrist straps, grounded work surfaces, and rigorous antistatic techniques when handling laser diodes.