Transient thermal measurement of laser diodes

1998 Proceedings. 48th Electronic Components and Technology Conference (Cat. No.98CH36206) Pub Date : 1998-05-25 DOI:10.1109/ECTC.1998.678931

C.C. Lee, J. Velasquez

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引用次数: 1

Abstract

In this research, the transient thermal response of laser diodes is measured using light power as the temperature sensitive parameter. It is well known that the light power of a laser diode decreases as temperature increases. When the laser is driven by a long pulse signal, the light power decreases within the pulse duration as a result of temperature increase. From the percentage of light power decrease versus time, the temperature rise as a function of time is deduced. In determining the temperature rise, a calibration curve of power versus temperature is used. This curve is produced by measuring the peak light power of the laser driven by a short pulse over a range of case temperature. Under short pulse condition, the laser junction temperature is approximated by the case temperature since the junction does not have enough time to heat up. For the approximation to be valid, the short pulse width must be much shorter than the thermal time constant of the laser. Several commercial laser diodes are studied. In the experiment, the laser case temperature is measured by a thermal coupler-based digital thermometer with an accuracy of /spl plusmn/0.1/spl deg/C. The accuracy is verified by boiling water and ice water temperatures.

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激光二极管瞬态热测量

本研究以光功率为温敏参数，测量激光二极管的瞬态热响应。众所周知，激光二极管的光功率随着温度的升高而降低。当激光由长脉冲信号驱动时，由于温度升高，光功率在脉冲持续时间内减小。从光功率随时间下降的百分比，推导出温度随时间上升的函数。在确定温升时，使用功率与温度的校准曲线。这条曲线是通过测量在一定温度范围内由短脉冲驱动的激光的峰值光功率而产生的。在短脉冲条件下，由于结没有足够的时间加热，激光结温度近似于外壳温度。为了使近似有效，短脉冲宽度必须远远小于激光的热时间常数。研究了几种商用激光二极管。在实验中，采用基于热耦合器的数字温度计测量激光外壳温度，测量精度为/spl plusmn/0.1/spl度/C。通过沸水和冰水的温度来验证其准确性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

1998 Proceedings. 48th Electronic Components and Technology Conference (Cat. No.98CH36206)

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