Abstract
The amplification characteristics of picosecond Gaussian pulses in conventional nontapered and both linear and exponential tapered-waveguide (TW) laser-diode amplifier (LDA) structures have been studied. The analysis is based on numerical simulation of the rate equation which also takes into account the effect of lateral carrier density distribution. The amount of pulse distortion experienced within the amplifier for input pulses having energies E/sub in/=0.1 E/sub sat(in)/=0.475 pJ (where E/sub sat(in)/ is the input saturation energy of the amplifier) and E/sub in/=E/sub sat(in)/=4.75 pJ have been analyzed for each structure which has a length of 900 /spl mu/m and an input width of 1 /spl mu/m. It has been found that the TW-LDA provides higher gain saturation and hence imposes less distortion on the amplified pulse as compared with a conventional nontapered LDA. The amplified 10-ps pulse used in this study experiences almost no broadening in the TW-LDA, whereas it suffers from broadening in the conventional nontapered LDA. The carrier density distribution and the dependence of the amplifier gain on the input pulse energy have also been studied for both nontapered and tapered amplifier structures. For example, in a TW-LDA with an output width of 20 /spl mu/m and a length of 900 /spl mu/m, the exponential structure provides 9-dB improvement in saturation energy as compared with the conventional amplifier. This improvement is about 10.5 dB in linear TW-LDAs.
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More From: IEEE Journal of Selected Topics in Quantum Electronics
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