The detailed analysis of rate equation roots of BH-laser diode using Volterra series
In this study, the rate equation analysis of a BH-laser diode was performed for output carrier density (No) using the zero-degree solution of the Volterra series. The carrier rate equation of the laser diode was analyzed in terms of input carrier density (Ni) and output carrier density modeling (Ni-No), with respect to the DC current (Io). The polynomial root, which is obtained from the zero-degree solution (No) and limit values of Io, was found. For the linear operation of the laser diode, the range of Io current was also determined using a linearization approach and the maximum value of No.
The detailed analysis of rate equation roots of BH-laser diode using Volterra series
In this study, the rate equation analysis of a BH-laser diode was performed for output carrier density (No) using the zero-degree solution of the Volterra series. The carrier rate equation of the laser diode was analyzed in terms of input carrier density (Ni) and output carrier density modeling (Ni-No), with respect to the DC current (Io). The polynomial root, which is obtained from the zero-degree solution (No) and limit values of Io, was found. For the linear operation of the laser diode, the range of Io current was also determined using a linearization approach and the maximum value of No.
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