考虑垂直腔面发射激光器(VCSEL)在稳态时载流子数和光子数关系,改进了工作电流与输出光功率强度(L-I)模型的经验公式,利用交替方向乘子法,基于实测数据确定模型的参数.该模型在考虑激光器的偏置电流受激光器温度影响的同时,还考虑了激...考虑垂直腔面发射激光器(VCSEL)在稳态时载流子数和光子数关系,改进了工作电流与输出光功率强度(L-I)模型的经验公式,利用交替方向乘子法,基于实测数据确定模型的参数.该模型在考虑激光器的偏置电流受激光器温度影响的同时,还考虑了激光器内部参数之间的耦合关系.仿真结果显示,改进后的模型所得参数,代入经验L-I模型,在相同算法条件下,和实测数据之间的均方误差值比仅考虑激光器偏置电流受温度影响的L-I模型的参数估计方法降低了约1.61 d B.同时,在较高的温度下工作,改进L-I曲线工作电流的有效区间更大.展开更多
Abstract: The homogeneous, intensity modulated salinity sensor using the photonic crystal ring resonator (PCRR) is proposed and designed for monitoring the salinity of the seawater from 0% to 100% (0 g/L to 100 g/...Abstract: The homogeneous, intensity modulated salinity sensor using the photonic crystal ring resonator (PCRR) is proposed and designed for monitoring the salinity of the seawater from 0% to 100% (0 g/L to 100 g/L) at 25℃. The concentration of the salinity in the seawater changes the refractive index of the seawater. The change in the refractive index of the seawater brings the change in the output signal intensity of the sensor as the output power and mapping the salinity level, the seawater flows inside the sensor. By detecting the salinity can be evaluated. The proposed sensor is composed of periodic Si rods embedded in an air host with a circular PCRR placed between the inline quasi waveguides. Approximately, 2.69% of output power reduction is observed for every 5% (5 g/L) increase in the salinity as the seawater has a unique refractive index for each salt level. With this underlying principle, the performance of the sensor is analyzed for different temperatures.展开更多
文摘考虑垂直腔面发射激光器(VCSEL)在稳态时载流子数和光子数关系,改进了工作电流与输出光功率强度(L-I)模型的经验公式,利用交替方向乘子法,基于实测数据确定模型的参数.该模型在考虑激光器的偏置电流受激光器温度影响的同时,还考虑了激光器内部参数之间的耦合关系.仿真结果显示,改进后的模型所得参数,代入经验L-I模型,在相同算法条件下,和实测数据之间的均方误差值比仅考虑激光器偏置电流受温度影响的L-I模型的参数估计方法降低了约1.61 d B.同时,在较高的温度下工作,改进L-I曲线工作电流的有效区间更大.
文摘Abstract: The homogeneous, intensity modulated salinity sensor using the photonic crystal ring resonator (PCRR) is proposed and designed for monitoring the salinity of the seawater from 0% to 100% (0 g/L to 100 g/L) at 25℃. The concentration of the salinity in the seawater changes the refractive index of the seawater. The change in the refractive index of the seawater brings the change in the output signal intensity of the sensor as the output power and mapping the salinity level, the seawater flows inside the sensor. By detecting the salinity can be evaluated. The proposed sensor is composed of periodic Si rods embedded in an air host with a circular PCRR placed between the inline quasi waveguides. Approximately, 2.69% of output power reduction is observed for every 5% (5 g/L) increase in the salinity as the seawater has a unique refractive index for each salt level. With this underlying principle, the performance of the sensor is analyzed for different temperatures.
