超快全光波长和偏振无关解复用器

K. I. Kang, T. Chang, I. Glesk, P. Prucnal
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摘要

基于干涉原理的全光交换器件的最新发展对光通信系统,特别是基于光时分复用系统(OTDM)的光通信系统非常有前景,在OTDM系统中,用户可以在给定的时间框架内在指定的时隙内发送或接收数据。其中一种基于Sagnac干涉仪的装置被称为太赫兹光学非对称解复用器(TOAD)。另一种基于Mach-Zehnder干涉仪的装置是对称Mach-Zehnder (SMZ)。这两种器件都利用了半导体谐振区较大的光学非线性,因此可以用非常小的光控制脉冲能量来操作这些器件。目前演示的TOAD可以切换到0.8 pJ, SMZ可以切换到11 pJ。我们仍然可以通过优化和采用其他非线性光学材料来降低控制脉冲能量。利用Sagnac干涉仪中非线性光学元件的特殊几何位置和两个控制脉冲对Mach-Zehnder进行独立的开关操作,解决了共振非线性恢复时间慢的最关键问题。利用0.65 pJ的控制脉冲能量,在马赫-曾德尔干涉仪中反向传播控制脉冲和数据脉冲,实现了10 ps的切换窗口。该装置的优点是对控制信号有较好的抑制能力。就集成的可能性而言,该设备的设计预计将比之前演示的系统简单得多。此外,所利用的光学非线性元件是半导体光放大器,数据信号可以大于输入。这可以促进级联性和扇形输出能力。
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Ultrafast all-optical wavelength and polarization independent demultiplexer
Recent developments in all-optical switching devices based on the interferometric principle are very promising for optical communication systems, especially those based on optical time division multiplexing system (OTDM), where a user is allowed to transmit or receive a data in a assigned time slot within a given time frame. One such device based on a Sagnac interferometer is called a Terahertz Optical Asymmetric Demultiplexer (the TOAD). Another device based on a Mach-Zehnder interferometer is a Symmetric Mach-Zehnder (SMZ). Both devices utilize large optical nonlinearities in the resonance regime of the semiconductor, therefore it is possible to operate these devices with a very small optical control pulse energy. The currently demonstrated TOAD can be switched with 0.8 pJ, and the SMZ with 11 pJ. We still can reduce the control pulse energy by optimizing and employing other nonlinear optical materials. The most critical problem associated with a slow recovery time of the resonance nonlinearities has been solved by a special geometrical location of a nonlinear optical element in the Sagnac interferometer, and two control pulses to do independent on and off switching operation for the Mach-Zehnder. We demonstrated a 10 ps switching window by counter-propagating the control and data pulses in the Mach-Zehnder interferometer using 0.65 pJ of control pulse energy. This device is advantageous in its superior rejection capability of the control signal. In terms of the possibility of integration, this device is expected to be a much simpler design than the previously demonstrated systems. Also the utilized optical nonlinear elements are semiconductor optical amplifiers, the data signal can be larger than the input. This may facilitate cascadability and fan-out capability.
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