Optical adaptive filtering for Doppler shift simulator

Based on free space laser communication, this article describes the working principle of electro-optical frequency shifting, designs an optical adaptive filtering module, and builds the core module of the dynamic optical Doppler shifting simulator for laser channel. It is expected to be applied to the heaven-ground integrated communication link. In this article, we adopt the electro-optical frequency shifting technique combined with the microwave-light wave. In the 1 550 nm band, the negative feedback algorithm is used to complete the adaptive filtering, which realizes optical Doppler frequency shifting and high-precision locking. The frequency shift range reaches +5.5—+32 GHz, and the analog precision is better than 645 Hz. When the microwave frequency is greater than 13.5 GHz, the signal-to-noise ratio (SNR) of the output optical power reaches 20 dB, which lays the foundation for the next stage space laser communication.     

基于微环的响应可切换微波光子滤波器

基于微环谐振腔和光纤布拉格光栅，利用相位-强度调制，实现了三种滤波响应可切换微波光子滤波器。通过改变光纤布拉格光栅反射谱、微环谐振腔陷波和光载波三者之间的相对波长，微波光子滤波器的滤波响应可以在带通、平顶带通和高通之间切换。制备了欧拉微环并搭建了微波光子滤波器系统，实现了上述三种响应。三种响应的带宽均具有一定的调谐能力，其调谐范围分别为5.56～7.68 GHz、6.23～11.92 GHz和5.83～10.86 GHz。三种响应下微环的插入损耗均小于10 dB。可切换的滤波响应使该微波光子滤波器具有更高的灵活性，在频率测量、杂散抑制等场景中具有广阔的应用空间。