基于分数泰伯效应的双波长微距分束的研究

杨磊; 江敏; 赵宁波; 谢洪波

doi:doi:10.3788/irla201847.0220003

红外与激光工程, 2018, 47 (2): 0220003, 网络出版: 2018-04-26

基于分数泰伯效应的双波长微距分束的研究

Investigation on micro-distance dual-wavelength separation using fractional Talbot effect

论文大纲

杨磊江敏赵宁波谢洪波

作者单位

天津大学精密仪器与光电子工程学院光电信息技术教育部重点实验室, 天津 300072

阶梯相位光栅频谱分离分数泰伯效应中红外波段 stepped phase grating spectral separation fractional Talbot effect mid-infrared band

摘要

微距光谱分束是红外领域小型双波段成像系统的关键技术之一。利用菲涅耳衍射理论和角谱理论, 研究了双波长和宽角度入射光场通过阶梯光栅在分数泰伯距离下的衍射特性。建立了基于阶梯光栅的双探测阵列成像模型, 数值模拟了入射波长分别为4 μm和4.5 μm的光束在-30°~30°入射角度范围的光栅分束结果, 获取了探测面上的发光强度、能量和信噪比等参数值。此文的研究成果可为构建微型双波段成像装置及设计精密光谱分束器件提供理论支持。

Abstract

Micro-distance spectra splitting is a key technology for compact dual-band imaging system in infrared field. Utilizing the Fresnel diffraction theory and angular spectrum theory, the diffractive properties of dual-wavelength and wide angle light passing through stepped phase grating in fractional Talbot distance were theoretically investigated. A typical scheme of imaging structure based on dual-array detection pixels was set up, where two light beams with different wavelength incidented after passing through the stepped phase grating. The numerical simulation shows the splitting results of incident light of 4 μm and 4.5 μm wavelength with -30° to 30° angle, including the distribution of luminous intensity, energy and signal-to-noise ratio on dual-array detection pixels. Our results are beneficial not only for designing the compact dual-band optical imaging structure, but also for building up precision spectral separating component.

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杨磊, 江敏, 赵宁波, 谢洪波. 基于分数泰伯效应的双波长微距分束的研究[J]. 红外与激光工程, 2018, 47(2): 0220003. Yang Lei, Jiang Min, Zhao Ningbo, Xie Hongbo. Investigation on micro-distance dual-wavelength separation using fractional Talbot effect[J]. Infrared and Laser Engineering, 2018, 47(2): 0220003.

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