LiDAR Beam Steering and Optics

LiDAR Technologies and Systems Pub Date : 2019-07-11 DOI:10.1117/3.2518254.CH7

P. McManamon

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Abstract

There are many ways to steer optical beams. Historically, steering an optical beam meant moving a mirror or a transmissive optical element. Over the last few decades, other approaches have been developed that involve creating an optical path difference (OPD) or a phase difference. We can group beam steering methods into mechanical and nonmechanical approaches. Nonmechanical approaches are sometimes called optical phased arrays (OPAs) because they change the angle of an optical beam based on changing the phase profile of that optical beam. Microwave phased-array radars, which have been around for decades, use this approach of changing the phase of an outgoing or incoming beam. The much-shorter wavelength associated with optical systems makes this approach more difficult. Following the discussion of mechanical and nonmechanical approaches to beam steering, a few relevant optical design parameters for a LiDAR are presented. This topic includes a brief discussion of adaptive optics, as well as how to use some of the presented nonmechanical techniques to make dynamically adaptive optical elements. If it is possible to change a phase profile across an optical element to steer a beam, then it is also possible to change a phase profile to make a lens or another optical element. The future era of flexible optical elements will be an enabler.

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激光雷达光束转向与光学

有许多方法来控制光束。从历史上看，控制光束意味着移动镜子或透射光学元件。在过去的几十年里，已经开发了其他方法，包括创建光程差(OPD)或相位差。我们可以将波束导向方法分为机械导向和非机械导向。非机械方法有时被称为光学相控阵(OPAs)，因为它们通过改变光束的相位轮廓来改变光束的角度。微波相控阵雷达，已经存在了几十年，使用这种方法来改变发射或入射光束的相位。光学系统的波长要短得多，这使得这种方法更加困难。在讨论了光束导向的机械和非机械方法之后，提出了激光雷达的一些相关光学设计参数。本主题包括对自适应光学的简要讨论，以及如何使用一些提出的非机械技术来制造动态自适应光学元件。如果有可能通过改变一个光学元件的相位轮廓来引导光束，那么也有可能改变一个相位轮廓来制造透镜或另一个光学元件。柔性光学元件的未来时代将是一个推动者。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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LiDAR Technologies and Systems

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