Flash and point-and-shoot hybrid lidar by DMD-based solid-state diffractive beam and image steering

Jeff Chan; Xianyue Deng; Ted Liang Tai Lee; Rajesh Shrestha; Yefu Zhang; Emil Rajan Varghese; Yuzuru Takashima

doi:10.1364/OE.545153

Flash and point-and-shoot hybrid lidar by DMD-based solid-state diffractive beam and image steering

Jeff Chan
, Xianyue Deng
, Ted Liang Tai Lee
, Rajesh Shrestha
, Yefu Zhang
, Emil Rajan Varghese
, Yuzuru Takashima

Optical Sciences

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Solid-state implementation of lidar is highly anticipated for a wide field of view (FOV), long range, high resolution, and high-framerate lidar, yet is elusive. Traditional solid-state flash lidar using a 2-dimensional detector array suffers from a trade-off among FOV, range, and resolution due to the limited number of pixels. To decouple the trade-off while retaining solid-state implementation, we demonstrate an optical architecture that hybridizes flash and a point-and-shoot lidar, which is enabled by diffractive beam and image steering by digital micromirror device (DMD). With a low pixel count detector, a 32 × 32-pixel silicon photo multiplier (SiPM), the lidar image steering method employs a time-multiplexing method to expand the FOV to 49.5 degrees, while preserving an angular resolution of 0.22 degrees and achieving a frame rate exceeding 142 fps.

Original language	English (US)
Pages (from-to)	19650-19663
Number of pages	14
Journal	Optics Express
Volume	33
Issue number	9
DOIs	https://doi.org/10.1364/OE.545153
State	Published - May 5 2025

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics

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10.1364/OE.545153

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title = "Flash and point-and-shoot hybrid lidar by DMD-based solid-state diffractive beam and image steering",

abstract = "Solid-state implementation of lidar is highly anticipated for a wide field of view (FOV), long range, high resolution, and high-framerate lidar, yet is elusive. Traditional solid-state flash lidar using a 2-dimensional detector array suffers from a trade-off among FOV, range, and resolution due to the limited number of pixels. To decouple the trade-off while retaining solid-state implementation, we demonstrate an optical architecture that hybridizes flash and a point-and-shoot lidar, which is enabled by diffractive beam and image steering by digital micromirror device (DMD). With a low pixel count detector, a 32 × 32-pixel silicon photo multiplier (SiPM), the lidar image steering method employs a time-multiplexing method to expand the FOV to 49.5 degrees, while preserving an angular resolution of 0.22 degrees and achieving a frame rate exceeding 142 fps.",

author = "Jeff Chan and Xianyue Deng and Lee, \{Ted Liang Tai\} and Rajesh Shrestha and Yefu Zhang and Varghese, \{Emil Rajan\} and Yuzuru Takashima",

note = "Publisher Copyright: {\textcopyright} 2025 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.",

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doi = "10.1364/OE.545153",

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T1 - Flash and point-and-shoot hybrid lidar by DMD-based solid-state diffractive beam and image steering

AU - Chan, Jeff

AU - Deng, Xianyue

AU - Lee, Ted Liang Tai

AU - Shrestha, Rajesh

AU - Zhang, Yefu

AU - Varghese, Emil Rajan

AU - Takashima, Yuzuru

PY - 2025/5/5

Y1 - 2025/5/5

N2 - Solid-state implementation of lidar is highly anticipated for a wide field of view (FOV), long range, high resolution, and high-framerate lidar, yet is elusive. Traditional solid-state flash lidar using a 2-dimensional detector array suffers from a trade-off among FOV, range, and resolution due to the limited number of pixels. To decouple the trade-off while retaining solid-state implementation, we demonstrate an optical architecture that hybridizes flash and a point-and-shoot lidar, which is enabled by diffractive beam and image steering by digital micromirror device (DMD). With a low pixel count detector, a 32 × 32-pixel silicon photo multiplier (SiPM), the lidar image steering method employs a time-multiplexing method to expand the FOV to 49.5 degrees, while preserving an angular resolution of 0.22 degrees and achieving a frame rate exceeding 142 fps.

AB - Solid-state implementation of lidar is highly anticipated for a wide field of view (FOV), long range, high resolution, and high-framerate lidar, yet is elusive. Traditional solid-state flash lidar using a 2-dimensional detector array suffers from a trade-off among FOV, range, and resolution due to the limited number of pixels. To decouple the trade-off while retaining solid-state implementation, we demonstrate an optical architecture that hybridizes flash and a point-and-shoot lidar, which is enabled by diffractive beam and image steering by digital micromirror device (DMD). With a low pixel count detector, a 32 × 32-pixel silicon photo multiplier (SiPM), the lidar image steering method employs a time-multiplexing method to expand the FOV to 49.5 degrees, while preserving an angular resolution of 0.22 degrees and achieving a frame rate exceeding 142 fps.

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Flash and point-and-shoot hybrid lidar by DMD-based solid-state diffractive beam and image steering

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