Optical design and fabrication of a multi-channel imaging spectrometer for combustion flame monitoring

Bingqing Xie; Jun Chang; Jing Cai; Weilin Chen; Wenxi Wang; Xuecong Zhang; Yang Zhang; Huilin Jiang

doi:10.1364/OE.516493

Optical design and fabrication of a multi-channel imaging spectrometer for combustion flame monitoring

Bingqing Xie
, Jun Chang^*
, Jing Cai
, Weilin Chen
, Wenxi Wang
, Xuecong Zhang
, Yang Zhang
, Huilin Jiang

^*Corresponding author for this work

School of Optics and Photonics

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

1 Citation (Scopus)

Abstract

We design and construct a broadband integrated multi-channel imaging spectrometer (MCIS) from visible light to near-infrared. This system can directly obtain spectral images that conform to the consistent visual habits of the human eyes through a single exposure of the detector. The genetic algorithm is used to calculate system parameters to minimize pixel waste between spectral channels, achieving nearly 100% utilization of detector pixels. The field stop suppresses stray light in the system. This device is used for imaging an optical-resolution target, an object, and a furnace to verify the basic principles of the system. The results indicate that the system can effectively utilize detectors to monitor high-temperature objects in the visible to near-infrared wavelength range.

Original language	English
Pages (from-to)	14755-14769
Number of pages	15
Journal	Optics Express
Volume	32
Issue number	8
DOIs	https://doi.org/10.1364/OE.516493
Publication status	Published - 8 Apr 2024

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title = "Optical design and fabrication of a multi-channel imaging spectrometer for combustion flame monitoring",

abstract = "We design and construct a broadband integrated multi-channel imaging spectrometer (MCIS) from visible light to near-infrared. This system can directly obtain spectral images that conform to the consistent visual habits of the human eyes through a single exposure of the detector. The genetic algorithm is used to calculate system parameters to minimize pixel waste between spectral channels, achieving nearly 100\% utilization of detector pixels. The field stop suppresses stray light in the system. This device is used for imaging an optical-resolution target, an object, and a furnace to verify the basic principles of the system. The results indicate that the system can effectively utilize detectors to monitor high-temperature objects in the visible to near-infrared wavelength range.",

author = "Bingqing Xie and Jun Chang and Jing Cai and Weilin Chen and Wenxi Wang and Xuecong Zhang and Yang Zhang and Huilin Jiang",

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T1 - Optical design and fabrication of a multi-channel imaging spectrometer for combustion flame monitoring

AU - Xie, Bingqing

AU - Chang, Jun

AU - Cai, Jing

AU - Chen, Weilin

AU - Wang, Wenxi

AU - Zhang, Xuecong

AU - Zhang, Yang

AU - Jiang, Huilin

PY - 2024/4/8

Y1 - 2024/4/8

N2 - We design and construct a broadband integrated multi-channel imaging spectrometer (MCIS) from visible light to near-infrared. This system can directly obtain spectral images that conform to the consistent visual habits of the human eyes through a single exposure of the detector. The genetic algorithm is used to calculate system parameters to minimize pixel waste between spectral channels, achieving nearly 100% utilization of detector pixels. The field stop suppresses stray light in the system. This device is used for imaging an optical-resolution target, an object, and a furnace to verify the basic principles of the system. The results indicate that the system can effectively utilize detectors to monitor high-temperature objects in the visible to near-infrared wavelength range.

AB - We design and construct a broadband integrated multi-channel imaging spectrometer (MCIS) from visible light to near-infrared. This system can directly obtain spectral images that conform to the consistent visual habits of the human eyes through a single exposure of the detector. The genetic algorithm is used to calculate system parameters to minimize pixel waste between spectral channels, achieving nearly 100% utilization of detector pixels. The field stop suppresses stray light in the system. This device is used for imaging an optical-resolution target, an object, and a furnace to verify the basic principles of the system. The results indicate that the system can effectively utilize detectors to monitor high-temperature objects in the visible to near-infrared wavelength range.

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JF - Optics Express

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Optical design and fabrication of a multi-channel imaging spectrometer for combustion flame monitoring

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