Review of design and signal processing of polarimetric imaging cameras

IF 1.3 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
G. Bieszczad, S. Gogler, J. Świderski
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引用次数: 5

Abstract

Article history: Received 23 Nov. 2020 Received in revised form 2 Jan. 2021 Accepted 7 Jan. 2021 Thermal-imaging systems respond to infrared radiation that is naturally emitted by objects. Various multispectral and hyperspectral devices are available for measuring radiation in discrete sub-bands and thus enable a detection of differences in a spectral emissivity or transmission. For example, such devices can be used to detect hazardous gases. However, their operation principle is based on the fact that radiation is considered a scalar property. Consequently, all the radiation vector properties, such as polarization, are neglected. Analysing radiation in terms of the polarization state and the spatial distribution of thereof across a scene can provide additional information regarding the imaged objects. Various methods can be used to extract polarimetric information from an observed scene. We briefly review architectures of polarimetric imagers used in different wavebands. First, the state-of-the-art polarimeters are presented, and, then, a classification of polarimetricmeasurement devices is described in detail. Additionally, the data processing in Stokes polarimeters is given. Emphasis is laid on the methods for obtaining the Stokes parameters. Some predictions in terms of LWIR polarimeters are presented in the conclusion.
偏振成像相机的设计与信号处理综述
文章历史:接收2020年11月23日接收2021年1月2日接收2021年1月7日热成像系统响应物体自然发射的红外辐射。各种多光谱和高光谱设备可用于测量离散子带中的辐射,从而能够检测光谱发射率或透射率的差异。例如,这种装置可用于检测有害气体。然而,它们的工作原理是基于这样一个事实,即辐射被认为是一种标量性质。因此,所有的辐射矢量性质,如偏振,被忽略。根据极化状态及其在场景中的空间分布分析辐射可以提供关于成像对象的附加信息。可以使用各种方法从观测场景中提取偏振信息。我们简要地回顾了在不同波段使用的偏振成像仪的结构。首先,介绍了最先进的偏振光测量仪,然后详细描述了偏振光测量设备的分类。此外,还给出了斯托克斯偏振仪的数据处理方法。重点介绍了获得Stokes参数的方法。在结论部分,对LWIR偏振计进行了一些预测。
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来源期刊
Opto-Electronics Review
Opto-Electronics Review 工程技术-工程:电子与电气
CiteScore
1.90
自引率
12.50%
发文量
0
审稿时长
>12 weeks
期刊介绍: Opto-Electronics Review is peer-reviewed and quarterly published by the Polish Academy of Sciences (PAN) and the Association of Polish Electrical Engineers (SEP) in electronic version. It covers the whole field of theory, experimental techniques, and instrumentation and brings together, within one journal, contributions from a wide range of disciplines. The scope of the published papers includes any aspect of scientific, technological, technical and industrial works concerning generation, transmission, transformation, detection and application of light and other forms of radiative energy whose quantum unit is photon. Papers covering novel topics extending the frontiers in optoelectronics or photonics are very encouraged. It has been established for the publication of high quality original papers from the following fields: Optical Design and Applications, Image Processing Metamaterials, Optoelectronic Materials, Micro-Opto-Electro-Mechanical Systems, Infrared Physics and Technology, Modelling of Optoelectronic Devices, Semiconductor Lasers Technology and Fabrication of Optoelectronic Devices, Photonic Crystals, Laser Physics, Technology and Applications, Optical Sensors and Applications, Photovoltaics, Biomedical Optics and Photonics
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