Yinan Wang , Xue Chen , Shurui Wang , Wanqin Fu , Chuang Sun
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引用次数: 0
Abstract
Infrared stray radiation adversely impacts the imaging performance of optical systems and affects detection accuracy. The suppression of stray radiation is regarded as essential in the design process of optical systems. Currently, most stray radiation analysis methods employ the Monte Carlo ray tracing approach, which is used to simulate the influence of stray radiation sources on the imaging process in a forward manner. However, for cases where the stray radiation source is unknown, such as high-temperature particles, forward simulation makes it challenging to accurately determine the location of the stray radiation source. To address this issue, a rapid tracing method is proposed in this study, which identifies stray radiation sources based on interference information obtained from the detection surface. This method combines the Monte Carlo approach with a genetic algorithm, enabling rapid determination of the location and size of stray radiation sources.
The Monte Carlo ray tracing method is applied to characterize the imaging process within the optical system. A genetic algorithm is employed to localize the particles, with the objective function defined based on specific parameters of the image, including the inner and outer diameters and the offset position. Parameter identification is then performed to determine the size and position of the particles. The identified parameters are validated by comparing the generated images with real images. Then the results show that the maximum radius error is approximately 3%, while the largest offset error is about 3.5%. Based on this automatic identification method, the stray radiation source caused by particles can be quickly and accurately identified, providing valuable support for subsequent stray radiation suppression and optical system design.
期刊介绍:
The Journal covers the entire field of infrared physics and technology: theory, experiment, application, devices and instrumentation. Infrared'' is defined as covering the near, mid and far infrared (terahertz) regions from 0.75um (750nm) to 1mm (300GHz.) Submissions in the 300GHz to 100GHz region may be accepted at the editors discretion if their content is relevant to shorter wavelengths. Submissions must be primarily concerned with and directly relevant to this spectral region.
Its core topics can be summarized as the generation, propagation and detection, of infrared radiation; the associated optics, materials and devices; and its use in all fields of science, industry, engineering and medicine.
Infrared techniques occur in many different fields, notably spectroscopy and interferometry; material characterization and processing; atmospheric physics, astronomy and space research. Scientific aspects include lasers, quantum optics, quantum electronics, image processing and semiconductor physics. Some important applications are medical diagnostics and treatment, industrial inspection and environmental monitoring.
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