Research on calculation method for optical scattering characteristics of space target
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摘要: 光学散射特性是空间目标的重要特征,在目标识别和探测系统中起着非常重要的作用。针对空间目标仿真渲染需求,以及传统目标光学散射特性方法仅给出目标光学散射截面(OCS)、散射特性或模拟目标图像等不足,对空间目标光学散射特性计算进行了较全面研究,给出了空间目标光学散射特性计算流程,给出了目标OCS、目标辐照度、天光背景亮度、目标星等、信噪比和探测概率等计算公式,根据太阳辐射特性、相对于站址位置、天地背景球辐射特性等,利用图形处理单元(GPU)和着色语言实现任意时刻目标光学散射特性计算(目标OCS、探测器接收到的目标反射光功率和背景光功率、目标星等、信噪比和探测概率、模拟目标亮度图像等)。通过球体和圆柱体实验验证了目标OCS计算正确性。通过光学散射特性仿真实验,给出了空间目标在不同站址、不同反射特性和不同探测窗口下目标光学散射特性计算结果,结果表明,目标光学散射特性计算结果合理。给出了全套计算公式、计算参数和计算结果,对空间目标光学散射特性计算、目标图像识别等研究提供了参考。Abstract:
Background Optical scattering characteristics are crucial features of space targets and play a vital role in target recognition and detection systems. Traditional methods are limited in simulating optical scattering properties -which only provide optical cross-section (OCS), scattering characteristics, or synthetic target images.Purpose To address the above limitations and meet requirements of rendering spatial target, this paper conducts a comprehensive study on the computational modeling of optical scattering characteristics for space targets.Methods A systematic workflow is proposed, along with formulas for calculating target OCS, target irradiance, sky background luminance, target magnitude, signal-to-noise ratio (SNR), and detection probability. By integrating solar radiation properties, observer-site positioning, and celestial-terrestrial background sphere radiation characteristics, a graphics processing unit (GPU) accelerated framework combined with shading languages is implemented to compute time-dependent optical scattering properties, including target OCS, detector-received target/background optical power, target magnitude, SNR, detection probability, and synthetic brightness imagery.Results Experimental validation using spherical and cylindrical objects confirms the accuracy of the OCS calculations. Simulations under varying observer locations, reflective properties, and detection windows demonstrate the rationality of the computed optical scattering characteristics.Conclusions This study provides a complete set of formulas, parameters, and results, offering significant value for research on space target optical scattering modeling and image-based recognition. -
图 1 空间目标光学散射特性计算流程图
Figure 1. Flowchart for calculating optical scattering characteristics of space targets
图 2 球体OCS理论值与计算值曲线图
Figure 2. Comparison of theoretical and simulated OCS values for a sphere
图 3 圆柱体OCS理论值与计算值
Figure 3. Comparison of theoretical and simulated OCS values for a cylinder
图 6 黑河站目标光学散射特性计算结果
Figure 6. Calculation results of optical scattering characteristics of targets at Heihe station
图 7 佳木斯站和长春站目标光学散射特性计算结果
Figure 7. Calculation results of optical scattering characteristics of targets at Jiamusi station and Changchun station
表 2 轨道参数
Table 2. Parameters of satellite orbit
a/km e $ \omega $/(°) I/(°) $ {\mathit{\Omega}} $/(°) M/(°) 7237.394 0.001555 187.7263 98.7169 85.7864 172.364 
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表 3 探测器参数
Table 3. Parameters of detector
central wavelength/μm spectral width/m QE sampling period/s aperture/m FFOV/(°) PFA 550 20 0.8 0.01 1 0.133 0.01
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表 1 站址信息
Table 1. Parameters of station
station longitude/(°) latitude/(°) altitude/m Heihe 100.14 38.01 1143.0 Changchun 125.26 43.47 1143.0 Jiamusi 130.78 46.50 1143.0
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表 4 目标表面材质BRDF参数
Table 4. BRDF parameters of target surface materials
material $ {K_{\mathrm{d}}} $ $ {K_{\mathrm{s}}} $ $ {A_0} $ $ {A_1} $ B silver film 0.2873 291.8351 4053.5 1.3118 0.7435 white paint 0.2512 2.8358 897.9647 2.7264 2.4693 GaAs 0.0428 23.0067 2122.5 2.1124 4.8569
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表 5 窗口信息
Table 5. Window information
station start time end time overhead time maximum elevation/(°) Heihe 10:38:18 10:45:00 10:41:39 41.2860 Changchun 18:41:55 18:48:57 18:45:26 44.9339 Jiamusi 18:41:56 18:45:52 18:49:48 74.7703
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