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摘要:
针对偏振光导航对天空中特征点精确位置信息的需求,提出一种基于全天域偏振模式成像系统对太阳位置进行精确检测的方法。与传统的基于光斑的太阳位置检测方法相比,该方法利用大气中固有的偏振信息完成对太阳位置的精确测量,具有检测方法简单、精度高且适用范围广等特点。搭建的光学采集系统由三个微小型的大视场摄像头模组和偏振片构成,使得结构更加紧凑,体积更小,高度更低。从原理出发,仿真分析太阳位置求解算法,采用搭建的光学采集系统对本算法在3种天气(晴天、遮挡、气溶胶)环境下进行验证。结果显示:当天气晴朗时,在同一天不同时刻,测量的太阳高度角和方位角的精度分别为0.024°和0.03°;当太阳被高层建筑物遮挡时,太阳的高度角和方位角的测量精度分别为0.08°和0.05°;当太阳被树木的枝叶遮挡时,太阳的高度角和方位角的测量精度分别为0.3°和0.1°。研究发现当气溶胶的浓度超过一定量时就会破坏偏振光的Rayleigh分布模式,进而会影响太阳位置的检测精度。实验结果表明,这种新型的检测方法不仅能够满足偏振光导航对太阳位置精确信息的需求,还能为喜欢探索宇宙奥秘的爱好者提供一种新的探索思路。
Abstract:Aiming at the requirement of polarized light navigation for accurate position information of feature points in the sky, an accurate detection method for the solar position of imaging system based on all sky polarization mode is proposed. Compared with the traditional detection method of the solar position based on spot, we use the inherent polarization information in the atmosphere to complete the accurate measurement of the solar position, which has the characteristics of simple, high accuracy and wide application range. The optical acquisition system consists of three micro large-field-of-view camera modules and polarizers, which makes the structure more compact, smaller and lower in height. Starting from the principle, the algorithm of solving the solar position is simulated first, and then the algorithm is verified in three weather environments (sunny, occluded, and aerosol) using the optical acquisition system. It can be seen that when the weather is clear, the sun is detected at different times of the same day, and the accuracy of the measured sun's altitude and azimuth are 0.024° and 0.03° respectively; when the sun is blocked by high-rise buildings, the accuracy of the measured sun's altitude and azimuth are 0.08° and 0.05°; when the sun is blocked by the branches and leaves of trees, the accuracy of the measured sun's altitude and azimuth are 0.3° and 0.1° respectively. Only when the aerosol concentration exceeds a certain amount will the Rayleigh distribution mode of polarized light be destroyed, which will affect the detection accuracy of solar position. The experimental results show that this new detection method can not only meet the needs of polarized light navigation for the solar position, but also provide a new way of exploration for fans who like to explore the mysteries of the universe.
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太阳位置的多次迭代算法 计算太阳的空间位置:$ {\boldsymbol{S}} = \left( {{h_{\rm{s}}},{\alpha _{\rm{s}}}} \right) $ 当$ k = {\text{0}} $时 选取初始值 $ {{\boldsymbol{S}}_{\text{0}}} $ 选择迭代终止条件 $ \varepsilon $>0,且为一个很小的常数 确定最大迭代次数 计算雅可比矩阵: 使用公式(11)计算雅克比矩阵 $ {\boldsymbol{J}}\left( {{{\boldsymbol{S}}_k}} \right) $ 将$ \Delta \left( {{{\boldsymbol{S}}_k}} \right) $代入式(9)中的雅克比矩阵$ {\boldsymbol{J}}\left( {{{\boldsymbol{S}}_k}} \right) $ $ {{\boldsymbol{g}}_k} = {\boldsymbol{J}}\left( {{{\boldsymbol{S}}_k}} \right){\boldsymbol{F}}\left( {{{\boldsymbol{S}}_k}} \right),{{\boldsymbol{S}}_{k + {\text{1}}}} = {{\boldsymbol{S}}_k} + \Delta {{\boldsymbol{S}}_k} $ 如果 $ \left\| {{{\boldsymbol{g}}_k}} \right\| \lt \varepsilon $,或者 $ k \gt n $,迭代停止 输出 $ {{\boldsymbol{S}}_k} $ 结束 通过式(10)计算 $ {{\boldsymbol{S}}_{k + {\text{1}}}} $ 迭代继续 如果 $ \left\| {{{\boldsymbol{g}}_k}} \right\| \geqslant \varepsilon $,或者 $ k \leqslant n $ 令$ k = k + {\text{1}} $ 计算雅克比矩阵 ... 直到 $ \left\| {{{\boldsymbol{g}}_k}} \right\| \lt \varepsilon $,$ k \gt n $,然后计算 $ {{\boldsymbol{S}}_k} $ 结束 计算 $ {h_{\rm{s}}} $,$ {\alpha _{\rm{s}}} $ 表 1实验数据表
Table 1.Experiment data list
时间 太阳的理论位置 基于改进的偏振角
模型计算的太阳位置误差 $\alpha_s $ hs $\alpha_s $ hs $\alpha_s $ hs 8:00 95.333 23.450 95.365 23.472 0.031 0.022 9:00 105.216 35.529 105.189 35.554 −0.028 0.025 10:00 117.819 46.959 117.791 46.939 −0.028 −0.020 11:00 135.892 56.827 135.857 56.800 −0.035 −0.027 12:00 162.984 63.167 163.018 63.143 0.033 −0.024 13:00 196.214 63.255 196.178 63.276 −0.036 0.021 14:00 223.550 57.040 223.519 57.063 −0.032 0.022 15:00 241.809 47.232 241.838 47.212 0.029 −0.020 16:00 254.509 35.826 254.545 35.807 0.036 −0.019 17:00 264.438 23.757 264.469 23.783 0.031 0.026 18:00 273.160 11.486 273.192 11.504 0.032 0.018 -
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