空间失稳目标的高精度运动估计方法

High-precision motion estimation for instability space targets

  • 摘要: 运动估计是解决线性测量系统下动态目标成像畸变问题的有效手段,然而空间失稳目标的非合作性和运动复杂性往往使得运动估计精度难以保证。为提高运动估计的准确性,提出了一种特征驱动的空间失稳目标高精度运动估计方法。该方法首先引入球面坐标建立一般空间失稳目标的自约束时空运动模型,将运动估计推演到高维空间进行非线性无约束求解。然后,根据真实解的存在唯一性,制定了两次异帧相似判别法则给出非线性求解的成功判别,提高运动估计的准确性和鲁棒性。最后,实验比较了不同条件下多类非线性求解方法针对本问题的求解效率,设计了一种基于初值精度划分的求解策略,进一步提高运动估计的效率。实验结果显示该方法最多采用15帧均可实现一般情况的高精度(<10−5)运动估计,进而能够对成像畸变进行精准畸变矫正。

     

    Abstract: Motion estimation is an effective way to rectify the distortion of linear array images of moving target in linear measurement system. However, the non-cooperation and motion complexity of instability space targets make it difficult to precisely estimate their motion parameters. In order to improve the estimation accuracy, a feature-driven high-precision motion estimation for instability space targets was presented. Firstly, a self-constrained motion model of instability space targets by means of the spherical coordinate was established, which transformed the motion estimation into an unconstrained nonlinear optimization problem in high dimensional space. Then, according to the existence and uniqueness of global solutions, an effective way was devised to judge the validity of obtained solutions via comparing the similarity of two solutions calculated via two solving processes under different selections of frame number, which evidently improved the effectiveness and robustness of our method. Finally, the solving efficiency among different non-linear solution methods in the view of our problem was numerically analyzed and an efficient solution scheme in terms of the accuracy of initial values was presented to improve the efficiency of our method. Experimental results illustrate that only needing a maximum of 15 frames of linear array images the estimation accuracy of motion parameters all reach (<10−5) and thus achieve the high performance of rectification for distorted linear array images in our research background.

     

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