Initial State Estimation for Boost Phase Object Based on Linear Least Square Estimation

Zhao  Yan; Cheng  Hong-Wei; Yi  Dong-Yun; Zhang Qian

doi:10.3724/SP.J.1146.2010.00129

Volume 32 Issue 12

Jan. 2011

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Zhao Yan, Cheng Hong-Wei, Yi Dong-Yun, Zhang Qian. Initial State Estimation for Boost Phase Object Based on Linear Least Square Estimation[J]. Journal of Electronics & Information Technology, 2010, 32(12): 2884-2889. doi: 10.3724/SP.J.1146.2010.00129

Citation:

Zhao Yan, Cheng Hong-Wei, Yi Dong-Yun, Zhang Qian. Initial State Estimation for Boost Phase Object Based on Linear Least Square Estimation[J]. Journal of Electronics & Information Technology, 2010, 32(12): 2884-2889. doi: 10.3724/SP.J.1146.2010.00129

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Initial State Estimation for Boost Phase Object Based on Linear Least Square Estimation

doi: 10.3724/SP.J.1146.2010.00129 cstr: 32379.14.SP.J.1146.2010.00129

Received Date: 2010-02-02
Rev Recd Date: 2010-06-09
Publish Date: 2010-12-19

Abstract

Abstract

The initial state estimation for boost phase object is an important issue to estimate the missiles tactical parameters, as well as the precondition for the surveillance system to perform the real-time tracking. In the condition of the space-based observations, the initial state estimation is the solution of the nonlinear LSE problem. Firstly, the 8-state gravity turn model for the boost phase object is established, and then the targets kinematic parameters are approximated by using the linear constant acceleration derivative model, and the nonlinear measurements are pseudo linearized. Therefore, the nonlinear LSE problem is translated into the linear LSE problem after the aforementioned steps . Specially, in this paper, the explicit derivation of the pseudo linearized space-based observation and its statistical moments are deduced, and its application conditions are illuminated. Finally, the advantage of the proposed method is illustrated in the aspects of precision and efficiency by comparing with the CRLB and classical Gauss-Newton iteration algorithm.
- Object tracking,
- Initial state estimation,
- Least Square Estimation (LSE),
- Gravity turn model,
- Space-based observation,
- Pseudo linearized observation

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References

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