Even Order Explicit Symplectic Geometric Algorithms for Quaternion Kinematical Differential Equation in Guidance Navigation and Control via Diagonal Padè Approximation and Cayley Transform
The Quaternion kinematical differential equation (QKDE) plays a key role in navigation, control and guidance systems. Although explicit symplectic geometric algorithms (ESGA) for this problem are available, there is a lack of a unified way for constructing high order symplectic difference schemes with configurable order parameter. We present even order explicit symplectic geometric algorithms to solve the QKDE with diagonal Pad\`{e} approximation and Cayley transform. The maximum absolute error for solving the QKDE is $\mathcal{O}(\tau^{2\ell})$ where $\tau$ is the time step and $\ell$ is the order parameter. The linear time complexity and constant space complexity of computation as well as the simple algorithmic structure show that our algorithms are appropriate for realtime applications in aeronautics, astronautics, robotics, visual-inertial odemetry and so on. The performance of the proposed algorithms are verified and validated by mathematical analysis and numerical simulation.
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