A new generalized optimum strapdown algorithm with coning and sculling compensation is presented, in which the position, velocity and attitude updating operations are carried out based on the single-speed structure in which all computations are executed at a single updating rate that is sufficiently high to accurately account for high frequency angular rate and acceleration rectification effects. Different from existing algorithms, the updating rates of the coning and sculling compensations are unrelated with the number of the gyro incremental angle samples and the number of the accelerometer incremental velocity samples. When the output sampling rate of inertial sensors remains constant, this algorithm allows increasing the updating rate of the coning and sculling compensation, yet with more numbers of gyro incremental angle and accelerometer incremental velocity in order to improve the accuracy of system. Then, in order to implement the new strapdown algorithm in a single FPGA chip, the parallelization of the algorithm is designed and its computational complexity is analyzed. The performance of the proposed parallel strapdown algorithm is tested on the Xilinx ISE 12.3 software platform and the FPGA device XC6VLX550T hardware platform on the basis of some fighter data. It is shown that this parallel strapdown algorithm on the FPGA platform can greatly decrease the execution time of algorithm to meet the real-time and high precision requirements of system on the high dynamic environment, relative to the existing implemented on the DSP platform.
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机译:提出了一种新的具有锥度和双桨补偿的广义最优捷联算法,其中基于单速结构执行位置,速度和姿态更新操作,其中所有计算均以足够高的单个更新速率执行。准确地考虑了高频角速率和加速整流效果。与现有算法不同,圆锥补偿和划桨补偿的更新速率与陀螺仪增量角样本的数量和加速度计增量速度样本的数量无关。当惯性传感器的输出采样率保持恒定时,该算法可以提高锥度和双桨补偿的更新率,同时可以增加更多的陀螺仪增量角和加速度计增量速度,以提高系统的精度。然后,为了在单个FPGA芯片中实现新的捷联算法,设计了算法的并行化并分析了其计算复杂性。根据一些战斗机数据,在Xilinx ISE 12.3软件平台和FPGA器件XC6VLX550T硬件平台上测试了所提出的并行捷联算法的性能。结果表明,相对于在DSP平台上实现的现有算法,在FPGA平台上的这种并行捷联算法可以大大减少算法的执行时间,以满足系统在高动态环境下对实时性和高精度的要求。
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