论文信息 - Finite Wordlength Recursive Sliding-DFT for Phase Measurement

Finite Wordlength Recursive Sliding-DFT for Phase Measurement

This paper proposes a modified recursive sliding DFT to measure the phase of a singletone. The modification is to provide a self error-cancelling mechanism so that it can significantly reduce the numerical error, which is generally introduced and accumulated when a recursive algorithm is implemented in finite wordlength arithmetic. The phase measurement error is analytically derived to suggest optimized distributions of quantization bits. The analytic derivation and the robustness of the algorithm are also verified by computer simulations. It shows that the maximum phase error of less than 5×10 -2 r adian is obtained even when the algorithm is coarsely implemented with 4-bit wordlength twiddle factors.

Min-Kyu Cho | Byoung-Il Kim | Tae-Gyu Chang

[1] Bernard Widrow,et al. On the advantages of the LMS spectrum analyzer over nonadaptive implementations of the sliding-DFT , 1995 .

[2] Dong-Hwan Hwang,et al. Position DOP Analysis for Sensor Placement in the TDOA-based Localization System , 2012 .

[3] Chih-Wen Liu,et al. A precise calculation of power system frequency and phasor , 2000 .

[4] E. Jacobsen,et al. The sliding DFT , 2003, IEEE Signal Process. Mag..

[5] R. Lyons,et al. An update to the sliding DFT , 2004, IEEE Signal Process. Mag..

[6] A. Domijan,et al. Recursive algorithm for real-time measurement of electrical variables in power systems , 2006, IEEE Transactions on Power Delivery.

[7] Byoung-Il Kim,et al. A sliding-DFT based power-line phase measurement algorithm and its FPGA implementation , 2004 .

[8] Tae-Gyu Chang,et al. Analytic derivation of the finite wordlength effect of the twiddle factors in recursive implementation of the sliding-DFT , 2000, IEEE Trans. Signal Process..

[9] Phillip A. Regalia,et al. On the numerical stability and accuracy of the conventional recursive least squares algorithm , 1999, IEEE Trans. Signal Process..

[10] James R. Bunch,et al. Error accumulation effects for the a posteriori RLSL prediction filter , 1995, IEEE Trans. Signal Process..

[11] K.P. Sozanski. Sliding DFT control algorithm for three-phase active power filter , 2006, Twenty-First Annual IEEE Applied Power Electronics Conference and Exposition, 2006. APEC '06..