logo

SCIENCE CHINA Information Sciences, Volume 60 , Issue 8 : 082301(2017) https://doi.org/10.1007/s11432-016-0097-4

A high-precision phase-derived range and velocity measurement method based on synthetic wideband pulse Doppler radar

More info
  • ReceivedJun 30, 2016
  • AcceptedAug 3, 2016
  • PublishedDec 8, 2016

Abstract


Funded by

111 Project of China(B14010)

National Natural Science Foundation of China(61301189)


Acknowledgment

Acknowledgments

This work was supported by 111 Project of China (Grant No. B14010) and National Natural Science Foundation of China (Grant No. 61301189).


References

[1] Liu H B, Lu J D. Target motion compensation algorithm based on Keystone transform for wideband pulse Doppler radar. Trans Beijing Inst Tech, 2012, 32: 625-630 Google Scholar

[2] Long T, Ren L X. HPRF pulse Doppler stepped frequency radar. Sci China Ser F-Inf Sci, 2009, 52: 883-893 Google Scholar

[3] Bao Y X. Signal processing algorithms in stepped frequency wideband radar. Dissertation for PH.D. Degree. Beijing: Beijing Institute of Technology, 2010. 40--106. Google Scholar

[4] Gao W B, Ding Z G, Zhu D L, et al. Improved spectrum reconstruction technique based on chirp rate modulation in stepped-frequency SAR. Sci China Inf Sci, 2015, 58: 102308-893 Google Scholar

[5] Jin K, Wang W D, Wang D J. The study on a new radar waveform (PCSF) with high range resolution. J Univ Sci Tech China, 2006, 36: 137-142 Google Scholar

[6] Steudel F. An Improved Process for Phase-Derived-Range Measurements. World Intellectual Property Organization Patent, 1651978, 2005-2-24. Google Scholar

[7] Steudel F. Process for Phase-Derived-Range Measurements. U.S. Patent, 7046190, 2005-2-10. Google Scholar

[8] Skolnik M I. Introduction to Radar Systems. 3rd ed. Beijing: Publishing House of Electronics Industry, 2007. 313--402. Google Scholar

[9] Liu Y, Hou Q K, Xu S Y, et al. System distortion analysis and compensation of DIFS signals for wideband imaging radar. Sci China Inf Sci, 2015, 58: 020304-142 Google Scholar

[10] Wang H F, Ren L X. Velocity estimation of moving targets with stepped-frequency radar based on Doppler frequency difference. J Beijing Inst Tech, 2014, 23: 78-82 Google Scholar

[11] Li L. Theory and implementation of stepped-frequency radar signal processing. Dissertation for PH.D. Degree. Beijing: Beijing Institute of Technology, 2010. 55--68. Google Scholar

[12] Tian J, Cui W, Shen Q, et al. High-speed maneuvering target detection approach based on joint RFT and keystone transform. Sci China Inf Sci, 2013, 56: 062309-82 Google Scholar

[13] Gao M G, Zhou D Y, Mao E K. A method of digital moving target track based on waveform analysis. Chinese J Electron, 1998, 26: 112-114 Google Scholar

[14] Liu Y X, Zhu D K, Li X, et al. Micromotion characteristic acquisition based on wideband radar phase. IEEE Trans Geosci Remote Sens, 2014, 52: 3650-3657 CrossRef Google Scholar

[15] Bao Y X, Ren L X, He P K, et al. Velocity measurement and compensation method based on range profile cross-correlation in stepped-frequency radar. Syst Eng Electron, 2008, 30: 2112-2115 Google Scholar

[16] Li L, Ren L X, Mao E K, et al. Accurate velocity measurement of range profile cross correlation in stepped-frequency signal. Trans Beijing Inst Tech, 2011, 31: 708-712 Google Scholar

[17] Wang G Y, Bao Z. The minimum entropy criterion of range alignment in ISAR motion compensation. In: Proceedings of Conference Radar, Edinburgh, 1997. 14--16. Google Scholar

qqqq

Contact and support