Your search keyword '"local fractional Fourier transform (LFrFT)"' showing total 2 results

1. A Novel High-Frequency Vibration Error Estimation and Compensation Algorithm for THz-SAR Imaging Based on Local FrFT

Author

Yinwei Li, Li Ding, Qibin Zheng, Yiming Zhu, and Jialian Sheng

Subjects

terahertz synthetic aperture radar (THz-SAR) imaging, high-frequency vibration error, local fractional Fourier transform (LFrFT), sinusoidal frequency modulation (SFM), Chemical technology, TP1-1185

Abstract

Compared with microwave synthetic aperture radar (SAR), terahertz SAR (THz-SAR) is easier to achieve ultrahigh-resolution image due to its higher frequency and shorter wavelength. However, higher carrier frequency makes THz-SAR image quality very sensitive to high-frequency vibration error of motion platform. Therefore, this paper proposes a novel high-frequency vibration error estimation and compensation algorithm for THz-SAR imaging based on local fractional Fourier transform (LFrFT). Firstly, the high-frequency vibration error of the motion platform is modeled as a simple harmonic motion and THz-SAR echo signal received in each range pixel can be considered as a sinusoidal frequency modulation (SFM) signal. A novel algorithm for the parameter estimation of the SFM signal based on LFrFT is proposed. The instantaneous chirp rate of the SFM signal is estimated by determining the matched order of LFrFT in a sliding small-time window and the vibration acceleration is obtained. Hence, the vibration frequency can be estimated by the spectrum analysis of estimated vibration acceleration. With the estimated vibration acceleration and vibration frequency, the SFM signal is reconstructed. Then, the corresponding THz-SAR imaging algorithm is proposed to estimate and compensate the phase error caused by the high-frequency vibration error of the motion platform and realize high-frequency vibration error estimation and compensation for THz-SAR imaging. Finally, the effectiveness of the novel algorithm proposed in this paper is demonstrated by simulation results.

Published

2020

2. A Novel High-Frequency Vibration Error Estimation and Compensation Algorithm for THz-SAR Imaging Based on Local FrFT

Author

Li Ding, Yiming Zhu, Qibin Zheng, Jialian Sheng, and Yinwei Li

Subjects

Synthetic aperture radar, Image quality, Computer science, Terahertz radiation, Acoustics, 0211 other engineering and technologies, 02 engineering and technology, Simple harmonic motion, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Signal, Article, Analytical Chemistry, lcsh:TP1-1185, sinusoidal frequency modulation (SFM), Electrical and Electronic Engineering, Instrumentation, high-frequency vibration error, 021101 geological & geomatics engineering, Carrier signal, Estimation theory, 010401 analytical chemistry, Atomic and Molecular Physics, and Optics, Fractional Fourier transform, 0104 chemical sciences, Vibration, Wavelength, terahertz synthetic aperture radar (THz-SAR) imaging, local fractional Fourier transform (LFrFT), Frequency modulation, Microwave

Abstract

Compared with microwave synthetic aperture radar (SAR), terahertz SAR (THz-SAR) is easier to achieve ultrahigh-resolution image due to its higher frequency and shorter wavelength. However, higher carrier frequency makes THz-SAR image quality very sensitive to high-frequency vibration error of motion platform. Therefore, this paper proposes a novel high-frequency vibration error estimation and compensation algorithm for THz-SAR imaging based on local fractional Fourier transform (LFrFT). Firstly, the high-frequency vibration error of the motion platform is modeled as a simple harmonic motion and THz-SAR echo signal received in each range pixel can be considered as a sinusoidal frequency modulation (SFM) signal. A novel algorithm for the parameter estimation of the SFM signal based on LFrFT is proposed. The instantaneous chirp rate of the SFM signal is estimated by determining the matched order of LFrFT in a sliding small-time window and the vibration acceleration is obtained. Hence, the vibration frequency can be estimated by the spectrum analysis of estimated vibration acceleration. With the estimated vibration acceleration and vibration frequency, the SFM signal is reconstructed. Then, the corresponding THz-SAR imaging algorithm is proposed to estimate and compensate the phase error caused by the high-frequency vibration error of the motion platform and realize high-frequency vibration error estimation and compensation for THz-SAR imaging. Finally, the effectiveness of the novel algorithm proposed in this paper is demonstrated by simulation results.

Published

2020