Comparative analysis of different empirical mode decomposition-kind algorithms on sea-level inversion by GNSS-MR

IF 1.2 Q4 REMOTE SENSING
Linghuo Jian, Xinpeng Wang, Shengxiang Huang, Haining Hao, Xianyun Zhang, Xiyuan Yang
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引用次数: 0

Abstract

Abstract The rising sea level caused by global climate change might impact the human living environment. Global navigation satellite systems (GNSS)-multipath reflection (MR) technology holds significant potential for monitoring tide level changes. GNSS-MR technology typically employs low-order polynomials to extract the signal-to-noise ratio (SNR) residuals containing GNSS interference signals. It utilizes Lomb-Scargle (LSP) spectral analysis or empirical mode decomposition (EMD) to obtain the dominant frequency of the SNR residuals, which is then converted into tidal heights. However, as the satellite elevation angle increases, the GNSS interference signals decrease and the traditional method does not adapt well to the extraction of SNR residuals under such conditions. A series of improved EMD-kind algorithms, namely ensemble empirical mode decomposition (EEMD), complementary ensemble empirical mode decomposition (CEEMD), complete ensemble empirical mode decomposition with adaptive noise (CEEMDAN), and improved complete ensemble empirical mode decomposition with adaptive noise (ICEEDMAN), have been proposed to address the shortcomings of EMD algorithms such as end effect and mode aliasing. However, these improved EMD-kind algorithms have yet to be reported in sea level inversion. This study investigates the mitigation effects of EMD-kind algorithms on GNSS-MR direct signal and noise to improve the stability and accuracy of an SNR residual sequence with high satellite elevation angles. Experimental data from the HKQT station for one week and the SC02 station for one year are utilized to validate the effectiveness and accuracy of these algorithms in extracting SNR residuals. Compared to the traditional polynomial method, the experimental results demonstrate that all EMD-kind algorithms effectively address the distortion issue in traditional inversion methods under long periods, higher satellite elevation angles, and low GNSS receiver sampling rates. Among these algorithms, the results from the experiments show that ICEEMDAN consistently provides the best inversion accuracy. The results of the comparative analysis show that ICEEMDAN effectively reduces non-interference signals in SNR residuals at higher satellite elevation angles, expanding the useable range of satellite elevation angles and improving the utilization and temporal resolution of GNSS data inversion. Hence, it is an effective and appropriate approach to improving the accuracy of GNSS-MR tide level monitoring.
GNSS-MR海平面反演不同经验模式分解算法的比较分析
摘要全球气候变化导致的海平面上升可能会影响人类的生存环境。全球导航卫星系统(GNSS)-多路径反射(MR)技术在监测潮汐水位变化方面具有巨大潜力。GNSS-MR技术通常采用低阶多项式来提取包含GNSS干扰信号的信噪比(SNR)残差。它利用Lom-Scargle(LSP)频谱分析或经验模式分解(EMD)来获得SNR残差的主频,然后将其转换为潮高。然而,随着卫星仰角的增加,GNSS干扰信号减少,传统方法不能很好地适应这种条件下SNR残差的提取。一系列改进的EMD类算法,即系综经验模式分解(EEMD)、互补系综经验模态分解(CEEMD)、带自适应噪声的完全系综经验模分解(CEEDAN)和带自适应噪声改进的完全系统经验模分解,已经被提出来解决EMD算法的缺点,例如末端效应和模式混叠。然而,这些改进的EMD算法在海平面反演中还没有报道。本研究研究了EMD类算法对GNSS-MR直接信号和噪声的抑制作用,以提高高卫星仰角SNR残差序列的稳定性和准确性。利用HKQT站一周和SC02站一年的实验数据验证了这些算法在提取SNR残差方面的有效性和准确性。实验结果表明,与传统的多项式方法相比,所有EMD算法都能有效地解决传统反演方法在长周期、高卫星仰角和低GNSS接收机采样率下的失真问题。在这些算法中,实验结果表明ICEEMDAN始终提供最佳的反演精度。对比分析结果表明,ICEEMDAN在较高的卫星仰角下有效地减少了信噪比残差中的不干扰信号,扩大了卫星仰角的可用范围,提高了GNSS数据反演的利用率和时间分辨率。因此,这是提高GNSS-MR水位监测精度的一种有效而合适的方法。
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来源期刊
Journal of Applied Geodesy
Journal of Applied Geodesy REMOTE SENSING-
CiteScore
2.30
自引率
7.10%
发文量
30
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