Abstract
The closed-form robust Chinese Remainder Theorem (CRT) is a powerful approach to achieve single-frequency estimation from noisy undersampled waveforms. However, the difficulty of CRT-based methods’ extension into the multi-tone case lies in the fact it is complicated to explore the mapping relationship between an individual tone and its corresponding remainders. This work deals with this intractable issue by means of decomposing the desired multi-tone estimator into several single-tone estimators. Firstly, high-accuracy harmonic remainders are calculated by applying all-phase Discrete Fourier Transform (apDFT) and spectrum correction operations on the undersampled waveforms. Secondly, the aforementioned mapping relationship is built up by a novel frequency classifier which fully captures the amplitude and phase features of remainders. Finally, the frequencies are estimated one by one through directly applying the closed-form robust CRT into these remainder groups. Due to all the components (including closed-form CRT, the apDFT, the spectrum corrector and the remainder classifier) only involving slight computation complexity, the proposed scheme is of high efficiency and consumes low hardware cost. Moreover, numeral results also show that the proposed method possesses high accuracy.
Highlights
Frequency measurement is a fundamental problem in signal processing, which is widely encountered in instrumentation, digital communication, radar, etc
To suppress the spectral leakage, we proposed the all-phase discrete Fourier transform (DFT) spectral analysis in [17] and pointed out that all-phase Discrete Fourier Transform (apDFT) spectrum’s sidelobe leakage is much slighter than DFT even when dealing with multi-tone waveforms
We develop a novel estimator combining closed-form Chinese Remainder Theorem (CRT), apDFT and spectrum correction
Summary
Frequency measurement is a fundamental problem in signal processing, which is widely encountered in instrumentation, digital communication, radar, etc. As some applications work in a wider band and higher frequency, e.g., the millimeter-wave band in 5G technologies, these methods become impractical, since the realizable sampling rates of the analog to digital converters (ADCs) are limited by the Nyquist theorem. Investigations on the frequency estimation from undersampled sequences are interesting. The Chinese Remainder Theorem (CRT) is an effective approach to resolve ambiguity related problems including the undersampling frequency estimation [9,10,11,12,13,14].
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