FPGA Implementation of an Efficient FFT Processor for FMCW Radar Signal Processing

Heo, Jinmoo; Jung, Yongchul; Lee, Seongjoo; Jung, Yunho

doi:10.3390/s21196443

Cited by 20 publications

(15 citation statements)

References 37 publications

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“…Besides, the signal processing for advanced pulse compression comprises of cross-correlation operations between the matched filter and the raw, uncompressed signal, which can be efficiently implemented with FFT operations. FPGA-based signal processing schemes, which have been used to enhance FFT processing rates for radiofrequency systems with frequency-modulated continuous waveforms by up to 7.3 times [28], can also be employed in optical pulse compression to enable more efficient denoising of backscattering traces.…”

Section: Resultsmentioning

confidence: 99%

Adaptable Pulse Compression in ϕ-OTDR With Direct Digital Synthesis of Probe Waveforms and Rigorously Defined Nonlinear Chirping

et al. 2022

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Recent research in Phase-Sensitive Optical Time Doman Reflectometry (ϕ-OTDR) has been focused, among others, on performing spatially resolved measurements with various methods including the use of frequency modulated probes. However, conventional schemes either rely on phase-coded sequences, involve inflexible generation of the probe frequency modulation or mostly employ simple linear frequency modulated (LFM) pulses which suffer from elevated sidelobes introducing degradation in range resolution. In this contribution, we propose and experimentally demonstrate a novel ϕ-OTDR scheme which employs a readily adaptable Direct Digital Synthesis (DDS) of pulses with custom frequency modulation formats and demonstrate advanced optical pulse compression with a nonlinear frequency modulated (NLFM) waveform containing a complex, rigorously defined modulation law optimized for bandwidth-limited synthesis and sidelobe suppression. The proposed method offers high fidelity chirped waveforms, and when employed in resolving a 50-cm event at ∼1.13 km using a 1.2-µs probe pulse, matched filtering with the DDS-generated NLFM waveform results in a significant reduction in range ambiguity owing to autocorrelation sidelobe suppression of ∼20 dB with no averages and windowing functions, for an improvement of ∼16 dB compared to conventional linear chirping. Experimental results also show that the contribution of autocorrelation sidelobes to the power in the compressed backscattering responses around localized events is suppressed by up to ∼18 dB when advanced pulse compression with an optical NLFM pulse is employed.

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Section: Resultsmentioning

confidence: 99%

Adaptable Pulse Compression in ϕ-OTDR With Direct Digital Synthesis of Probe Waveforms and Rigorously Defined Nonlinear Chirping

et al. 2022

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“…A one-dimensional Fisher class [19] is introduced to calculate the signal AIB feature point discriminant degree. The AIB feature points with the high discriminant are selected and re-taken as the new feature vectors.…”

Section: Selected Aibmentioning

confidence: 99%

“…The radial integral bispectrum (RIB) [15], axial integral bispectrum (AIB) [16], circular integral bispectrum (CIB) [17], surrounding-line integrated bispectrum (SIB) [18] and other methods have been proposed. Professor Zhang Xianda proposed the selected bispectrum [19].…”

Section: Introductionmentioning

confidence: 99%

Distribution Characteristics of Ground Echo Amplitude and Recognition of Signal Grazing Angle

Zhang

et al. 2021

Sensors

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With the continuous advancement of electronic technology, terahertz technology has gradually been applied on radar. Since short wavelength causes severe ground clutter, this paper studies the amplitude distribution statistical characteristics of the terahertz radar clutter based on the measured data, and provides technical support for the radar clutter suppression. Clutter distribution is the function of the radar glancing angle. In order to achieve targeted suppression, in this paper, selected axial integral bispectrum (selected AIB) feature is selected as deep belief network (DBN)input to complete the radar glancing angle recognition and the network structure, network training method, robustness are analyzed also. The ground clutter amplitude distribution can follow normal distribution at 0~45° grazing angles. The Weibull distribution and G0 distribution can describe the amplitude probability density function of ground clutter at grazing angles 85° and 65°. The recognition rate of different signal grazing angles can reach 91% on three different terrains. At the same time, the wide applicability of the selected AIB feature is verified. The analysis results of ground clutter amplitude characteristics play an important role in the suppression of radar ground clutter.

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“…Another optimisation direction is to provoke computing efficiency directly. Some scholars have used field programmable gate array (FPGA) devices to enhance the signal processing bandwidth [21] and algorithm execution efficiency of hardware devices [22,23]. However, the high cost and the large equipment limit the possibility of largescale applications.…”

Section: Introductionmentioning

confidence: 99%

A GPU‐based real‐time processing system for frequency division multiple‐input‐multiple‐output radar

Liu,

Bao,

Yue

et al. 2023

IET Radar Sonar & Navi

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Multiple‐Input‐Multiple‐Output (MIMO) radar has the characteristic of multiple antenna channels, bringing on a big data volume for signal processing. Therefore, the trade‐off between detection ability and computational efficiency is always considered. In this article, an optimisation system is proposed to enhance the real‐time performance of frequency division MIMO radar without compromising accuracy. For the scenario of low‐altitude small target detection, a signal processing acceleration method is proposed and a MIMO radar optimisation system based on graphics processing unit (GPU) architecture is built. The signal model of frequency division MIMO radar is first established, improving the classical signal processing flow efficiency from the perspective of reducing fast Fourier transform (FFT) times and windowing operation times. To achieve an advanced acceleration, the parallel architecture of ArrayFire‐library in GPU is then employed. Distinct minimum parallel units are extracted by analysing the principle of digital beamforming (DBF), pulse compression, moving target detection (MTD), and constant false‐alarm rate (CFAR) algorithms. And the corresponding parallel algorithms are designed to constitute a parallel acceleration system of frequency division MIMO. Simulation results indicate that the proposed method significantly improves the efficiency of MIMO system with a maximum acceleration ratio of 65 times, meeting the real‐time processing requirements.

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FPGA Implementation of an Efficient FFT Processor for FMCW Radar Signal Processing

Cited by 20 publications

References 37 publications

Adaptable Pulse Compression in ϕ-OTDR With Direct Digital Synthesis of Probe Waveforms and Rigorously Defined Nonlinear Chirping

Adaptable Pulse Compression in ϕ-OTDR With Direct Digital Synthesis of Probe Waveforms and Rigorously Defined Nonlinear Chirping

Distribution Characteristics of Ground Echo Amplitude and Recognition of Signal Grazing Angle

A GPU‐based real‐time processing system for frequency division multiple‐input‐multiple‐output radar

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