Low-Level Sinusoidal Signal Detection From a High-Resolution Virtual Spectral Image Using Autoregressive Vector Extrapolation

Marino, C.S.; Chau, P.M.

doi:10.1109/tim.2012.2190549

Cited by 7 publications

(9 citation statements)

References 17 publications

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“…It can be zero-filled (as was done in [15]) or extrapolated using a 1-D linear prediction technique as was done in [21] and [22]. A vector extrapolation technique [24] was applied by the authors to enhance spectral estimation in [17] and [18], which overcomes this limitation. The vector extrapolation technique uses the existing measurement data to predict a vector of measurements at a time.…”

Section: A Virtual Measurement Data Creationmentioning

confidence: 99%

“…The virtual measurement data is partitioned in the original measurement data and the extrapolated measurement data. Because the extrapolation is trying to predict the signals, it has been shown in [17] and [18] that the extrapolated measurement data is just the truth plus some error terms, which is presented…”

Section: Signal-to-noise Derivationmentioning

confidence: 99%

“…First, we improve upon the current DOA estimation by demonstrating a high-resolution capability of a constrained sensor system, where the measurements are limited. The environment differs from [18] and [19] because the data is narrowband and there are three closely spaced sources instead of two. We cover three different environmental cases a high-SNR case, and two low-SNR cases.…”

mentioning

confidence: 99%

“…By close, we mean that the sources are within one beamwidth of the array and unresolvable by a CBF and high-resolution algorithms. Second, is that we apply different algorithms than those of [18] and [19] to address a different problem space, narrow-band DOA estimation. Here, we use the CBF instead of a 2-D fast Fourier transform.…”

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confidence: 99%

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Constrained Sensor System Resolves Closely Spaced Obscured Low-SNR Sources Using Virtual Beamforming

Marino

Chau

2014

IEEE Trans. Instrum. Meas.

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We present a high-resolution capability for systems constrained in the number of elements (measurements) due to size, weight, and power that operate in harsh signal-to-noise ratio (SNR) environments through virtual beamforming. The high resolution is created by applying a conventional beamformer to a virtual measurement data set. The virtual measurement data is made up of original measurements extended with vector extrapolated measurements. We derive the SNR of this new virtual system and show that, in the case of perfect extrapolation, we are within a constant of the true SNR (if we had that many sensor measurements). Simulations show the super-resolution capability of resolving the two closely spaced, equal-powered low-SNR sources, in the presence of a third closely spaced dominant source (15 dB larger signal power) with a limited number of measurements. In a second case, the virtual beamforming technique again resolves two low-SNR sources that are even closer while high-resolution techniques fall short due to the harsh environments. In both cases, the algorithm is shown to be robust in noise through Monte Carlo simulations. We provide the computational cost to achieve this high-resolution capability.Index Terms-2-D autoregressive modeling, high-resolution direction of arrival, low-level signal detection, vector measurement extrapolation, virtual beamforming.

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Section: A Virtual Measurement Data Creationmentioning

confidence: 99%

Section: Signal-to-noise Derivationmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Constrained Sensor System Resolves Closely Spaced Obscured Low-SNR Sources Using Virtual Beamforming

Marino

Chau

2014

IEEE Trans. Instrum. Meas.

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“…However, there are more and more constraints in extending the aperture of an array, so the array extrapolation technique is a considerable option, especially for a small-scale array [18,19]. One typical extrapolation method is the vector extrapolation based on two dimensional autoregressive model (2D-ARVE) [20,21]. However, this method utilizes a linear model and makes use of multiple snapshots to create virtual measurement data, so the real-time performance is affected.…”

Section: Introductionmentioning

confidence: 99%

High-resolution digital beamforming of UWB signals based on Caratheodory representation for delay compensation and array extrapolation

2018

Journal of Systems Engineering and Electronics

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To realize high-resolution digital beamforming (DBF) of ultra-wideband (UWB) signals, we propose a DBF method based on Carathéodory representation for delay compensation and array extrapolation. Delay compensation by Carathéodory representation could achieve high interpolation accuracy while using the single channel sampling technique. Array extrapolation by Carathéodory representation reformulates and extends each snapshot, consequently extends the aperture of the original uniform linear array (ULA) by several times and provides a better realtime performance than the existing aperture extrapolation utilizing vector extrapolation based on the two dimensional autoregressive (2-D AR) model. The UWB linear frequency modulated (LFM) signal is used for simulation analysis. Simulation results demonstrate that the proposed method is featured by a much higher spatial resolution than traditional DBF methods and lower sidelobes than using Lagrange fractional filters.

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Digital beamforming for ultra‐wideband signals utilizing an extrapolated array generated by Carathéodory representation combining fractional delay filters based on high‐order Hermite interpolation

Song

et al. 2018

IEEJ Transactions Elec Engng

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Digital beamforming (DBF) for ultra‐wideband (UWB) signals plays a key role in many applications, and high spatial resolution and accurate digital delay of UWB signals are the focus of UWB DBF research. In this paper, we propose a novel DBF method utilizing an extrapolated array generated by Carathéodory representation combining fractional delay filters (FDFs) based on high‐order Hermite interpolation. The Carathéodory representation could extrapolate the aperture of the original uniform linear array (ULA) significantly and provide a better real‐time performance than the existing extrapolation technique based on the two‐dimensional autoregressive (2‐D AR) model. The FDFs based on high‐order Hermite interpolation not only improve the DBF performance when the frequency of the signals is close to the Nyquist rate but also reduce the sampling rate to half the Nyquist rate. The UWB linear frequency‐modulated (LFM) signal is used for simulation analysis. In contrast with traditional DBF methods and FDFs based on Lagrange interpolation, the proposed method has a much higher spatial resolution, has no false peak, and requires fewer sensors, as demonstrated by simulation results. © 2018 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.

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Low-Level Sinusoidal Signal Detection From a High-Resolution Virtual Spectral Image Using Autoregressive Vector Extrapolation

Cited by 7 publications

References 17 publications

Constrained Sensor System Resolves Closely Spaced Obscured Low-SNR Sources Using Virtual Beamforming

Constrained Sensor System Resolves Closely Spaced Obscured Low-SNR Sources Using Virtual Beamforming

High-resolution digital beamforming of UWB signals based on Caratheodory representation for delay compensation and array extrapolation

Digital beamforming for ultra‐wideband signals utilizing an extrapolated array generated by Carathéodory representation combining fractional delay filters based on high‐order Hermite interpolation

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