Hardware Enabled Acceleration of Near-Field Coded Aperture Radar Physical Model for Millimetre-Wave Computational Imaging

Sharma, Rahul; Yurduseven, Okan; Deka, Bhabesh; Fusco, Vincent

doi:10.2528/pierb20112305

Cited by 14 publications

(11 citation statements)

References 57 publications

(92 reference statements)

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“…All results are provided for signal-tonoise ratio (SNR) of 20dB to ensure a realistic channel response in the presence of additional loss factors. Our previous works in NF imaging [34][35][36] justify this SNR selection. According to the parameters of Configs.…”

Section: Simulation Resultsmentioning

confidence: 91%

Fourier Compatible Near-Field Multiple-Input Multiple-Output Terahertz Imaging With Sparse Non-Uniform Apertures

Molaei¹,

Skouroliakou

et al. 2021

IEEE Access

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Section: Simulation Resultsmentioning

confidence: 91%

Fourier Compatible Near-Field Multiple-Input Multiple-Output Terahertz Imaging With Sparse Non-Uniform Apertures

Molaei¹,

Skouroliakou

et al. 2021

IEEE Access

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“…(1), f signifies the reflectivity distribution of the discretized pixels in the imaged scene, H is the sensing matrix and n is the measurement noise, modelled as a Gaussian distribution with zero mean [33]. In this work, to ensure a realistic model, the back-scattered measurements, g, exhibit a finite SNR of 20 dB [33], [34]. Subscripts M and N denote the number of measurement modes and the number of pixels used to define the scene, respectively.…”

Section: Coded-aperture CI Systemmentioning

confidence: 99%

“…In a typical CI setup, which uses multiple apertures and usually involves imaging a large scene, it has been shown in the past that processing of sensing matrices as large as 90 GB can be required [35]. Such a calculation tend to be intensive computationally, hence an FPGA architecture is employed in the reconstruction process to share the computational load with the CPU, as presented in [34]. This hardware architecture makes use of the FPGA logic blocks to carry out the calculation of the sensing matrix in quasi realtime.…”

Section: Coded-aperture CI Systemmentioning

confidence: 99%

Coded-Aperture Computational Millimeter-Wave Image Classifier Using Convolutional Neural Network

et al. 2021

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A millimeter-wave (mmW) classifier system applied to images synthesized from a codedaperture based computational imaging (CI) radar is presented. A developed physical model of a CI system is used to generate the image dataset for the classification algorithm. A convolutional neural network (CNN) is integrated with the physical model and trained using the dataset comprising of synthesized mmW images obtained directly from the developed CI physical model. A k-fold cross validation technique is applied during the training process to validate the classification model. The coded-aperture CI concept enables image reconstruction from a significantly reduced number of back-scattered measurements by facilitating physical layer compression. This physical layer compression can substantially simplify the data acquisition layer of imaging radars, which is realized using only two channels in this article. The integration of the classification algorithm with the CI numerical model is particularly important in enabling the training step to be carried out using relevant system metrics and without the necessity for experimental data. Leveraging the CI numerical model generated data, training step for the classification algorithm is achieved in real-time while also confirming that the numerically trained CI classifier offers high accuracy with both simulated and experimental data. The classifier integrated physical model also enables performance analysis of the classification algorithm to be carried out as a function of key system metrics such as signal-to-noise (SNR) level, ensuring a complete understanding of the classification accuracy under different operating conditions. The trained CI system is tested with synthesized mmW images from the physical model and a classification accuracy of 89% is achieved. The proposed model is also verified using experimental data validating the fidelity of the developed CI integrated classifier system. A classification latency of 3.8 ms per frame is achieved, paving the way for real-time automated threat detection (ATD) for security-screening applications.INDEX TERMS Millimetre-wave, imaging radars, computational imaging, neural networks, image classification, coded-aperture.

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“…To alleviate the above constraints, computational imaging approaches have been used in the literature [4][5][6][7]. However, such configurations demand the inversion of an ill-posed matrix, which results in a bottleneck in achieving fast image reconstruction time.…”

Section: Introductionmentioning

confidence: 99%

Fourier-based Radar Processing for Multistatic Millimetre-wave Imaging with Sparse Apertures

Skouroliakou

Molaei

Fusco

et al. 2022

2022 16th European Conference on Antennas and Propagation (EuCAP)

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Fourier-based radar processing algorithms have attracted a lot of interest among imaging techniques mostly because they are extremely fast. Moreover, such techniques can be integrated with a Multiple-Input Multiple-Output (MIMO) effective aperture, able to alleviate the hardware constraints, to form a cost-effective imaging system that can retrieve an estimation of the scene in real-time. The proposed technique leverages the phase center approximation and a multistatic-tomonostatic data conversion to render the back-scattered measurements compatible with fast Fourier processing. Whereas the phase center approximation is applicable for imaging in the far-field of the synthesized aperture, in the near-field, a more sophisticated aperture design should be considered to reduce the distortion in the reconstructed images. This paper presents a theoretical study for a sparse aperture design and the optimization of the aperture layout in the context of the phase center approximation validity for near-field imaging facilitated by Fourier-based reconstructions. Furthermore, it proposes a GPU accelerated reconstruction algorithm able to form 3D images in a few milliseconds with low-cost hardware.

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Hardware Enabled Acceleration of Near-Field Coded Aperture Radar Physical Model for Millimetre-Wave Computational Imaging

Cited by 14 publications

References 57 publications

Fourier Compatible Near-Field Multiple-Input Multiple-Output Terahertz Imaging With Sparse Non-Uniform Apertures

Fourier Compatible Near-Field Multiple-Input Multiple-Output Terahertz Imaging With Sparse Non-Uniform Apertures

Coded-Aperture Computational Millimeter-Wave Image Classifier Using Convolutional Neural Network

Fourier-based Radar Processing for Multistatic Millimetre-wave Imaging with Sparse Apertures

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