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168 results on '"Bhashyam Balaji"'

1. Performance Prediction for Coherent Noise Radars Using the Correlation Coefficient

Author

David Luong, Bhashyam Balaji, and Sreeraman Rajan

Subjects
Noise radar, covariance matrix, correlation coefficient, quantum radar, radar performance prediction, range, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Noise radars, as well as certain types of quantum radar, can be understood in terms of a correlation coefficient which characterizes their detection performance. Although most results in the noise radar literature are stated in terms of the signal-to-noise ratio (SNR), we show that it is possible to carry out performance prediction in terms of the correlation coefficient. To this end, we derive the range dependence of the correlation coefficient under the assumption that all external noise is additive white Gaussian noise. We then combine our result with a previously-derived expression for the receiver operating characteristic (ROC) curve of a coherent noise radar, showing that we can obtain ROC curves for varying ranges. A comparison with corresponding results for a conventional radar employing coherent integration shows that our results are sensible. The aim of our work is to show that the correlation coefficient is a viable adjunct to SNR in understanding noise radar performance.

Published
2022
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2. Target Detection Through Riemannian Geometric Approach With Application to Drone Detection

Author

Hossein Chahrour, Richard M. Dansereau, Sreeraman Rajan, and Bhashyam Balaji

Subjects
Differential geometry, Burg algorithm, Brauer disc theorem, Riemannian mean and distance, Toeplitz Hermitian positive definite covariance matrices, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Radar detection of small drones in presence of noise and clutter is considered from a differential geometry viewpoint. The drone detection problem is challenging due to low radar cross section (RCS) of drones, especially in cluttered environments and when drones fly low and slow in urban areas. This paper proposes two detection techniques, the Riemannian-Brauer matrix (RBM) and the angle-based hybrid-Brauer (ABHB), to improve the probability of drone detection under small sample size and low signal-to-clutter ratio (SCR). These techniques are based on the regularized Burg algorithm (RBA), the Brauer disc (BD) theorem, and the Riemannian mean and distance. Both techniques exploit the RBA to obtain a Toeplitz Hermitian positive definite (THPD) covariance matrix from each snapshot and apply the BD theorem to cluster the clutter-plus-noise THPD covariance matrices. The proposed Riemannian-Brauer matrix technique is based on the Riemannian distance between the Riemannian mean of clutter-plus-noise cluster and potential targets. The proposed angle-based hybrid-Brauer technique uses the Euclidean tangent space and the Riemannian geodesical distances between the Riemannian mean, the Riemannian median and the potential target point. The angle at the potential target on the manifold is computed using the law of cosines on the manifold. The proposed detection techniques show advantage over the fast Fourier transform, the Riemannian distance-based matrix and the Kullback-Leibler (KLB) divergence detectors. The validity of both proposed techniques are demonstrated with real data.

Published
2021
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3. Quantum Two-Mode Squeezing Radar and Noise Radar: Correlation Coefficient and Integration Time

Author

David Luong, Bhashyam Balaji, and Sreeraman Rajan

Subjects
Quantum radar, quantum two-mode squeezing radar, noise radar, correlation, integration time, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Quantum two-mode squeezing (QTMS) radars and noise radars perform matched filtering of the received signal using a reference signal stored within the radar. Their target detection performance depends on the correlation between the received and reference signals, and the improved detection performance of QTMS radars over noise radars is due to the fact that it has an increased correlation. In this paper, we present a novel way of understanding how detection performance depends on the correlation by relating the correlation to the integration time. Concretely, we prove that increasing the correlation by a given factor is equivalent to increasing the integration time by the square of that factor. We apply this result to a recent QTMS radar experiment where the increase in correlation was approximately a factor of 3. This was found to be equivalent to increasing the integration time by a factor of 9, thus confirming the validity of our result and approximation.

Published
2020
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4. An Adaptive Kernels Layer for Deep Neural Networks Based on Spectral Analysis for Image Applications

Author

Tariq Al Shoura, Henry Leung, and Bhashyam Balaji

Subjects
convolutional kernels, deep learning, high-resolution images, spectral analysis, Chemical technology, TP1-1185
Abstract

As the pixel resolution of imaging equipment has grown larger, the images’ sizes and the number of pixels used to represent objects in images have increased accordingly, exposing an issue when dealing with larger images using the traditional deep learning models and methods, as they typically employ mechanisms such as increasing the models’ depth, which, while suitable for applications that have to be spatially invariant, such as image classification, causes issues for applications that relies on the location of the different features within the images such as object localization and change detection. This paper proposes an adaptive convolutional kernels layer (AKL) as an architecture that adjusts dynamically to images’ sizes in order to extract comparable spectral information from images of different sizes, improving the features’ spatial resolution without sacrificing the local receptive field (LRF) for various image applications, specifically those that are sensitive to objects and features locations, using the definition of Fourier transform and the relation between spectral analysis and convolution kernels. The proposed method is then tested using a Monte Carlo simulation to evaluate its performance in spectral information coverage across images of various sizes, validating its ability to maintain coverage of a ratio of the spectral domain with a variation of around 20% of the desired coverage ratio. Finally, the AKL is validated for various image applications compared to other architectures such as Inception and VGG, demonstrating its capability to match Inception v4 in image classification applications, and outperforms it as images grow larger, up to a 30% increase in accuracy in object localization for the same number of parameters.

Published
2023
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5. Convolutional Neural Networks for Classification of Drones Using Radars

Author

Divy Raval, Emily Hunter, Sinclair Hudson, Anthony Damini, and Bhashyam Balaji

Subjects
drone classification, CNN, machine learning, HERM lines, micro-Doppler, radars, Motor vehicles. Aeronautics. Astronautics, TL1-4050
Abstract

The ability to classify drones using radar signals is a problem of great interest. In this paper, we apply convolutional neural networks (CNNs) to the Short-Time Fourier Transform (STFT) spectrograms of the simulated radar signals reflected from the drones. The drones vary in many ways that impact the STFT spectrograms, including blade length and blade rotation rates. Some of these physical parameters are captured in the Martin and Mulgrew model which was used to produce the datasets. We examine the data under X-band and W-band radar simulation scenarios and show that a CNN approach leads to an F1 score of 0.816±0.011 when trained on data with a signal-to-noise ratio (SNR) of 10 dB. The neural network which was trained on data from an X-band radar with 2 kHz pulse repetition frequency was shown to perform better than the CNN trained on the aforementioned W-band radar. It remained robust to the drone blade pitch and its performance varied directly in a linear fashion with the SNR.

Published
2021
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6. An Investigation of Rotary Drone HERM Line Spectrum under Manoeuvering Conditions

Author

Peter Klaer, Andi Huang, Pascale Sévigny, Sreeraman Rajan, Shashank Pant, Prakash Patnaik, and Bhashyam Balaji

Subjects
micro-Doppler, UAV, drone, radar, HERM lines, spool lines, Chemical technology, TP1-1185
Abstract

Detecting and identifying drones is of great interest due to the proliferation of highly manoeuverable drones with on-board sensors of increasing sensing capabilities. In this paper, we investigate the use of radars for tackling this problem. In particular, we focus on the problem of detecting rotary drones and distinguishing between single-propeller and multi-propeller drones using a micro-Doppler analysis. Two different radars were used, an ultra wideband (UWB) continuous wave (CW) C-band radar and an automotive frequency modulated continuous wave (FMCW) W-band radar, to collect micro-Doppler signatures of the drones. By taking a closer look at HElicopter Rotor Modulation (HERM) lines, the spool and chopping lines are identified for the first time in the context of drones to determine the number of propeller blades. Furthermore, a new multi-frequency analysis method using HERM lines is developed, which allows the detection of propeller rotation rates (spool and chopping frequencies) of single and multi-propeller drones. Therefore, the presented method is a promising technique to aid in the classification of drones.

Published
2020
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7. Continuous-Discrete Path Integral Filtering

Author

Bhashyam Balaji

Subjects
Fokker-Planck equation, Kolmogorov equation, universal nonlinear filtering, Feynman path integrals, path integral filtering, data assimilation, tracking, continuousdiscrete filters, nonlinear filtering, Dirac-Feynman approximation, Science, Astrophysics, QB460-466, Physics, QC1-999
Abstract

A summary of the relationship between the Langevin equation, Fokker-Planck-Kolmogorov forward equation (FPKfe) and the Feynman path integral descriptions of stochastic processes relevant for the solution of the continuous-discrete filtering problem is provided in this paper. The practical utility of the path integral formula is demonstrated via some nontrivial examples. Specifically, it is shown that the simplest approximation of the path integral formula for the fundamental solution of the FPKfe can be applied to solve nonlinear continuous-discrete filtering problems quite accurately. The Dirac-Feynman path integral filtering algorithm is quite simple, and is suitable for real-time implementation.

Published
2009
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8. Euclidean Quantum Mechanics and Universal Nonlinear Filtering

Author

Bhashyam Balaji

Subjects
Bayesian filtering and estimation, Fokker-Planck Equation, Kolmogorov Equation, stochastic differential equations, Duncan-Mortensen-Zakai (DMZ) Equation, nonlinear filtering, Feynman path integral, Science, Astrophysics, QB460-466, Physics, QC1-999
Abstract

An important problem in applied science is the continuous nonlinear filtering problem, i.e., the estimation of a Langevin state that is observed indirectly. In this paper, it is shown that Euclidean quantum mechanics is closely related to the continuous nonlinear filtering problem. The key is the configuration space Feynman path integral representation of the fundamental solution of a Fokker-Planck type of equation termed the Yau Equation of continuous-continuous filtering. A corollary is the equivalence between nonlinear filtering problem and a time-varying Schr¨odinger equation.

Published
2009
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9. Track-before-Detect Using Swerling 0, 1, and 3 Target Models for Small Manoeuvring Maritime Targets

Author

Bhashyam Balaji and Michael McDonald

Subjects
Telecommunication, TK5101-6720, Electronics, TK7800-8360
Abstract

Real-radar data containing a small manoeuvring boat in sea clutter is processed using a finite difference (FD) implementation of continuous-discrete filtering with a four-dimensional constant velocity model. Measurement data is modelled assuming a Rayleigh sea clutter model with embedded Swerling 0, 1, or 3 target signal models. The results are examined to obtain a qualitative understanding of the effects of using the different target models. The Swerling 0 model is observed to exhibit a heightened sensitivity to changes in measured signal strength and provides enhanced detection of the maritime target examined at the cost of more peaked or multimodal posterior density in comparison with Swerling 1 and 3 targets.

Published
2008
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45. Target Detection Through Riemannian Geometric Approach With Application to Drone Detection

Author

Bhashyam Balaji, Sreeraman Rajan, Richard M. Dansereau, and Hossein Chahrour

Subjects
Burg algorithm, General Computer Science, Covariance matrix, Toeplitz Hermitian positive definite covariance matrices, General Engineering, Covariance, Brauer disc theorem, Toeplitz matrix, Manifold, TK1-9971, Matrix (mathematics), Riemannian mean and distance, Differential geometry, Tangent space, General Materials Science, Mathematics::Differential Geometry, Electrical engineering. Electronics. Nuclear engineering, Divergence (statistics), Algorithm, Mathematics
Abstract

Radar detection of small drones in presence of noise and clutter is considered from a differential geometry viewpoint. The drone detection problem is challenging due to low radar cross section (RCS) of drones, especially in cluttered environments and when drones fly low and slow in urban areas. This paper proposes two detection techniques, the Riemannian-Brauer matrix (RBM) and the angle-based hybrid-Brauer (ABHB), to improve the probability of drone detection under small sample size and low signal-to-clutter ratio (SCR). These techniques are based on the regularized Burg algorithm (RBA), the Brauer disc (BD) theorem, and the Riemannian mean and distance. Both techniques exploit the RBA to obtain a Toeplitz Hermitian positive definite (THPD) covariance matrix from each snapshot and apply the BD theorem to cluster the clutter-plus-noise THPD covariance matrices. The proposed Riemannian-Brauer matrix technique is based on the Riemannian distance between the Riemannian mean of clutter-plus-noise cluster and potential targets. The proposed angle-based hybrid-Brauer technique uses the Euclidean tangent space and the Riemannian geodesical distances between the Riemannian mean, the Riemannian median and the potential target point. The angle at the potential target on the manifold is computed using the law of cosines on the manifold. The proposed detection techniques show advantage over the fast Fourier transform, the Riemannian distance-based matrix and the Kullback-Leibler (KLB) divergence detectors. The validity of both proposed techniques are demonstrated with real data.

Published
2021

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