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198 results on '"Choubey, Bhaskar"'

1. Recurrence recovery in heterogeneous Fermi--Pasta--Ulam--Tsingou systems

Author

Li, Zidu, Porter, Mason A., and Choubey, Bhaskar

Subjects
Nonlinear Sciences - Pattern Formation and Solitons, Condensed Matter - Statistical Mechanics, Mathematics - Dynamical Systems, Nonlinear Sciences - Chaotic Dynamics
Abstract

The computational investigation of Fermi, Pasta, Ulam, and Tsingou of arrays of nonlinearly coupled oscillators has led to a wealth of studies in nonlinear dynamics. Most studies of oscillator arrays have considered homogeneous oscillators, even though there are inherent heterogeneities between {individual} oscillators in real-world arrays. Well-known FPUT phenomena, such as energy recurrence, can break down in such heterogeneous systems. In this paper, we present an approach -- the use of structured heterogeneities -- to recover recurrence in FPUT systems in the presence of oscillator heterogeneities. We examine oscillator variabilities in FPUT systems with cubic nonlinearities, and we demonstrate that centrosymmetry in oscillator arrays may be an important source of recurrence., Comment: revised version

Published
2023

3. AM-DCGAN: Analog Memristive Hardware Accelerator for Deep Convolutional Generative Adversarial Networks

Author

Krestinskaya, Olga, Choubey, Bhaskar, and James, Alex Pappachen

Subjects
Computer Science - Emerging Technologies, Computer Science - Neural and Evolutionary Computing, Electrical Engineering and Systems Science - Signal Processing
Abstract

Generative Adversarial Network (GAN) is a well known computationally complex algorithm requiring signficiant computational resources in software implementations including large amount of data to be trained. This makes its implementation in edge devices with conventional microprocessor hardware a slow and difficult task. In this paper, we propose to accelerate the computationally intensive GAN using memristive neural networks in analog domain. We present a fully analog hardware design of Deep Convolutional GAN (DCGAN) based on CMOS-memristive convolutional and deconvolutional networks simulated using 180nm CMOS technology.

Published
2020

4. Synaptic Plasticity in Memristive Artificial Synapses and Their Robustness Against Noisy Inputs

Author

Du, Nan, Zhao, Xianyue, Chen, Ziang, Choubey, Bhaskar, Di Ventra, Massimiliano, Skorupa, Ilona, Bürger, Danilo, and Schmidt, Heidemarie

Subjects
Biomedical and Clinical Sciences, Neurosciences, Bioengineering, Mental health, Neurological, artificial synapse, resistive switching, synaptic plasticity, neuronal noise, spike-timing dependent plasticity, cycle-number dependent plasticity, generalized frequency-dependent plasticity, unconventional neuromorphic computing, Psychology, Cognitive Sciences, Biological psychology
Abstract

Emerging brain-inspired neuromorphic computing paradigms require devices that can emulate the complete functionality of biological synapses upon different neuronal activities in order to process big data flows in an efficient and cognitive manner while being robust against any noisy input. The memristive device has been proposed as a promising candidate for emulating artificial synapses due to their complex multilevel and dynamical plastic behaviors. In this work, we exploit ultrastable analog BiFeO3 (BFO)-based memristive devices for experimentally demonstrating that BFO artificial synapses support various long-term plastic functions, i.e., spike timing-dependent plasticity (STDP), cycle number-dependent plasticity (CNDP), and spiking rate-dependent plasticity (SRDP). The study on the impact of electrical stimuli in terms of pulse width and amplitude on STDP behaviors shows that their learning windows possess a wide range of timescale configurability, which can be a function of applied waveform. Moreover, beyond SRDP, the systematical and comparative study on generalized frequency-dependent plasticity (FDP) is carried out, which reveals for the first time that the ratio modulation between pulse width and pulse interval time within one spike cycle can result in both synaptic potentiation and depression effect within the same firing frequency. The impact of intrinsic neuronal noise on the STDP function of a single BFO artificial synapse can be neglected because thermal noise is two orders of magnitude smaller than the writing voltage and because the cycle-to-cycle variation of the current-voltage characteristics of a single BFO artificial synapses is small. However, extrinsic voltage fluctuations, e.g., in neural networks, cause a noisy input into the artificial synapses of the neural network. Here, the impact of extrinsic neuronal noise on the STDP function of a single BFO artificial synapse is analyzed in order to understand the robustness of plastic behavior in memristive artificial synapses against extrinsic noisy input.

Published
2021

5. Variability in Fermi--Pasta--Ulam--Tsingou Arrays Prevents Recurrences

Author

Nelson, Heather, Porter, Mason A., and Choubey, Bhaskar

Subjects
Nonlinear Sciences - Pattern Formation and Solitons, Condensed Matter - Other Condensed Matter, Condensed Matter - Statistical Mechanics, Mathematics - Dynamical Systems, Nonlinear Sciences - Chaotic Dynamics
Abstract

In 1955, Fermi, Pasta, Ulam, and Tsingou reported recurrence over time of energy between modes in a one-dimensional array of nonlinear oscillators. Subsequently, there have been myriad numerical experiments using homogenous FPUT arrays, which consist of chains of ideal, nonlinearly-coupled oscillators. However, inherent variations --- e.g., due to manufacturing tolerance --- introduce heterogeneity into the parameters of any physical system. We demonstrate that such tolerances degrade the observance of recurrence, often leading to complete loss in moderately sized arrays. We numerically simulate heterogeneous FPUT systems to investigate the effects of tolerances on dynamics. Our results illustrate that tolerances in real nonlinear oscillator arrays may limit the applicability of results from numerical experiments on them to physical systems, unless appropriate heterogeneities are taken into account., Comment: 11 pages in main text + short supplement (2 extra figures and terse accompanying text)

Published
2018
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7. Nanomechanical resonators show higher order nonlinearity at room temperature

Author

Kumar, Madhav, Choubey, Bhaskar, and Bhaskaran, Harish

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Most mechanical resonators are treated as simple linear oscillators. Nonlinearity in the resonance behavior of nanoelectromechanical systems (NEMS) has only lately attracted significant interest. Most recently, cubic-order nonlinearity has been used to explain anomalies in the resonance frequency behaviors in the frequency domain. Particularly, such nonlinearities were explained using cubic nonlinearity in the restoring force (Duffing nonlinearity) or damping (van der Pol nonlinearity). Understanding the limits of linear resonant behavior is particularly important in NEMS, as they are frequently studied for their potential in ultrasensitive sensing and detection, applications that most commonly assume a linear behavior to transduce motion into a detected signal. In this paper, we report that even at low excitation, cubic nonlinearity is insufficient to explain nonlinearity in graphene NEMS. Rather, we observe that higher order, in particular, the fifth order effects need to be considered even for systems at room temperature with modest quality factors. These are particularly important results that could determine the limits of linear detection in such systems and quite possibly present unconventional avenues for ultrasensitive detection paradigms using nonlinear dynamics. Such intriguing possibilities, however, hinge crucially on a superior understanding and exploitation of these inherent nonlinearities as opposed to modeling them as approximated linear or cubic systems., Comment: 10 pages, 6 figures

Published
2017

11. Contributors

Author

Arutinov, D., primary, Böhmer, S., additional, Buxbaum, B., additional, Centen, P., additional, Choubey, Bhaskar, additional, Van Den Broeck, H., additional, Durini, D., additional, Fenigstein, A., additional, Ginhac, D., additional, Gouveia, Luiz, additional, Gove, Robert J., additional, Hoenk, M.E., additional, Jerram, P., additional, Lahav, A., additional, Lange, R., additional, Lesser, M., additional, Li, Day-Uei, additional, De Locht, C., additional, Mughal, Waqas, additional, Nikzad, S., additional, Rae, Bruce R., additional, Rizzolo, S., additional, Henderson, Robert K., additional, Stefanov, K., additional, Strum, A., additional, and Turchetta, R., additional

Published
2020
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14. On wide dynamic range logarithmic CMOS image sensors

Author

Choubey, Bhaskar and Collins, Steve

Subjects
621.367, Electronics, Electrical engineering, Information engineering, Image understanding, Mathematical modeling (engineering), Optoelectronics, Sensors, Robotics, analogue, subthreshold, logarithmic, image sensor, calibration, dark current, fixed pattern noise, contrast threshold
Abstract

Logarithmic sensors are capable of capturing the wide dynamic range of intensities available in nature with minimum number of bits and post-processing required. A simple circuit able to perform logarithmic capture is one utilising a MOS device in weak inversion. However, the output of this pixel is crippled due to fixed pattern noise. Technique proposed to reduce this noise fail to produce high quality images on account of unaccounted high gain variations in the pixel. An electronic calibration technique is proposed which is capable of reducing both multiplicative as well as additive FPN. Contrast properties matching that of human eye are reported from these sensors. With reduced FPN, the pixel performance at low intensities becomes concerning. In these regions, the high leakage current of the CMOS process affects the logarithmic pixel. To reduce this current, two different techniques using a modified circuit and another with modified layout are tested. The layout technique is observed to reduce the leakage current. In addition, this layout can be used to linearise the output of logarithmic pixel in low light regions. The unique linear response at low light and logarithmic pixel at high light is further investigated. A new model based on the device physics is derived to represent this response. The fixed pattern noise profile is also investigated. An intelligent iterative scheme is proposed and verified to extract the photocurrent flowing in the pixel and correct the fixed pattern noise utilising the new model. Future research ideas leading to better designs of logarithmic pixels and post-processing of these signals are proposed at the end of the thesis.

Published
2006

22. An Integrated Fluorescence Optical Fiber Temperature Sensor Front-End Based on a Ring-Gate-Isolated Photodiode

Author

Xiong, Bingjun, Yang, Jian, Wang, Yang, Guan, Jian, Yan, Feng, Zhang, Qian, Choubey, Bhaskar, and Liu, Jingjing

Abstract

Fluorescence optical fiber temperature sensors have found widespread use in harsh environments with electromagnetic interference, high voltages, flammability, and combustibility due to their excellent insulating properties. However, conventional fluorescence detection systems are constructed from discrete photodiodes and other front-end circuit chips, which cause bulky size, inferior detection efficiency, and degraded signal-to-noise performance. To address these issues, an integrated optical front-end circuit for fluorescence detection was proposed. The front-end circuit monolithically integrated a ring-gate-isolated photodiode (RGI-PD) device, a transimpedance amplifier (TIA), and a bandgap reference (BGR) circuit. The RGI-PD enabled the detection of the fluorescence afterglow signals, while the TIA circuit converted the photocurrent generated by the RGI-PD into a measurable photovoltage output. The RGI-PD utilized a P-well guard ring structure to prevent edge breakdown by isolating the avalanche region from the shallow trench. The dummy ring-gate created an inverted pyramid hole profile, focusing the electric field on the planar junction to enhance photodetection, which reduced trapping effects and dark counts. The proposed front-end circuit was fabricated using a standard $0.18~\mu \text{m}$ bipolar CMOS DMOS (BCD) process. The measurement results demonstrated that the avalanche breakdown voltage (BV) of the RGI-PD was 13.05 V. The front-end circuit achieved a responsivity of 17.29 A/W at 500 nm wavelength, under a 13.88 V reverse bias voltage applied on the RGI-PD. Moreover, the front-end’s dark voltage measured 0.908 V, with an optimal temperature coefficient (TC) of 41.01 ppm/°C within the temperature range of −40 °C to 85 °C. The proposed front-end circuit was suitable for fluorescence fiber temperature sensing applications.

Published
2024
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24. ESSM: Extended Synaptic Sampling Machine With Stochastic Echo State Neuro-Memristive Circuits

Author

Nair, Vineeta V., Reghuvaran, Chithra, John, Deepu, Choubey, Bhaskar, and James, Alex

Abstract

Synaptic stochasticity is an important feature of biological neural networks that is not widely explored in analog memristor networks. Synaptic Sampling Machine (SSM) is one of the recent models of the neural network that explores the importance of the synaptic stochasticity. In this paper, we present a memristive Echo State Network (ESN) with Extended-SSM (ESSM). The circuit-level design of the single synaptic sampling cell that can introduce stochasticity to the neural network is presented. The architecture of synaptic sampling cells is proposed that have the ability to adaptively reprogram the arrays and respond to stimuli of various strengths. The effect of stochasticity is achieved by randomly blocking the input with the probability that follows Bernoulli distribution, and can lead to the reduction of the memory capacity requirements. The blocking signals are randomly generated using Circular Shift Registers (CSRs). The network processing is handled in analog domain and the training is performed offline. The performance of the neural network is analyzed with a view to benchmark for hardware performance without compromising the system performance. The neural system was tested on ECG, MNIST, Fashion MNIST and CIFAR10 dataset for classification problem. The advantage of memristive CSR in comparison with conventional CMOS based CSR is presented. The ESSM-ESN performance is evaluated with the effect of device variations like resistance variations, noise and quantization. The advantage of ESSM-ESN is demonstrated in terms of performance and power requirements in comparison with other neural architectures.

Published
2023
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39. Holistic Die-to-Die Interface Design Methodology for 2.5-D Multi-Chip-Module Systems

Author

Chaudhary, Muhammad Waqas, Heinig, Andy, Choubey, Bhaskar, and Publica

Abstract

More than Moore technologies can be supported by system level diversification enabled by chiplet based integrated systems within multi-chip-modules (MCM) and silicon interposer based 2.5D systems. The division of large system-on-chip dies into smaller chiplets with different technology nodes specific to the chiplet application requirement enables the performance enhancement at system level while achieving lower power consumption. However, these chiplets need to communicate between each other. Routing resources in MCM and 2.5D systems are limited due to system size and thickness restrictions. This work presents energy/bit optimization approach for multi-chip systems with possibility of co-optimization with the routing resources defined by the signalling pitch. Holistic design methodologies are shown which can be further extended by the designer to define the application specific constraints. A detailed analysis of energy per bit relationship to the voltage swing requirement for different topologies is presented along with a specific CML signalling oriented design flow for 2.5D chip to chip interfaces as an example of topology specific optimization possibilities within this methodology.

Published
2021

40. An experimental investigation of coupled van der Pol oscillators

Author

Choubey, Bhaskar

Subjects
Oscillators (Electronics) -- Testing, Performance-based assessment -- Methods, Science and technology
Abstract

Experimental investigations of synchronization of linearly diffusive coupled van der Pol electronic oscillators are reported. In addition to in-and antiphase stable oscillations, shifted symmetric and asymmetric trajectories have been observed experimentally. However, the experiments have failed to produce stable chaotic behavior in these systems. Extended numeric simulations are then performed to show that the previously believed chaotic region is a transient numeric effect, thereby validating experimental results. [DOI: 10.1115/1.4000808]

Published
2010

44. Artificial Intelligence Techniques for Driver Fatigue Detection

Author

Yassine, Nabil, Yassine, Nabil, Hayatleh, Khaled, Barker, Steve, Choubey, Bhaskar, Yassine, Nabil, Yassine, Nabil, Hayatleh, Khaled, Barker, Steve, and Choubey, Bhaskar

Abstract

The research discussed here aims to design a deep learning algorithm based on Convolutional Neural Networks models to detect driver distraction and fatigue using driver facial expressions. The proposed model provides high accuracy during both training and validation. The research was inspired to contribute to transport safety by providing alternative solutions to detect driver habit. First, the thesis discussed Conventional methods, including Haar cascade classifiers and eigenfaces. In 2018 I published a proposal for a blink rate detection system using Haar cascade feature detection. However, due to the advantages of Neural Networks, the research focused on providing a unique solution in that field. An in-depth look at how Neural Networks function, specifically Convolutional Neural Networks (CNNs), was investigated and discussed next. Due to the advantages CNN's have with feature detection in images, the algorithm I proposed in this research uses a CNN architecture. Lastly, I proposed an adaptive approach for deep learning to enhance training, validation and testing accuracies. My original algorithm and subsequent models were trained on two datasets. These were the American University in Cairo (AUC) Distracted Driver Dataset and the UTA Real-Life Drowsiness Dataset (UTA-RLDD). Hence the research proposed two original CNN models that produced high training and validation accuracy. The model designed on the AUC Distracted Driver Dataset achieved good 97% training accuracy and good 96% validation accuracy. Evaluation of this model produced good 99% accuracy. The model designed on UTA-RLDD achieved 100% training accuracy, 69% validation accuracy, and evaluated at 69% accuracy.

Published
2020

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