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Your search keyword '"Hasan, Md Sakib"' showing total 28 results
Start Over Author "Hasan, Md Sakib" Publication Type Electronic Resources
28 results on '"Hasan, Md Sakib"'

1. Intrinsic Voltage Offsets in Memcapacitive Bio-Membranes Enable High-Performance Physical Reservoir Computing

Author

Mohamed, Ahmed S., Dhungel, Anurag, Hasan, Md Sakib, Najem, Joseph S., Mohamed, Ahmed S., Dhungel, Anurag, Hasan, Md Sakib, and Najem, Joseph S.

Abstract

Reservoir computing is a brain-inspired machine learning framework for processing temporal data by mapping inputs into high-dimensional spaces. Physical reservoir computers (PRCs) leverage native fading memory and nonlinearity in physical substrates, including atomic switches, photonics, volatile memristors, and, recently, memcapacitors, to achieve efficient high-dimensional mapping. Traditional PRCs often consist of homogeneous device arrays, which rely on input encoding methods and large stochastic device-to-device variations for increased nonlinearity and high-dimensional mapping. These approaches incur high pre-processing costs and restrict real-time deployment. Here, we introduce a novel heterogeneous memcapacitor-based PRC that exploits internal voltage offsets to enable both monotonic and non-monotonic input-state correlations crucial for efficient high-dimensional transformations. We demonstrate our approach's efficacy by predicting a second-order nonlinear dynamical system with an extremely low prediction error (0.00018). Additionally, we predict a chaotic H\'enon map, achieving a low normalized root mean square error (0.080). Unlike previous PRCs, such errors are achieved without input encoding methods, underscoring the power of distinct input-state correlations. Most importantly, we generalize our approach to other neuromorphic devices that lack inherent voltage offsets using externally applied offsets to realize various input-state correlations. Our approach and unprecedented performance are a major milestone towards high-performance full in-materia PRCs., Comment: Supplementary Information is included under the main text

Published
2024

2. Biomembrane-based Memcapacitive Reservoir Computing System for Energy Efficient Temporal Data Processing

Author

Hossain, Md Razuan, Mohamed, Ahmed Salah, Armendarez, Nicholas Xavier, Najem, Joseph S., Hasan, Md Sakib, Hossain, Md Razuan, Mohamed, Ahmed Salah, Armendarez, Nicholas Xavier, Najem, Joseph S., and Hasan, Md Sakib

Abstract

Reservoir computing is a highly efficient machine learning framework for processing temporal data by extracting features from the input signal and mapping them into higher dimensional spaces. Physical reservoir layers have been realized using spintronic oscillators, atomic switch networks, silicon photonic modules, ferroelectric transistors, and volatile memristors. However, these devices are intrinsically energy-dissipative due to their resistive nature, which leads to increased power consumption. Therefore, capacitive memory devices can provide a more energy-efficient approach. Here, we leverage volatile biomembrane-based memcapacitors that closely mimic certain short-term synaptic plasticity functions as reservoirs to solve classification tasks and analyze time-series data in simulation and experimentally. Our system achieves a 99.6% accuracy rate for spoken digit classification and a normalized mean square error of 7.81*10^{-4} in a second-order non-linear regression task. Furthermore, to showcase the device's real-time temporal data processing capability, we achieve 100% accuracy for a real-time epilepsy detection problem from an inputted electroencephalography (EEG) signal. Most importantly, we demonstrate that each memcapacitor consumes an average of 41.5 fJ of energy per spike, regardless of the selected input voltage pulse width, while maintaining an average power of 415 fW for a pulse width of 100 ms. These values are orders of magnitude lower than those achieved by state-of-the-art memristors used as reservoirs. Lastly, we believe the biocompatible, soft nature of our memcapacitor makes it highly suitable for computing and signal-processing applications in biological environments., Comment: Supplementary information is attached under the main text

Published
2023
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3. Brain-Inspired Reservoir Computing Using Memristors with Tunable Dynamics and Short-Term Plasticity

Author

Armendarez, Nicholas X., Mohamed, Ahmed S., Dhungel, Anurag, Hossain, Md Razuan, Hasan, Md Sakib, Najem, Joseph S., Armendarez, Nicholas X., Mohamed, Ahmed S., Dhungel, Anurag, Hossain, Md Razuan, Hasan, Md Sakib, and Najem, Joseph S.

Abstract

Recent advancements in reservoir computing research have created a demand for analog devices with dynamics that can facilitate the physical implementation of reservoirs, promising faster information processing while consuming less energy and occupying a smaller area footprint. Studies have demonstrated that dynamic memristors, with nonlinear and short-term memory dynamics, are excellent candidates as information-processing devices or reservoirs for temporal classification and prediction tasks. Previous implementations relied on nominally identical memristors that applied the same nonlinear transformation to the input data, which is not enough to achieve a rich state space. To address this limitation, researchers either diversified the data encoding across multiple memristors or harnessed the stochastic device-to-device variability among the memristors. However, this approach requires additional pre-processing steps and leads to synchronization issues. Instead, it is preferable to encode the data once and pass it through a reservoir layer consisting of memristors with distinct dynamics. Here, we demonstrate that ion-channel-based memristors with voltage-dependent dynamics can be controllably and predictively tuned through voltage or adjustment of the ion channel concentration to exhibit diverse dynamic properties. We show, through experiments and simulations, that reservoir layers constructed with a small number of distinct memristors exhibit significantly higher predictive and classification accuracies with a single data encoding. We found that for a second-order nonlinear dynamical system prediction task, the varied memristor reservoir experimentally achieved a normalized mean square error of 0.0015 using only five distinct memristors. Moreover, in a neural activity classification task, a reservoir of just three distinct memristors experimentally attained an accuracy of 96.5%.

Published
2023

4. Spike-based Neuromorphic Computing for Next-Generation Computer Vision

Author

Hasan, Md Sakib, Schuman, Catherine D., Zhang, Zhongyang, Rahman, Tauhidur, Rose, Garrett S., Hasan, Md Sakib, Schuman, Catherine D., Zhang, Zhongyang, Rahman, Tauhidur, and Rose, Garrett S.

Abstract

Neuromorphic Computing promises orders of magnitude improvement in energy efficiency compared to traditional von Neumann computing paradigm. The goal is to develop an adaptive, fault-tolerant, low-footprint, fast, low-energy intelligent system by learning and emulating brain functionality which can be realized through innovation in different abstraction layers including material, device, circuit, architecture and algorithm. As the energy consumption in complex vision tasks keep increasing exponentially due to larger data set and resource-constrained edge devices become increasingly ubiquitous, spike-based neuromorphic computing approaches can be viable alternative to deep convolutional neural network that is dominating the vision field today. In this book chapter, we introduce neuromorphic computing, outline a few representative examples from different layers of the design stack (devices, circuits and algorithms) and conclude with a few exciting applications and future research directions that seem promising for computer vision in the near future., Comment: Pending to be published as a book chapter in the book 'Computer Vision: Challenges, Trends, and Opportunities' from CRC Press

Published
2023

5. Design of an Enhanced Reconfigurable Chaotic Oscillator using G4FET-NDR Based Discrete Map

Author

Hasan, Md Sakib, Shanta, Aysha S., Paul, Partha Sarathi, Sadia, Maisha, Majumder, Md Badruddoja, Rose, Garrett S., Hasan, Md Sakib, Shanta, Aysha S., Paul, Partha Sarathi, Sadia, Maisha, Majumder, Md Badruddoja, and Rose, Garrett S.

Abstract

In this paper, a novel chaotic map is introduced usinga voltage controlled negative differential resistance (NDR) circuitcomposed of ann-channel and ap-channel silicon-on-insulator(SOI) four-gate transistor (G4FET). The multiple gates of theG4FET are leveraged to create a discrete chaotic map with threebifurcation parameters. The three tunable parameters are thegain of a transimpedance amplifier (TIA), top-gate voltage ofn-channel G4FET, and top-gate voltage ofp-channel G4FET. Twomethods are proposed for building chaotic oscillators using thisdiscrete map. The effect of altering bifurcation parameters onchaotic operation is illustrated using bifurcation diagrams andLyapunov exponent. A design methodology for building flexibleand reconfigurable logic gate is outlined and the consequentenhancement in functionality space caused by the existence ofthree independent bifurcation parameters is demonstrated andcompared with previous work., Comment: This paper is accepted and presented in '14TH IEEE DALLAS CIRCUITS AND SYSTEMS CONFERENCE', November 16, 2020. The name of the paper can be found in conference schedule: https://engineering.utdallas.edu/DCAS/schedule.html

Published
2021

6. Design of a Dynamic Parameter-Controlled Chaotic-PRNG in a 65nm CMOS process

Author

Paul, Partha Sarathi, Sadia, Maisha, Hasan, Md Sakib, Paul, Partha Sarathi, Sadia, Maisha, and Hasan, Md Sakib

Abstract

In this paper, we present the design of a new chaotic map circuit with a 65nm CMOS process. This chaotic map circuit uses a dynamic parameter-control topology and generates a wide chaotic range. We propose two designs of dynamic parameter-controlled chaotic map (DPCCM)-based pseudo-random number generators (PRNG). The randomness of the generated sequence is verified using three different statistical tests, namely, NIST SP 800-22 test, FIPS PUB 140-2 test, and Diehard test. Our first design offers a throughput of 200 MS/s with an on-chip area of 0.024mm2 and a power consumption of 2.33mW. The throughput of our second design is 300 MS/s with an area consumption of 0.132mm2 and power consumption of 2.14mW. The wider chaotic range and lower-overhead, offered by our designs, can be highly suitable for various applications such as, logic obfuscation, chaos-based cryptography, re-configurable random number generation,and hard-ware security for resource-constrained edge devices like IoT., Comment: Accepted and presented in '14TH IEEE DALLAS CIRCUITS AND SYSTEMS CONFERENCE'. The name is appeared in the schedule of the conference: https://engineering.utdallas.edu/DCAS/schedule.html

Published
2021

7. A Secure Back-up and Restore for Resource-Constrained IoT based on Nanotechnology

Author

Uddin, Mesbah, Majumder, Md. Badruddoja, Hasan, Md. Sakib, Rose, Garrett S., Uddin, Mesbah, Majumder, Md. Badruddoja, Hasan, Md. Sakib, and Rose, Garrett S.

Abstract

With the emergence of IoT (Internet of things), huge amounts of sensitive data are being processed and transmitted everyday in edge devices with little to no security. Due to their aggressive power management schemes, it is a common and necessary technique to make a back-up of their program states and other necessary data in a non-volatile memory (NVM) before going to sleep or low power mode. However, this memory is often left unprotected as adding robust security measures tends to be expensive for these resource constrained systems. In this paper, we propose a lightweight security system for NVM during low power mode. This security architecture uses the memristor, an emerging nanoscale device which is used to build hardware security primitives like PUF (physical unclonable function) based encryption-decryption, true random number generators (TRNG), and memory integrity checking. A reliability enhancement technique for this PUF is also proposed which shows how this system would work even with less-than-100\% reliable PUF responses. Together, with all these techniques, we have established a dual layer security protocol (data encryption+integrity check) which provides reasonable security to an embedded processor while being very lightweight in terms of area, power, and computation time. A complete system design is demonstrated with 65$n$m CMOS and emerging memristive technology. With this, we have provided a detailed and accurate estimation of resource overhead. Analysis of the security of the whole system is also provided., Comment: Content: 17 pages with 15 figures and 7 tables Submitted to IEEE IoT Journal

Published
2020

15. A 2D Chaotic Oscillator for Analog IC

Author

Paul, Partha Sarathi, Hardy, Parker, Sadia, Maisha, Hasan, Md Sakib, Paul, Partha Sarathi, Hardy, Parker, Sadia, Maisha, and Hasan, Md Sakib

Abstract

The Article Processing Charge (APC) for this article was partially funded by the UM Libraries Open Access Fund.

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20. A 2D Chaotic Oscillator for Analog IC

Author

Paul, Partha Sarathi, Hardy, Parker, Sadia, Maisha, Hasan, Md Sakib, Paul, Partha Sarathi, Hardy, Parker, Sadia, Maisha, and Hasan, Md Sakib

Abstract

The Article Processing Charge (APC) for this article was partially funded by the UM Libraries Open Access Fund.

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24. A 2D Chaotic Oscillator for Analog IC

Author

Paul, Partha Sarathi, Hardy, Parker, Sadia, Maisha, Hasan, Md Sakib, Paul, Partha Sarathi, Hardy, Parker, Sadia, Maisha, and Hasan, Md Sakib

Abstract

The Article Processing Charge (APC) for this article was partially funded by the UM Libraries Open Access Fund.

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28. A 2D Chaotic Oscillator for Analog IC

Author

Paul, Partha Sarathi, Hardy, Parker, Sadia, Maisha, Hasan, Md Sakib, Paul, Partha Sarathi, Hardy, Parker, Sadia, Maisha, and Hasan, Md Sakib

Abstract

The Article Processing Charge (APC) for this article was partially funded by the UM Libraries Open Access Fund.

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