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18 results on '"Islam, A. N. M. Nafiul"'

1. Hardware in Loop Learning with Spin Stochastic Neurons

Author

Islam, A N M Nafiul, Yang, Kezhou, Shukla, Amit K., Khanal, Pravin, Zhou, Bowei, Wang, Wei-Gang, and Sengupta, Abhronil

Subjects
Computer Science - Emerging Technologies
Abstract

Despite the promise of superior efficiency and scalability, real-world deployment of emerging nanoelectronic platforms for brain-inspired computing have been limited thus far, primarily because of inter-device variations and intrinsic non-idealities. In this work, we demonstrate mitigating these issues by performing learning directly on practical devices through a hardware-in-loop approach, utilizing stochastic neurons based on heavy metal/ferromagnetic spin-orbit torque heterostructures. We characterize the probabilistic switching and device-to-device variability of our fabricated devices of various sizes to showcase the effect of device dimension on the neuronal dynamics and its consequent impact on network-level performance. The efficacy of the hardware-in-loop scheme is illustrated in a deep learning scenario achieving equivalent software performance. This work paves the way for future large-scale implementations of neuromorphic hardware and realization of truly autonomous edge-intelligent devices.

Published
2023

2. Hybrid Stochastic Synapses Enabled by Scaled Ferroelectric Field-effect Transistors

Author

Islam, A N M Nafiul, Saha, Arnob, Jiang, Zhouhang, Ni, Kai, and Sengupta, Abhronil

Subjects
Computer Science - Emerging Technologies
Abstract

Achieving brain-like density and performance in neuromorphic computers necessitates scaling down the size of nanodevices emulating neuro-synaptic functionalities. However, scaling nanodevices results in reduction of programming resolution and emergence of stochastic non-idealities. While prior work has mainly focused on binary transitions, in this work we leverage the stochastic switching of a three-state ferroelectric field effect transistor (FeFET) to implement a long-term and short-term 2-tier stochastic synaptic memory with a single device. Experimental measurements are performed on a scaled 28nm high-$k$ metal gate technology-based device to develop a probabilistic model of the hybrid stochastic synapse. In addition to the advantage of ultra-low programming energies afforded by scaling, our hardware-algorithm co-design analysis reveals the efficacy of the 2-tier memory in comparison to binary stochastic synapses in on-chip learning tasks -- paving the way for algorithms exploiting multi-state devices with probabilistic transitions beyond deterministic ones.

Published
2022

3. Astromorphic Self-Repair of Neuromorphic Hardware Systems

Author

Han, Zhuangyu, Islam, A N M Nafiul, and Sengupta, Abhronil

Subjects
Computer Science - Neural and Evolutionary Computing
Abstract

While neuromorphic computing architectures based on Spiking Neural Networks (SNNs) are increasingly gaining interest as a pathway toward bio-plausible machine learning, attention is still focused on computational units like the neuron and synapse. Shifting from this neuro-synaptic perspective, this paper attempts to explore the self-repair role of glial cells, in particular, astrocytes. The work investigates stronger correlations with astrocyte computational neuroscience models to develop macro-models with a higher degree of bio-fidelity that accurately captures the dynamic behavior of the self-repair process. Hardware-software co-design analysis reveals that bio-morphic astrocytic regulation has the potential to self-repair hardware realistic faults in neuromorphic hardware systems with significantly better accuracy and repair convergence for unsupervised learning tasks on the MNIST and F-MNIST datasets. Our implementation source code and trained models are available at https://github.com/NeuroCompLab-psu/Astromorphic_Self_Repair.

Published
2022

4. Intrinsic synaptic plasticity of ferroelectric field effect transistors for online learning

Author

Saha, Arnob, Islam, A N M Nafiul, Zhao, Zijian, Deng, Shan, Ni, Kai, and Sengupta, Abhronil

Subjects
Computer Science - Emerging Technologies
Abstract

Nanoelectronic devices emulating neuro-synaptic functionalities through their intrinsic physics at low operating energies is imperative toward the realization of brain-like neuromorphic computers. In this work, we leverage the non-linear voltage dependent partial polarization switching of a ferroelectric field effect transistor to mimic plasticity characteristics of biological synapses. We provide experimental measurements of the synaptic characteristics for a $28nm$ high-k metal gate technology based device and develop an experimentally calibrated device model for large-scale system performance prediction. Decoupled read-write paths, ultra-low programming energies and the possibility of arranging such devices in a cross-point architecture demonstrate the synaptic efficacy of the device. Our hardware-algorithm co-design analysis reveals that the intrinsic plasticity of the ferroelectric devices has potential to enable unsupervised local learning in edge devices with limited training data.

Published
2021
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5. Hardware in Loop Learning with Spin Stochastic Neurons

Author

Islam, A. N. M. Nafiul, Yang, Kezhou, Shukla, Amit Kumar, Khanal, Pravin, Zhou, Bowei, Wang, Wei-Gang, Sengupta, Abhronil, Islam, A. N. M. Nafiul, Yang, Kezhou, Shukla, Amit Kumar, Khanal, Pravin, Zhou, Bowei, Wang, Wei-Gang, and Sengupta, Abhronil

Abstract

Despite the promise of superior efficiency and scalability, real-world deployment of emerging nanoelectronic platforms for brain-inspired computing have been limited thus far, primarily because of inter-device variations and intrinsic non-idealities. In this work, mitigation of these issues is demonstrated by performing learning directly on practical devices through a hardware-in-loop approach, utilizing stochastic neurons based on heavy metal/ferromagnetic spin-orbit torque heterostructures. The probabilistic switching and device-to-device variability of the fabricated devices of various sizes is characterized to showcase the effect of device dimension on the neuronal dynamics and its consequent impact on network-level performance. The efficacy of the hardware-in-loop scheme is illustrated in a deep learning scenario achieving equivalent software performance. This work paves the way for future large-scale implementations of neuromorphic hardware and realization of truly autonomous edge-intelligent devices. Device-to-device variations and non-idealities have hindered the widespread adoption of neuromorphic platforms thus far. Herein, variation implications are demonstrated through a systematic analysis for spin-orbit torque-based stochastic neurons. Through characterization, the interplay between device dimensions, accuracy, and energy costs are identified - highlighting the need for hardware-software codesign. Finally, variation compensation is experimentally substantiated by training neural networks directly in hardware.image (c) 2024 WILEY-VCH GmbH

Published
2024

6. Hardware in Loop Learning with Spin Stochastic Neurons.

Author

Islam, A N M Nafiul, Yang, Kezhou, Shukla, Amit Kumar, Khanal, Pravin, Zhou, Bowei, Wang, Wei‐Gang, and Sengupta, Abhronil

Abstract

Despite the promise of superior efficiency and scalability, real‐world deployment of emerging nanoelectronic platforms for brain‐inspired computing have been limited thus far, primarily because of inter‐device variations and intrinsic non‐idealities. In this work, mitigation of these issues is demonstrated by performing learning directly on practical devices through a hardware‐in‐loop approach, utilizing stochastic neurons based on heavy metal/ferromagnetic spin–orbit torque heterostructures. The probabilistic switching and device‐to‐device variability of the fabricated devices of various sizes is characterized to showcase the effect of device dimension on the neuronal dynamics and its consequent impact on network‐level performance. The efficacy of the hardware‐in‐loop scheme is illustrated in a deep learning scenario achieving equivalent software performance. This work paves the way for future large‐scale implementations of neuromorphic hardware and realization of truly autonomous edge‐intelligent devices. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Hydrogenated VO2 Bits for Probabilistic Computing

Author

Deng, Sunbin, primary, Park, Tae Joon, additional, Yu, Haoming, additional, Saha, Arnob, additional, Islam, A. N. M. Nafiul, additional, Wang, Qi, additional, Sengupta, Abhronil, additional, and Ramanathan, Shriram, additional

Published
2023
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10. Selective area doping for Mott neuromorphic electronics

Author

Deng, Sunbin, primary, Yu, Haoming, additional, Park, Tae Joon, additional, Islam, A. N. M. Nafiul, additional, Manna, Sukriti, additional, Pofelski, Alexandre, additional, Wang, Qi, additional, Zhu, Yimei, additional, Sankaranarayanan, Subramanian K. R. S., additional, Sengupta, Abhronil, additional, and Ramanathan, Shriram, additional

Published
2023
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11. Complex Oxides for Brain‐Inspired Computing: A Review

Author

Park, Tae Joon, primary, Deng, Sunbin, additional, Manna, Sukriti, additional, Islam, A. N. M. Nafiul, additional, Yu, Haoming, additional, Yuan, Yifan, additional, Fong, Dillon D., additional, Chubykin, Alexander A., additional, Sengupta, Abhronil, additional, Sankaranarayanan, Subramanian K. R. S., additional, and Ramanathan, Shriram, additional

Published
2022
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13. Hydrogenated VO2 Bits for Probabilistic Computing

Author

Deng, Sunbin, Park, Tae Joon, Yu, Haoming, Saha, Arnob, Islam, A. N. M. Nafiul, Wang, Qi, Sengupta, Abhronil, and Ramanathan, Shriram

Abstract

The stochastic nature of electronic phase transitions can serve as a random number generating source. This work reports probabilistic bits ( ${p}$ -bits) based on hydrogen-doped vanadium oxide (H-VO2) devices with tunable insulator-metal transition (IMT) characteristics. Hydrogen donor doping reduces ground state resistance and enables control over threshold switching voltage in the post-fabricated devices. Through a paired-pulse scheme, the H-VO2 devices could generate stochastic bit sequences with adjustable switching probabilities. The sequence with a ${p}$ -bit value of 0.488 could pass 14 out of 15 National Institute of Standards and Technology (NIST) random and pseudorandom number generator tests.

Published
2023
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14. All‐Electric Nonassociative Learning in Nickel Oxide

Author

Mondal, Sandip, primary, Zhang, Zhen, additional, Islam, A. N. M. Nafiul, additional, Andrawis, Robert, additional, Gamage, Sampath, additional, Aghamiri, Neda Alsadat, additional, Wang, Qi, additional, Zhou, Hua, additional, Rodolakis, Fanny, additional, Tran, Richard, additional, Kaur, Jasleen, additional, Chen, Chi, additional, Ong, Shyue Ping, additional, Sengupta, Abhronil, additional, Abate, Yohannes, additional, Roy, Kaushik, additional, and Ramanathan, Shriram, additional

Published
2022
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16. Reconfigurable perovskite nickelate electronics for artificial intelligence

Author

Zhang, Hai-Tian, primary, Park, Tae Joon, additional, Islam, A. N. M. Nafiul, additional, Tran, Dat S. J., additional, Manna, Sukriti, additional, Wang, Qi, additional, Mondal, Sandip, additional, Yu, Haoming, additional, Banik, Suvo, additional, Cheng, Shaobo, additional, Zhou, Hua, additional, Gamage, Sampath, additional, Mahapatra, Sayantan, additional, Zhu, Yimei, additional, Abate, Yohannes, additional, Jiang, Nan, additional, Sankaranarayanan, Subramanian K. R. S., additional, Sengupta, Abhronil, additional, Teuscher, Christof, additional, and Ramanathan, Shriram, additional

Published
2022
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