Littérature scientifique sur le sujet « Neuromorphic technologies/devices »
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Articles de revues sur le sujet "Neuromorphic technologies/devices"
Orii, Yasumitsu, Akihiro Horibe, Kuniaki Sueoka, Keiji Matsumoto, Toyohiro Aoki, Hirokazu Noma, Sayuri Kohara et al. « PERSPECTIVE ON REQUIRED PACKAGING TECHNOLOGIES FOR NEUROMORPHIC DEVICES ». International Symposium on Microelectronics 2015, no 1 (1 octobre 2015) : 000561–66. http://dx.doi.org/10.4071/isom-2015-tha15.
Texte intégralDiao, Yu, Yaoxuan Zhang, Yanran Li et Jie Jiang. « Metal-Oxide Heterojunction : From Material Process to Neuromorphic Applications ». Sensors 23, no 24 (12 décembre 2023) : 9779. http://dx.doi.org/10.3390/s23249779.
Texte intégralMilo, Valerio, Gerardo Malavena, Christian Monzio Compagnoni et Daniele Ielmini. « Memristive and CMOS Devices for Neuromorphic Computing ». Materials 13, no 1 (1 janvier 2020) : 166. http://dx.doi.org/10.3390/ma13010166.
Texte intégralAbbas, Haider, Jiayi Li et Diing Shenp Ang. « Conductive Bridge Random Access Memory (CBRAM) : Challenges and Opportunities for Memory and Neuromorphic Computing Applications ». Micromachines 13, no 5 (30 avril 2022) : 725. http://dx.doi.org/10.3390/mi13050725.
Texte intégralAllwood, Dan A., Matthew O. A. Ellis, David Griffin, Thomas J. Hayward, Luca Manneschi, Mohammad F. KH Musameh, Simon O'Keefe et al. « A perspective on physical reservoir computing with nanomagnetic devices ». Applied Physics Letters 122, no 4 (23 janvier 2023) : 040501. http://dx.doi.org/10.1063/5.0119040.
Texte intégralDella Rocca, Mattia. « Of the Artistic Nude and Technological Behaviorism ». Nuncius 32, no 2 (2017) : 376–411. http://dx.doi.org/10.1163/18253911-03202006.
Texte intégralKurshan, Eren, Hai Li, Mingoo Seok et Yuan Xie. « A Case for 3D Integrated System Design for Neuromorphic Computing and AI Applications ». International Journal of Semantic Computing 14, no 04 (décembre 2020) : 457–75. http://dx.doi.org/10.1142/s1793351x20500063.
Texte intégralHajtó, Dániel, Ádám Rák et György Cserey. « Robust Memristor Networks for Neuromorphic Computation Applications ». Materials 12, no 21 (31 octobre 2019) : 3573. http://dx.doi.org/10.3390/ma12213573.
Texte intégralCovi, Erika, Halid Mulaosmanovic, Benjamin Max, Stefan Slesazeck et Thomas Mikolajick. « Ferroelectric-based synapses and neurons for neuromorphic computing ». Neuromorphic Computing and Engineering 2, no 1 (7 février 2022) : 012002. http://dx.doi.org/10.1088/2634-4386/ac4918.
Texte intégralSueoka, Brandon, et Feng Zhao. « Memristive synaptic device based on a natural organic material—honey for spiking neural network in biodegradable neuromorphic systems ». Journal of Physics D : Applied Physics 55, no 22 (7 mars 2022) : 225105. http://dx.doi.org/10.1088/1361-6463/ac585b.
Texte intégralThèses sur le sujet "Neuromorphic technologies/devices"
Calayir, Vehbi. « Neurocomputing and Associative Memories Based on Emerging Technologies : Co-optimization of Technology and Architecture ». Research Showcase @ CMU, 2014. http://repository.cmu.edu/dissertations/422.
Texte intégralJanzakova, Kamila. « Développement de dendrites polymères organiques en 3D comme dispositif neuromorphique ». Electronic Thesis or Diss., Université de Lille (2022-....), 2023. http://www.theses.fr/2023ULILN017.
Texte intégralNeuromorphic technologies is a promising direction for development of more advanced and energy-efficient computing. They aim to replicate attractive brain features such as high computational efficiency at low power consumption on a software and hardware level. At the moment, brain-inspired software implementations (such as ANN and SNN) have already shown their successful application for different types of tasks (image and speech recognition). However, to benefit more from the brain-like algorithms, one may combine them with appropriate hardware that would also rely on brain-like architecture and processes and thus complement them. Neuromorphic engineering has already shown the utilization of solid-state electronics (CMOS circuits, memristor) for the development of brain-inspired devices. Nevertheless, these implementations are fabricated through top-down methods. In contrast, brain computing relies on bottom-up processes such as interconnectivity between cells and the formation of neural communication pathways.In the light of mentioned above, this work reports on the development of programmable 3D organic neuromorphic devices, which, unlike most current neuromorphic technologies, can be created in a bottom-up manner. This allows bringing neuromorphic technologies closer to the level of brain programming, where necessary neural paths are established only on the need.First, we found out that PEDOT:PSS based 3D interconnections can be formed by means of AC-bipolar electropolymerization and that they are capable of mimicking the growth of neural cells. By tuning individually the parameters of the waveform (peak amplitude voltage -VP, frequency - f, duty cycle - dc and offset voltage - Voff), a wide range of dendrite-like structures was observed with various branching degrees, volumes, surface areas, asymmetry of formation, and even growth dynamics.Next, it was discovered that dendritic morphologies obtained at various frequencies are conductive. Moreover, each structure exhibits an individual conductance value that can be interpreted as synaptic weight. More importantly, the ability of dendrites to function as OECT was revealed. Different dendrites exhibited different performances as OECT. Further, the ability of PEDOT:PSS dendrites to change their conductivity in response to gate voltage was used to mimic brain memory functions (short-term plasticity -STP and long-term plasticity -LTP). STP responses varied depending on the dendritic structure. Moreover, emulation of LTP was demonstrated not only by means of an Ag/AgCl gate wire but as well by means of a self-developed polymer dendritic gate.Finally, structural plasticity was demonstrated through dendritic growth, where the weight of the final connection is governed according to Hebbian learning rules (spike-timing-dependent plasticity - STDP and spike-rate-dependent plasticity - SRDP). Using both approaches, a variety of dendritic topologies with programmable conductance states (i.e., synaptic weight) and various dynamics of growth have been observed. Eventually, using the same dendritic structural plasticity, more complex brain features such as associative learning and classification tasks were emulated.Additionally, future perspectives of such technologies based on self-propagating polymer dendritic objects were discussed
Chapitres de livres sur le sujet "Neuromorphic technologies/devices"
Ricci, Saverio, Piergiulio Mannocci, Matteo Farronato, Alessandro Milozzi et Daniele Ielmini. « Development of Crosspoint Memory Arrays for Neuromorphic Computing ». Dans Special Topics in Information Technology, 65–74. Cham : Springer Nature Switzerland, 2024. http://dx.doi.org/10.1007/978-3-031-51500-2_6.
Texte intégralCarstens, Niko, Maik-Ivo Terasa, Pia Holtz, Sören Kaps, Thomas Strunskus, Abdou Hassanien, Rainer Adelung, Franz Faupel et Alexander Vahl. « Memristive Switching : From Individual Nanoparticles Towards Complex Nanoparticle Networks ». Dans Springer Series on Bio- and Neurosystems, 219–39. Cham : Springer International Publishing, 2023. http://dx.doi.org/10.1007/978-3-031-36705-2_9.
Texte intégralWalters, B., C. Lammie, J. Eshraghian, C. Yakopcic, T. Taha, R. Genov, M. V. Jacob, A. Amirsoleimani et M. R. Azghadi. « Memristive Devices for Neuromorphic and Deep Learning Applications ». Dans Advanced Memory Technology, 680–704. Royal Society of Chemistry, 2023. http://dx.doi.org/10.1039/bk9781839169946-00680.
Texte intégralShanbogh, Shobith M., R. Anju Kumari et Ponnam Anjaneyulu. « Hybrid Devices for Neuromorphic Applications ». Dans Advanced Memory Technology, 622–55. Royal Society of Chemistry, 2023. http://dx.doi.org/10.1039/bk9781839169946-00622.
Texte intégralAhmed, T., V. Krishnamurthi et S. Walia. « Working Dynamics in Low-dimensional Material-based Neuromorphic Devices ». Dans Advanced Memory Technology, 458–97. Royal Society of Chemistry, 2023. http://dx.doi.org/10.1039/bk9781839169946-00458.
Texte intégralYang, Chaofei, Hai Li et Yiran Chen. « Nanoscale Memory Architectures for Neuromorphic Computing ». Dans Security Opportunities in Nano Devices and Emerging Technologies, 215–34. CRC Press, 2017. http://dx.doi.org/10.1201/9781315265056-12.
Texte intégralAhmed, L. Jubair, S. Dhanasekar, K. Martin Sagayam, Surbhi Vijh, Vipin Tyagi, Mayank Singh et Alex Norta. « Introduction to Neuromorphic Computing Systems ». Dans Advances in Systems Analysis, Software Engineering, and High Performance Computing, 1–29. IGI Global, 2023. http://dx.doi.org/10.4018/978-1-6684-6596-7.ch001.
Texte intégralZhuang, Yanling, Shujuan Liu et Qiang Zhao. « Organic Resistive Memories for Neuromorphic Electronics ». Dans Advanced Memory Technology, 60–120. Royal Society of Chemistry, 2023. http://dx.doi.org/10.1039/bk9781839169946-00060.
Texte intégralZanotti, Tommaso, Paolo Pavan et Francesco Maria Puglisi. « Study of RRAM-Based Binarized Neural Networks Inference Accelerators Using an RRAM Physics-Based Compact Model ». Dans Neuromorphic Computing [Working Title]. IntechOpen, 2023. http://dx.doi.org/10.5772/intechopen.110340.
Texte intégralPereira, M. E., E. Carlos, E. Fortunato, R. Martins, P. Barquinha et A. Kiazadeh. « Amorphous Oxide Semiconductor Memristors : Brain-inspired Computation ». Dans Advanced Memory Technology, 431–57. Royal Society of Chemistry, 2023. http://dx.doi.org/10.1039/bk9781839169946-00431.
Texte intégralActes de conférences sur le sujet "Neuromorphic technologies/devices"
Strukov, D. « Emerging Memory Technologies for Neuromorphic Computing ». Dans 2016 International Conference on Solid State Devices and Materials. The Japan Society of Applied Physics, 2016. http://dx.doi.org/10.7567/ssdm.2016.b-7-02.
Texte intégralShelby, Robert M., Pritish Narayanan, Stefano Ambrogio, Hsinyu Tsai, Kohji Hosokawa, Scott C. Lewis et Geoffrey W. Burr. « Neuromorphic technologies for next-generation cognitive computing ». Dans 2017 IEEE Electron Devices Technology and Manufacturing Conference (EDTM). IEEE, 2017. http://dx.doi.org/10.1109/edtm.2017.7947500.
Texte intégralLee, Sungsik. « Amorphous oxide thin-film devices for neuromorphic applications ». Dans Advances in Display Technologies XII, sous la direction de Jiun-Haw Lee, Qiong-Hua Wang et Tae-Hoon Yoon. SPIE, 2022. http://dx.doi.org/10.1117/12.2612015.
Texte intégralShastri, Bhavin J., Thomas Ferreira de Lima, Alexander N. Tait, Bicky A. Marquez, Hsuan-Tung Peng, Chaoran Huang, Volker J. Sorger et Paul R. Prucnal. « Advances in neuromorphic photonics (Conference Presentation) ». Dans Integrated Optics : Devices, Materials, and Technologies XXIV, sous la direction de Sonia M. García-Blanco et Pavel Cheben. SPIE, 2020. http://dx.doi.org/10.1117/12.2554476.
Texte intégralOffrein, Bert Jan, Tommaso Stecconi, Donato Francesco Falcone, Elger Anne Vlieg, Felix Hermann, Laura Bégon-Lours, Daniel Jubin et al. « Photonic and electronic integrated technologies for neuromorphic computing ». Dans 2023 International Conference on Solid State Devices and Materials. The Japan Society of Applied Physics, 2023. http://dx.doi.org/10.7567/ssdm.2023.h-2-01.
Texte intégralDabos, George, George Mourgias-Alexandris, Angelina Totovic, Manos Kirtas, Nikos Passalis, Anastasios Tefas et Nikos Pleros. « End-to-end deep learning with neuromorphic photonics ». Dans Integrated Optics : Devices, Materials, and Technologies XXV, sous la direction de Sonia M. García-Blanco et Pavel Cheben. SPIE, 2021. http://dx.doi.org/10.1117/12.2587668.
Texte intégralPolnau, Ernst E., et Mikhail Vorontsov. « Atmospheric turbulence characterization using a neuromorphic camera ». Dans Image Sensing Technologies : Materials, Devices, Systems, and Applications IX, sous la direction de K. Kay Son, Nibir K. Dhar, Achyut K. Dutta et Sachidananda R. Babu. SPIE, 2022. http://dx.doi.org/10.1117/12.2618894.
Texte intégralPhillips, Matthew E., Nigel D. Stepp, Jose Cruz-Albrecht, Vincent De Sapio, Tsai-Ching Lu et Vincent Sritapan. « Neuromorphic and early warning behavior-based authentication for mobile devices ». Dans 2016 IEEE Symposium on Technologies for Homeland Security (HST). IEEE, 2016. http://dx.doi.org/10.1109/ths.2016.7568965.
Texte intégralYoo, S. J. Ben. « Intelligent imaging microsystems realized by 3D electronic-photonic integrated circuits with embedded neuromorphic computing ». Dans Image Sensing Technologies : Materials, Devices, Systems, and Applications XI, sous la direction de Nibir K. Dhar, Achyut K. Dutta et Sachidananda R. Babu. SPIE, 2024. http://dx.doi.org/10.1117/12.3013294.
Texte intégralRobinson, Michael G., Lin Zhang, Kristina M. Johnson et David A. Jared. « Custom electro-optic devices for optically implemented neuromorphic computing systems ». Dans OSA Annual Meeting. Washington, D.C. : Optica Publishing Group, 1990. http://dx.doi.org/10.1364/oam.1990.mvv9.
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