Your search keyword '"Vodenicarevic D"' showing total 15 results

1. Microwave neural processing and broadcasting with spintronic nano-oscillators

Author

Talatchian, P., Romera, M., Tsunegi, S., Araujo, F. Abreu, Cros, V., Bortolotti, P., Trastoy, J., Yakushiji, K., Fukushima, A., Kubota, H., Yuasa, S., Ernoult, M., Vodenicarevic, D., Hirtzlin, T., Locatelli, N., Querlioz, D., and Grollier, J.

Subjects

Physics - Applied Physics, Computer Science - Emerging Technologies

Abstract

Can we build small neuromorphic chips capable of training deep networks with billions of parameters? This challenge requires hardware neurons and synapses with nanometric dimensions, which can be individually tuned, and densely connected. While nanosynaptic devices have been pursued actively in recent years, much less has been done on nanoscale artificial neurons. In this paper, we show that spintronic nano-oscillators are promising to implement analog hardware neurons that can be densely interconnected through electromagnetic signals. We show how spintronic oscillators maps the requirements of artificial neurons. We then show experimentally how an ensemble of four coupled oscillators can learn to classify all twelve American vowels, realizing the most complicated tasks performed by nanoscale neurons.

Published

2019

2. Designing large arrays of interacting spin-torque nano-oscillators for microwave information processing

Author

Talatchian, P., Romera Rabasa, Miguel Álvaro, Abreu Araujo, Flavio, Bortolotti, P., Cros, V., Vodenicarevic, D., Locatelli, N., Querlioz, D., Grollier, J., Talatchian, P., Romera Rabasa, Miguel Álvaro, Abreu Araujo, Flavio, Bortolotti, P., Cros, V., Vodenicarevic, D., Locatelli, N., Querlioz, D., and Grollier, J.

Abstract

Arrays of spin-torque nano-oscillators are promising for broadband microwave signal detection and processing, as well as for neuromorphic computing. In many of these applications, the oscillators should be engineered to have equally spaced frequencies and equal sensitivity to microwave inputs. Here we design spin-torque nano-oscillator arrays with these rules and estimate their optimum size for a given sensitivity, as well as the frequency range that they cover. For this purpose, we explore analytically and numerically conditions to obtain vortex spin-torque nano-oscillators with equally spaced gyrotropic oscillation frequencies and having all similar synchronization bandwidths to input microwave signals. We show that arrays of hundreds of oscillators covering ranges of several hundred MHz can be built taking into account nanofabrication constraints., European Research Council, Fonds de la Recherche Scientifique, Depto. de Física de Materiales, Fac. de Ciencias Físicas, TRUE, pub

Published

2020

3. Designing Large Arrays of Interacting Spin-Torque Nano-Oscillators for Microwave Information Processing

Author

UCL - SST/IMCN/BSMA - Bio and soft matter, Talatchian, P., Romera, M., Abreu Araujo, Flavio, Bortolotti, P., Cros, V., Vodenicarevic, D., Locatelli, N., Querlioz, D., Grollier, J., UCL - SST/IMCN/BSMA - Bio and soft matter, Talatchian, P., Romera, M., Abreu Araujo, Flavio, Bortolotti, P., Cros, V., Vodenicarevic, D., Locatelli, N., Querlioz, D., and Grollier, J.

Abstract

Arrays of spin-torque nano-oscillators are promising for broadband microwave signal detection and processing, as well as for neuromorphic computing. In many of these applications, the oscillators should be engineered to have equally spaced frequencies and equal sensitivity to microwave inputs. Here we design spin-torque nano-oscillator arrays with these rules and estimate their optimum size for a given sensitivity, as well as the frequency range that they cover. For this purpose, we explore analytically and numerically conditions to obtain vortex spin-torque nano-oscillators with equally spaced gyrotropic oscillation frequencies and having all similar synchronization bandwidths to input microwave signals. We show that arrays of hundreds of oscillators covering ranges of several hundred MHz can be built taking into account nanofabrication constraints.

Published

2020

4. Designing Large Arrays of Interacting Spin-Torque Nano-Oscillators for Microwave Information Processing

Author

Talatchian, P., primary, Romera, M., additional, Araujo, F. Abreu, additional, Bortolotti, P., additional, Cros, V., additional, Vodenicarevic, D., additional, Locatelli, N., additional, Querlioz, D., additional, and Grollier, J., additional

Published

2020

5. Microwave Neural Processing and Broadcasting with Spintronic Nano-Oscillators

Author

Talatchian, P., primary, Romera, M., additional, Tsunegi, S., additional, Araujo, F. Abreu, additional, Cros, V., additional, Bortolotti, P., additional, Trastoy, J., additional, Yakushiji, K., additional, Fukushima, A., additional, Kubota, H., additional, Yuasa, S., additional, Ernoult, M., additional, Vodenicarevic, D., additional, Hirtzlin, T., additional, Locatelli, N., additional, Querlioz, D., additional, and Grollier, J., additional

Published

2018

6. Microwave Neural Processing and Broadcasting with Spintronic Nano-Oscillators

Author

UCL - SST/IMCN/BSMA - Bio and soft matter, Talatchian, P., Romera, M., Tsunegi, S., Abreu Araujo, Flavio, Cros, V., Bortolotti, P., Trastoy, J., Yakushiji, K., Fukushima, A., Kubota, H., Yuasa, S., Ernoult, M., Vodenicarevic, D., Hirtzlin, T., Locatelli, N., Querlioz, D., Grollier, J., UCL - SST/IMCN/BSMA - Bio and soft matter, Talatchian, P., Romera, M., Tsunegi, S., Abreu Araujo, Flavio, Cros, V., Bortolotti, P., Trastoy, J., Yakushiji, K., Fukushima, A., Kubota, H., Yuasa, S., Ernoult, M., Vodenicarevic, D., Hirtzlin, T., Locatelli, N., Querlioz, D., and Grollier, J.

Abstract

Can we build small neuromorphic chips capable of training deep networks with billions of parameters? This challenge requires hardware neurons and synapses with nanometric dimensions, which can be individually tuned, and densely connected. While nanosynaptic devices have been pursued actively in recent years, much less has been done on nanoscale artificial neurons. In this paper, we show that spintronic nano-oscillators are promising to implement analog hardware neurons that can be densely interconnected through electromagnetic signals. We show how spintronic oscillators maps the requirements of artificial neurons. We then show experimentally how an ensemble of four coupled oscillators can learn to classify all twelve American vowels, realizing the most complicated tasks performed by nanoscale neurons.

Published

2018

7. Low-energy truly random number generation with superparamagnetic tunnel junctions for unconventional computing

Author

Vodenicarevic, D., Locatelli, N., Mizrahi, A., Friedman, J. S., Vincent, A. F., Romera Rabasa, Miguel Álvaro, Fukushima, A., Yakushiji, K., Kubota, H., Yuasa, S., Tiwari, S., Grollier, J., Querlioz, D., Vodenicarevic, D., Locatelli, N., Mizrahi, A., Friedman, J. S., Vincent, A. F., Romera Rabasa, Miguel Álvaro, Fukushima, A., Yakushiji, K., Kubota, H., Yuasa, S., Tiwari, S., Grollier, J., and Querlioz, D.

Abstract

Low-energy random number generation is critical for many emerging computing schemes proposed to complement or replace von Neumann architectures. However, current random number generators are always associated with an energy cost that is prohibitive for these computing schemes. We introduce random number bit generation based on specific nanodevices: superparamagnetic tunnel junctions. We experimentally demonstrate high-quality random bit generation that represents an orders-of-magnitude improvement in energy efficiency over current solutions. We show that the random generation speed improves with nanodevice scaling, and we investigate the impact of temperature, magnetic field, and cross talk. Finally, we show how alternative computing schemes can be implemented using superparamagentic tunnel junctions as random number generators. These results open the way for fabricating efficient hardware computing devices leveraging stochasticity, and they highlight an alternative use for emerging nanodevices., European Research Council (ERC), BAMBI EU collaborative FET Project grant (FP7-ICT-C), Agence Nationale de la Recherche (ANR), French Ministere de l'ecologie, du developpement durable et de l'energie, Depto. de Física de Materiales, Fac. de Ciencias Físicas, TRUE, pub

Published

2017

8. Synaptic Weight Modulation and Logic Function Learning with Electro-grafted Nano Organic Memristors

Author

Lin, Y-P, Bennett, C, Chabi, D, Vodenicarevic, D, Querlioz, D, Cabaret, T, Balan, A, Jousselme, B, Gamrat, C, Klein, J-O, Derycke, V, Laboratoire Innovation en Chimie des Surfaces et NanoSciences (LICSEN), Nanosciences et Innovation pour les Matériaux, la Biomédecine et l'Energie (ex SIS2M) (NIMBE UMR 3685), Institut Rayonnement Matière de Saclay (IRAMIS), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Institut Rayonnement Matière de Saclay (IRAMIS), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), Centre de Nanosciences et Nanotechnologies (C2N (UMR_9001)), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Laboratoire d'Intégration des Systèmes et des Technologies (LIST), Direction de Recherche Technologique (CEA) (DRT (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Laboratoire Innovation en Chimie des Surfaces et NanoSciences (LICSEN UMR 3685), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Institut Rayonnement Matière de Saclay (IRAMIS), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), and Laboratoire d'Intégration des Systèmes et des Technologies (LIST (CEA))

Subjects

electro-grafting, spike timing-dependent plasticity, organic memristors, [CHIM.MATE]Chemical Sciences/Material chemistry, supervised learning, neuromorphic circuit

Abstract

International audience; Neuromorphic computing has gained important attention since it is an efficient way to handle advanced cognitive tasks such as image recognition and classification. Hardware implementation of an artificial neural network (ANN) requires arrays of scalable memory elements to act as artificial synapses. Memristors, which are two-terminal analog memory devices, are excellent candidates for this application as their tuna-ble resistance could be used to code and store synaptic weights with, in principle, low power consumption. In this work, we studied metal-organic-metal memristors in which the organic layer is a dense and robust electro-grafted thin film of redox complexes. The process allows fabricating planar and vertical junctions, as well as small crossbar arrays. The unipolar devices display non-volatile multi-level conductivity states with high RMAX/RMIN ratio and two distinct thresholds. The characteristics of individual memristors were characterized in depth with respect to the targeted synaptic function. We notably showed that they possess the Spike Timing-Dependent Plasticity (STDP) property (their conductivity evolves as a function of the time-delay between incoming pulses at both terminals), which is critical for future applications in neuromorphic circuits based on unsu-pervised learning. In parallel, we implemented a series of memristors as synapses in a simple prototype: a mixed circuit with the neuron implemented with conventional electronics. This ANN is able to learn linearly separable 3-input logic functions through an iterative supervised learning algorithm inspired by the Widrow-Hoff rule.

Published

2016

9. Low-Energy Truly Random Number Generation with Superparamagnetic Tunnel Junctions for Unconventional Computing

Author

Vodenicarevic, D., primary, Locatelli, N., additional, Mizrahi, A., additional, Friedman, J. S., additional, Vincent, A. F., additional, Romera, M., additional, Fukushima, A., additional, Yakushiji, K., additional, Kubota, H., additional, Yuasa, S., additional, Tiwari, S., additional, Grollier, J., additional, and Querlioz, D., additional

Published

2017

10. Spintronic Devices as Key Elements for Energy-Efficient Neuroinspired Architectures

Author

Locatelli, N., Vincent, A. F., Mizrahi, A., Friedman, J. S., Vodenicarevic, D., Kim, J. -V, Jacques-Olivier KLEIN, Zhao, W., Grollier, J., Querlioz, D., Unité mixte de physique CNRS/Thales (UMPhy CNRS/THALES), Centre National de la Recherche Scientifique (CNRS)-THALES, Institut d'électronique fondamentale (IEF), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Centre de Nanosciences et de Nanotechnologies [Orsay] (C2N), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Saclay, and Beihang University (BUAA)

Subjects

[PHYS]Physics [physics], [SPI]Engineering Sciences [physics], 0303 health sciences, 03 medical and health sciences, 02 engineering and technology, Hardware_ARITHMETICANDLOGICSTRUCTURES, 021001 nanoscience & nanotechnology, 0210 nano-technology, 030304 developmental biology

Abstract

International audience; —Processing the current deluge of data using conventional CMOS architectures requires a tremendous amount of energy, as it is inefficient for tasks such as data mining, recognition and synthesis. Alternative models of computation based on neuroinspiration can prove much more efficient for these kinds of tasks, but do not map ideally to traditional CMOS. Spintronics, by contrast, can bring features such as embedded nonvolatile memory and stochastic and memristive behavior, which, when associated with CMOS, can be key enablers for neuroinspired computing. In this paper, we explore different works that go in this direction. First, we illustrate how recent developments in embedded nonvolatile memory based on magnetic tunnel junctions (MTJs) can provide the large amount of nonvolatile memory required in neuro-inspired designs while avoiding Von Neumann bottleneck. Second, we show that recently developed spintronic memristors can implement artificial synapses for neuromorphic systems. With a more groundbreaking design, we show how the probabilistic writing of single MTJ bits can efficiently replace multi-level weighting for some classes of neuroinspired architectures. Finally, we show that a special class of MTJs can exhibit the phenomenon of stochastic resonance, a strategy used in biological systems to detect weak signals. These results suggest that the impact of spintronics extends beyond the traditional standalone and embedded memory markets.

Published

2015

11. Theoretical study of the magnetic order inα-CoV2O6

Author

Saúl, A., primary, Vodenicarevic, D., additional, and Radtke, G., additional

Published

2013

12. Theoretical study of the magnetic order in α-CoV2O6.

Author

Saúl, A., Vodenicarevic, D., and Radtket, G.

Subjects

*MAGNETICS, *ELECTRONIC structure, *ANTIFERROMAGNETISM, *MONTE Carlo method, *CONDENSED matter

Abstract

The electronic structure and magnetic properties of α-CoV2O6 are investigated using density functional theory calculations including spin-orbit coupling and orbital polarization effects. These calculations reveal a strong magnetocrystalline anisotropy with a magnetization easy axis close to the c axis. The evaluation of magnetic couplings on the basis of broken-symmetry formalism suggests the occurrence of an antiferromagnetic ground-state order where ferromagnetic chains running along b are coupled antiferromagnetically to their nearest neighbors along a and c. Monte Carlo simulations are finally employed to explore the origins of the 1/3 plateau observed in the magnetization curves of this compound and to propose a structure for the corresponding state. [ABSTRACT FROM AUTHOR]

Published

2013

13. Vowel recognition with four coupled spin-torque nano-oscillators.

Author

Romera M, Talatchian P, Tsunegi S, Abreu Araujo F, Cros V, Bortolotti P, Trastoy J, Yakushiji K, Fukushima A, Kubota H, Yuasa S, Ernoult M, Vodenicarevic D, Hirtzlin T, Locatelli N, Querlioz D, and Grollier J

Abstract

In recent years, artificial neural networks have become the flagship algorithm of artificial intelligence 1 . In these systems, neuron activation functions are static, and computing is achieved through standard arithmetic operations. By contrast, a prominent branch of neuroinspired computing embraces the dynamical nature of the brain and proposes to endow each component of a neural network with dynamical functionality, such as oscillations, and to rely on emergent physical phenomena, such as synchronization 2-6 , for solving complex problems with small networks 7-11 . This approach is especially interesting for hardware implementations, because emerging nanoelectronic devices can provide compact and energy-efficient nonlinear auto-oscillators that mimic the periodic spiking activity of biological neurons 12-16 . The dynamical couplings between oscillators can then be used to mediate the synaptic communication between the artificial neurons. One challenge for using nanodevices in this way is to achieve learning, which requires fine control and tuning of their coupled oscillations 17 ; the dynamical features of nanodevices can be difficult to control and prone to noise and variability 18 . Here we show that the outstanding tunability of spintronic nano-oscillators-that is, the possibility of accurately controlling their frequency across a wide range, through electrical current and magnetic field-can be used to address this challenge. We successfully train a hardware network of four spin-torque nano-oscillators to recognize spoken vowels by tuning their frequencies according to an automatic real-time learning rule. We show that the high experimental recognition rates stem from the ability of these oscillators to synchronize. Our results demonstrate that non-trivial pattern classification tasks can be achieved with small hardware neural networks by endowing them with nonlinear dynamical features such as oscillations and synchronization.

Published

2018

14. A Nanotechnology-Ready Computing Scheme based on a Weakly Coupled Oscillator Network.

Author

Vodenicarevic D, Locatelli N, Abreu Araujo F, Grollier J, and Querlioz D

Abstract

With conventional transistor technologies reaching their limits, alternative computing schemes based on novel technologies are currently gaining considerable interest. Notably, promising computing approaches have proposed to leverage the complex dynamics emerging in networks of coupled oscillators based on nanotechnologies. The physical implementation of such architectures remains a true challenge, however, as most proposed ideas are not robust to nanotechnology devices' non-idealities. In this work, we propose and investigate the implementation of an oscillator-based architecture, which can be used to carry out pattern recognition tasks, and which is tailored to the specificities of nanotechnologies. This scheme relies on a weak coupling between oscillators, and does not require a fine tuning of the coupling values. After evaluating its reliability under the severe constraints associated to nanotechnologies, we explore the scalability of such an architecture, suggesting its potential to realize pattern recognition tasks using limited resources. We show that it is robust to issues like noise, variability and oscillator non-linearity. Defining network optimization design rules, we show that nano-oscillator networks could be used for efficient cognitive processing.

Published

2017

15. Physical Realization of a Supervised Learning System Built with Organic Memristive Synapses.

Author

Lin YP, Bennett CH, Cabaret T, Vodenicarevic D, Chabi D, Querlioz D, Jousselme B, Derycke V, and Klein JO

Abstract

Multiple modern applications of electronics call for inexpensive chips that can perform complex operations on natural data with limited energy. A vision for accomplishing this is implementing hardware neural networks, which fuse computation and memory, with low cost organic electronics. A challenge, however, is the implementation of synapses (analog memories) composed of such materials. In this work, we introduce robust, fastly programmable, nonvolatile organic memristive nanodevices based on electrografted redox complexes that implement synapses thanks to a wide range of accessible intermediate conductivity states. We demonstrate experimentally an elementary neural network, capable of learning functions, which combines four pairs of organic memristors as synapses and conventional electronics as neurons. Our architecture is highly resilient to issues caused by imperfect devices. It tolerates inter-device variability and an adaptable learning rule offers immunity against asymmetries in device switching. Highly compliant with conventional fabrication processes, the system can be extended to larger computing systems capable of complex cognitive tasks, as demonstrated in complementary simulations.

Published

2016