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Toshiyuki Yamane
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2020 – today
- 2023
- [j4]Toshiyuki Yamane, Akira Hirose, Bert Jan Offrein:
Editorial: Physical neuromorphic computing and its industrial applications. Frontiers Neuroinformatics 17 (2023) - 2020
- [j3]Gouhei Tanaka
, Ryosho Nakane
Spatially Arranged Sparse Recurrent Neural Networks for Energy Efficient Associative Memory. IEEE Trans. Neural Networks Learn. Syst. 31(1): 24-38 (2020) - [i2]Seiji Takeda, Toshiyuki Hama, Hsiang-Han Hsu, Toshiyuki Yamane, Koji Masuda, Victoria A. Piunova, Dmitry Zubarev, Jed Pitera, Daniel P. Sanders, Daiju Nakano:
AI-driven Inverse Design System for Organic Molecules. CoRR abs/2001.09038 (2020)
2010 – 2019
- 2019
- [j2]Akira Hirose, Seiji Takeda, Toshiyuki Yamane, Hidetoshi Numata, Naoki Kanazawa, Jean Benoit Héroux, Daiju Nakano, Ryosho Nakane, Gouhei Tanaka:
Physical reservoir computing: Possibility to resolve the inconsistency between neuro-AI principles and its hardware. Aust. J. Intell. Inf. Process. Syst. 16(4): 49-55 (2019) - [j1]Gouhei Tanaka
Recent advances in physical reservoir computing: A review. Neural Networks 115: 100-123 (2019) - [c25]Toshiyuki Yamane, Jean Benoit Héroux, Hidetoshi Numata, Gouhei Tanaka, Ryosho Nakane
Application Identification of Network Traffic by Reservoir Computing. ICONIP (5) 2019: 389-396 - 2018
- [c24]Akira Hirose, Gouhei Tanaka
Proposal of Carrier-Wave Reservoir Computing. ICONIP (1) 2018: 616-624 - [c23]Toshiyuki Yamane, Hidetoshi Numata, Jean Benoit Héroux, Naoki Kanazawa, Seiji Takeda, Gouhei Tanaka
Dimensionality Reduction by Reservoir Computing and Its Application to IoT Edge Computing. ICONIP (1) 2018: 635-643 - [i1]Gouhei Tanaka, Toshiyuki Yamane, Jean Benoit Héroux, Ryosho Nakane, Naoki Kanazawa, Seiji Takeda, Hidetoshi Numata, Daiju Nakano, Akira Hirose:
Recent Advances in Physical Reservoir Computing: A Review. CoRR abs/1808.04962 (2018) - 2017
- [c22]Akira Hirose, Seiji Takeda, Toshiyuki Yamane, Daiju Nakano, Shigeru Nakagawa, Ryosho Nakane
Complex-Valued Neural Networks for Wave-Based Realization of Reservoir Computing. ICONIP (4) 2017: 449-456 - [c21]Gouhei Tanaka
Waveform Classification by Memristive Reservoir Computing. ICONIP (4) 2017: 457-465 - [c20]Toshiyuki Yamane, Seiji Takeda, Daiju Nakano, Gouhei Tanaka
Simulation Study of Physical Reservoir Computing by Nonlinear Deterministic Time Series Analysis. ICONIP (1) 2017: 639-647 - 2016
- [c19]Gouhei Tanaka
Exploiting Heterogeneous Units for Reservoir Computing with Simple Architecture. ICONIP (1) 2016: 187-194 - [c18]Toshiyuki Yamane, Seiji Takeda, Daiju Nakano, Gouhei Tanaka
Dynamics of Reservoir Computing at the Edge of Stability. ICONIP (1) 2016: 205-212 - [c17]Seiji Takeda, Daiju Nakano, Toshiyuki Yamane, Gouhei Tanaka
Photonic Reservoir Computing Based on Laser Dynamics with External Feedback. ICONIP (1) 2016: 222-230 - 2015
- [c16]Yasuteru Kohda, Kohji Takano, Daiju Nakano, Nobuyuki Ohba, Toshiyuki Yamane, Yasunao Katayama:
Single-channel full-duplex mmWave link using phased-array for Ethernet. CCNC 2015: 400-405 - [c15]Toshiyuki Yamane, Yasunao Katayama, Ryosho Nakane
Wave-Based Reservoir Computing by Synchronization of Coupled Oscillators. ICONIP (3) 2015: 198-205 - [c14]Gouhei Tanaka
Regularity and randomness in modular network structures for neural associative memories. IJCNN 2015: 1-7 - [c13]Yasunao Katayama, Toshiyuki Yamane, Daiju Nakano, Ryosho Nakane
Wave-based device scaling concept for brain-like energy efficiency and integration. NANOARCH 2015: 23-24 - 2014
- [c12]Gouhei Tanaka, Toshiyuki Yamane, Daiju Nakano, Ryosho Nakane
Hopfield-Type Associative Memory with Sparse Modular Networks. ICONIP (1) 2014: 255-262 - [c11]Yasunao Katayama, Toshiyuki Yamane, Daiju Nakano:
An Energy-Efficient Computing Approach by Filling the Connectome Gap. UCNC 2014: 229-241 - [c10]Daiju Nakano, Yasuteru Kohda, Kohji Takano, Nobuyuki Ohba, Toshiyuki Yamane, Yasunao Katayama:
60-GHz single-carrier coherent detection system with robust 16-QAM signal recovery. WCNC 2014: 341-346 - 2012
- [c9]Nobuyuki Ohba, Kohji Takano, Yasuteru Kohda, Daiju Nakano, Toshiyuki Yamane, Yasunao Katayama:
Multimedia content-downloading system using millimeter-wave attached memory. CCNC 2012: 94-98 - [c8]Toshiyuki Yamane, Yasunao Katayama:
An effective initialization of interference cancellation algorithms for distributed MIMO systems in wireless datacenters. GLOBECOM 2012: 4249-4254 - [c7]Yasunao Katayama, Toshiyuki Yamane, Yasuteru Kohda, Kohji Takano, Daiju Nakano, Nobuyuki Ohba:
MIMO link design strategy for wireless data center applications. WCNC 2012: 3302-3306 - 2011
- [c6]Daiju Nakano, Yasuteru Kohda, Kohji Takano, Toshiyuki Yamane, Nobuyuki Ohba, Yasunao Katayama:
Multi-Gbps 60-GHz single-carrier system using a low-power coherent detection technique. COOL Chips 2011: 1-3 - [c5]Yasuteru Kohda, Nobuyuki Ohba, Kohji Takano, Daiju Nakano, Toshiyuki Yamane, Yasunao Katayama:
Instant multimedia contents downloading system using a 60-GHZ-2.4-GHZ hybrid wireless link. ICME 2011: 1-6
2000 – 2009
- 2003
- [c4]Toshiyuki Yamane, Yasunao Katayama:
An ultra-fast Reed-Solomon decoder soft-IP with 8-error correcting capability. ICASSP (2) 2003: 297-300 - [c3]Toshiyuki Yamane, Yasunao Katayama:
Bit error rate analysis on iterative two-stage decoding of two dimensional codes by importance sampling. ICC 2003: 3140-3144 - [c2]Toshiyuki Yamane, Yasunao Katayama:
An ultra-fast Reed-Solomon decoder soft-IP with 8-error correcting capability. ICME 2003: 445-448 - 2001
- [c1]Sumio Morioka
Towards Efficient Verification of Arithmetic Algorithms over Galois Fields GF(2m). CAV 2001: 465-477
Coauthor Index
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