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Hiroyuki Torikai
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2020 – today
- 2024
- [j50]Koki Sone, Hiroyuki Torikai:
A novel design of ergodic sequential logic cochlear single partition model: reproduction of nonlinear compression characteristics of mammalian cochlea and efficient implementation. IEICE Electron. Express 21(6): 20240036 (2024) - [j49]Yuta Shiomi, Hiroyuki Torikai:
Ergodic sequential logic spiking neural network: reproductions of biologically plausible spatio-temporal phenomena and low-power implementation towards neural prosthesis. IEICE Electron. Express 21(8): 20240095 (2024) - [j48]Itsuki Kubota, Kentaro Takeda, Hiroyuki Torikai:
A Novel Ergodic Discrete Difference Equation Cochlear Model: Theoretical Analyses, Reproduction of Mammalian Nonlinear Sound Processing, and Comparison of Implementation. IEEE Trans. Circuits Syst. II Express Briefs 71(2): 877-881 (2024) - [j47]Yuta Shiomi, Haruto Suzuki, Hiroyuki Torikai:
A Novel Hardware-Efficient Ergodic Sequential Logic Neuron Model: Cellular Differentiation Method and Virtual Clinical Trial of Neural Prosthesis. IEEE Trans. Circuits Syst. II Express Briefs 71(9): 4311-4315 (2024) - [c87]Rikuto Nozu, Yunosuke Takemae, Hiroyuki Torikai:
A Novel Wireless CPG Based on Ergodic Sequential Logic Dynamics: Synchronization Analysis, Efficient FPGA Implementation, and Applications to Robot Control and Functional Electronic Stimulation. IJCNN 2024: 1-8 - [c86]Jiaying Lin, Ryuji Nagazawa, Koichi Tokunaga, Kien Nguyen, Hiroo Sekiya, Hiroyuki Torikai, Won-Joo Hwang:
SNN Modeling of Cricket Auditory Network with Izhikevich Model Optimized by PSO. ISCAS 2024: 1-5 - [c85]Koki Sone, Hiroyuki Torikai:
A Novel Design of Ergodic Sequential Logic Integrated Cochlear Model for Reproduction of Nonlinear Compression Characteristics of Mammalian Cochlea and Efficient Implementation. ISCAS 2024: 1-5 - [c84]Yunosuke Takemae, Hiroyuki Torikai, Masaya Kudo, Koki Sone:
A Novel Hardware-Efficient Wireless Functional Electrical Stimulation Device Based on Nonlinear Dynamics of Ergodic Cellular Automaton. ISCAS 2024: 1-5 - [c83]Isaki Yamamoto, Hiroyuki Torikai:
A Novel Ergodic Cellular Automaton Asthma Model: Reproductions of Nonlinear Dynamics of Asthma and Efficient FPGA Implementation. ISCAS 2024: 1-5 - 2023
- [j46]Shogo Shirafuji, Hiroyuki Torikai:
A Novel Ergodic Cellular Automaton Model of Gene-Protein Network: Theoretical Nonlinear Analyses and Efficient FPGA Implementation. IEEE Access 11: 300-312 (2023) - [j45]Kazuhito Onodera, Hiroyuki Torikai:
A novel design method of simplified central nervous system model of C. elegans based on hybrid dynamics of sequential logic and numerical integration. IEICE Electron. Express 20(10): 20230110 (2023) - [c82]Manami Makihira, Hiroyuki Torikai:
A Novel Ergodic CA Cochlear Model for Reproductions of Nonlinear Frequency Response Characteristics of Mammalian Cochlear Partitions and Ultra-Low-Power Implementation. IECON 2023: 1-6 - [c81]Kento Nakamura, Hiroyuki Torikai:
A Novel Ergodic Sequential Logic CPG: Efficient FPGA Implementation and Realizations of Various Gaits and their Safe Transitions. IJCNN 2023: 1-8 - [c80]Yuta Shiomi, Hiroyuki Torikai:
A novel hardware-efficient ergodic sequential logic spiking neural network and reproductions of biologically plausible spatio-temporal phenomena towards development of neural prosthetic device. IJCNN 2023: 1-8 - [c79]Kentaro Takeda, Hiroyuki Torikai:
A novel hardware-efficient liquid state machine of non-simultaneous CA-based neurons for spatio-temporal pattern recognition. IJCNN 2023: 1-8 - [c78]Yui Kishimoto, Itsuki Kubota, Hiroyuki Torikai:
A Novel Integrated Cochlear Model based on Ergodic Sequential Logic Dynamics: Reproduction of Mammalian Nonlinear Sound Processing and Efficient FPGA Implementation. ISCAS 2023: 1-5 - [c77]Jiaying Lin, Ryuji Nagazawa, Kien Nguyen, Hiroo Sekiya, Hiroyuki Torikai, Mikio Hasegawa, Won-Joo Hwang:
Pavlovian Conditioning Modeling Using Wireless Spiking Neural Network. ISOCC 2023: 163-164 - [c76]Masaya Kudo, Hiroyuki Torikai:
A hardware-efficient wireless functional electrical stimulation system based on ergodic cellular automaton dynamics. ISOCC 2023: 169-170 - [c75]Shoma Sato, Hiroyuki Torikai:
Analyses of nonlinear transient phenomena of ergodic cellular automaton central pattern generator. ISOCC 2023: 227-228 - [c74]Jumpei Kamitoko, Hiroyuki Torikai:
A chopper-type mixed gait controller based on ergodic cellular automaton central pattern generator. ISOCC 2023: 231-232 - [c73]Yui Kishimoto, Hiroyuki Torikai:
A hardware-efficient FPGA cochlear model for next generation nonlinear cochlear implant. ISOCC 2023: 253-255 - [c72]Kengo Hosoi, Hiroyuki Torikai:
A learnable network of analog electronic neuron models for brain prosthetic implant. ISOCC 2023: 255-256 - 2022
- [j44]Sho Komaki, Kentaro Takeda, Hiroyuki Torikai:
A Novel Ergodic Discrete Difference Equation Model of Central Pattern Generator: Theoretical Analysis and Efficient Implementation. IEEE Trans. Circuits Syst. II Express Briefs 69(3): 1767-1771 (2022) - [c71]Shogo Shirafuji, Hiroyuki Torikai:
A novel ergodic cellular automaton gene network model towards efficient hardware-based genome simulator. EMBC 2022: 2232-2235 - [c70]Itsuki Kubota, Kentaro Takeda, Hiroyuki Torikai:
A novel ergodic cellular automaton cochlear model: reproduction of nonlinear sound processing functions of mammalian cochlea and efficient hardware implementation. IJCNN 2022: 1-8 - [c69]Haruto Suzuki, Hiroyuki Torikai:
A Novel Hardware-Efficient Network of Ergodic Cellular Automaton Neuron Models and its On-FPGA Learning. ISCAS 2022: 2266-2270 - [c68]Yui Kishimoto, Hiroyuki Torikai:
Pitch-Shift Effects of an Ergodic Sequential Logic Nonlinear Cochlear Model Induced by Three Tones. ISOCC 2022: 265-266 - [c67]Shogo Shirafuji, Hiroyuki Torikai:
A hardware-efficient sequential logic biochemical switch model toward biosystem simulator. ISOCC 2022: 275 - [c66]Yuta Shiomi, Hiroyuki Torikai:
A hardware-efficient ergodic sequential logic neuron network for brain prosthetic FPGA. ISOCC 2022: 276-277 - [c65]Ryuji Nagazawa, Kien Nguyen, Hiroo Sekiya, Hiroyuki Torikai:
Reduction of Processing Time for Wireless Spiking Neural Network Using Wireless Communication Devices for IoT. ISOCC 2022: 278-279 - 2021
- [j43]Kentaro Takeda, Hiroyuki Torikai:
Two-tone distortion products in hardware-efficient cochlea model based on asynchronous cellular automaton oscillator. IEICE Electron. Express 18(18): 20210310 (2021) - [j42]Kentaro Takeda, Hiroyuki Torikai:
A Novel Hardware-Oriented Recurrent Network of Asynchronous CA Neurons for a Neural Integrator. IEEE Trans. Circuits Syst. II Express Briefs 68(8): 2972-2976 (2021) - [c64]Sho Komaki, Kentaro Takeda, Hiroyuki Torikai:
A novel asynchronous sequential logic model of central pattern generator for quadruped robot: systematic design and efficient implementation. IJCNN 2021: 1-8 - 2020
- [j41]Kentaro Takeda, Hiroyuki Torikai:
A Novel Hardware-Efficient Central Pattern Generator Model Based on Asynchronous Cellular Automaton Dynamics for Controlling Hexapod Robot. IEEE Access 8: 139609-139624 (2020) - [j40]Kentaro Takeda, Hiroyuki Torikai:
A Novel Asynchronous CA Neuron Model: Design of Neuron-Like Nonlinear Responses Based on Novel Bifurcation Theory of Asynchronous Sequential Logic Circuit. IEEE Trans. Circuits Syst. I Regul. Pap. 67-I(6): 1989-2001 (2020) - [c63]Masato Ishikawa, Hiroyuki Torikai:
A Novel Design Method of Multi-Compartment Soma-Dendrite-Spine Model having Nonlinear Asynchronous CA Dynamics and its Applications to STDP-based Learning and FPGA Implementation. IJCNN 2020: 1-8 - [c62]Kentaro Takeda, Hiroyuki Torikai:
A novel hardware-efficient CPG model based on asynchronous coupling of cellular automaton phase oscillators for a hexapod robot. IJCNN 2020: 1-8
2010 – 2019
- 2019
- [j39]Taiki Naka, Hiroyuki Torikai:
A Novel Generalized Hardware-Efficient Neuron Model Based on Asynchronous CA Dynamics and Its Biologically Plausible On-FPGA Learnings. IEEE Trans. Circuits Syst. II Express Briefs 66-II(7): 1247-1251 (2019) - [c61]Ryuya Hiraoka, Kazuki Matsumoto, Kien Nguyen, Hiroyuki Torikai, Hiroo Sekiya:
Implementation of Spiking Neural Network with Wireless Communications. ICONIP (5) 2019: 619-626 - [c60]Kentaro Takeda, Hiroyuki Torikai:
A novel hardware-efficient CPG model for a hexapod robot based on nonlinear dynamics of coupled asynchronous cellular automaton oscillators. IJCNN 2019: 1-8 - 2018
- [j38]Kentaro Takeda, Hiroyuki Torikai:
A novel hardware-efficient CPG model based on asynchronous cellular automaton. IEICE Electron. Express 15(11): 20180387 (2018) - [j37]Chiaki Matsuda, Hiroyuki Torikai:
A Novel Generalized PWC Neuron Model: Theoretical Analyses and Efficient Design of Bifurcation Mechanisms of Bursting. IEEE Trans. Circuits Syst. II Express Briefs 65-II(11): 1738-1742 (2018) - [c59]Kazuki Matsumoto, Hiroyuki Torikai, Hiroo Sekiya:
XOR learning by spiking neural network with infrared communications. APSIPA 2018: 1289-1292 - [c58]Kentaro Takeda, Hiroyuki Torikai:
A novel hardware-efficient spiking neuron model based on asynchronous cellular automaton dynamics exhibiting various nonlinear response curves. IJCNN 2018: 1-8 - 2017
- [j36]Kentaro Takeda, Hiroyuki Torikai:
A Novel Hardware-Efficient Cochlea Model Based on Asynchronous Cellular Automaton Dynamics: Theoretical Analysis and FPGA Implementation. IEEE Trans. Circuits Syst. II Express Briefs 64-II(9): 1107-1111 (2017) - [c57]Chiaki Matsuda, Hiroyuki Torikai:
A Novel Design Method of Burst Mechanisms of a Piece-Wise Constant Neuron Model Based on Bifurcation Analysis. ICONIP (6) 2017: 796-803 - [c56]Kentaro Takeda, Hiroyuki Torikai:
A Novel Hardware-Efficient CPG Model Based on Nonlinear Dynamics of Asynchronous Cellular Automaton. ICONIP (6) 2017: 812-820 - [c55]Ryota Araki, Hiroyuki Torikai, Takuya Yoshimoto:
A novel gene network model based on nonlinear dynamics of asynchronous cellular automaton. IJCNN 2017: 4488-4495 - 2016
- [j35]Kanata Isobe, Hiroyuki Torikai:
A Novel Hardware-Efficient Asynchronous Cellular Automaton Model of Spike-Timing-Dependent Synaptic Plasticity. IEEE Trans. Circuits Syst. II Express Briefs 63-II(6): 603-607 (2016) - [j34]Takashi Matsubara, Hiroyuki Torikai:
An Asynchronous Recurrent Network of Cellular Automaton-Based Neurons and Its Reproduction of Spiking Neural Network Activities. IEEE Trans. Neural Networks Learn. Syst. 27(4): 836-852 (2016) - [c54]Narutoshi Jodai, Hiroyuki Torikai:
A hardware-efficient multi-compartment soma-dendrite model based on asynchronous cellular automaton dynamics. IJCNN 2016: 219-226 - 2015
- [j33]Masato Izawa, Hiroyuki Torikai:
Asynchronous Cellular Automaton Model of Spiral Ganglion Cell in the Mammalian Cochlea: Theoretical Analyses and FPGA Implementation. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 98-A(2): 684-699 (2015) - [j32]Takashi Matsubara, Hiroyuki Torikai, Tetsuya Shimokawa, Kenji Leibnitz, Ferdinand Peper:
A Novel Double Oscillation Model for Prediction of fMRI BOLD Signals without Detrending. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 98-A(9): 1924-1936 (2015) - [j31]Naoki Shimada, Hiroyuki Torikai:
A Novel Asynchronous Cellular Automaton Multicompartment Neuron Model. IEEE Trans. Circuits Syst. II Express Briefs 62-II(8): 776-780 (2015) - [c53]Masato Izawa, Hiroyuki Torikai:
A novel hardware-efficient cochlea model based on asynchronous cellular automaton. IJCNN 2015: 1-8 - [c52]Yasushi Iwatani, Hiroyuki Torikai:
Flame extinguishment by cooperation of two aerial extinguishers. SII 2015: 534-539 - 2014
- [j30]Yutaro Yamashita, Hiroyuki Torikai:
Theoretical Analysis for Efficient Design of a Piecewise Constant Spiking Neuron Model. IEEE Trans. Circuits Syst. II Express Briefs 61-II(1): 54-58 (2014) - [c51]Masato Izawa, Hiroyuki Torikai:
Nonlinear responses of an asynchronous cellular automaton model of spiral ganglion cell. IJCNN 2014: 2483-2490 - [c50]Naoki Shimada, Hiroyuki Torikai:
Reproduction of forward and backward propagations on dendrites by multi-compartment asynchronous cell automaton neuron. IJCNN 2014: 2496-2503 - [c49]Takashi Matsubara, Hiroyuki Torikai, Tetsuya Shimokawa, Kenji Leibnitz, Ferdinand Peper:
A nonlinear model of fMRI BOLD signal including the trend component. IJCNN 2014: 2579-2586 - [c48]Satoshi Ogawa, Shinya Kudo, Masahiro Koide, Hiroyuki Torikai, Yasushi Iwatani:
Development and control of an aerial extinguisher with an inert gas capsule. ROBIO 2014: 1320-1325 - 2013
- [j29]Takumi Uramoto, Hiroyuki Torikai:
A Calcium-Based Simple Model of Multiple Spike Interactions in Spike-Timing-Dependent Plasticity. Neural Comput. 25(7): 1853-1869 (2013) - [j28]Takuya Noguchi, Hiroyuki Torikai:
Ghost Stochastic Resonance From an Asynchronous Cellular Automaton Neuron Model. IEEE Trans. Circuits Syst. II Express Briefs 60-II(2): 111-115 (2013) - [j27]Takashi Matsubara, Hiroyuki Torikai:
Asynchronous Cellular Automaton-Based Neuron: Theoretical Analysis and On-FPGA Learning. IEEE Trans. Neural Networks Learn. Syst. 24(5): 736-748 (2013) - [c47]Takashi Matsubara, Hiroyuki Torikai:
A novel reservoir network of asynchronous cellular automaton based neurons for MIMO neural system reproduction. IJCNN 2013: 1-7 - 2012
- [j26]Yutaro Yamashita, Hiroyuki Torikai:
A Generalized PWC Spiking Neuron Model and Its Neuron-Like Activities and Burst-Related Bifurcations. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 95-A(7): 1125-1135 (2012) - [j25]Takashi Matsubara, Hiroyuki Torikai:
Neuron-Like Responses and Bifurcations of a Generalized Asynchronous Sequential Logic Spiking Neuron Model. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 95-A(8): 1317-1328 (2012) - [j24]Yutaro Yamashita, Hiroyuki Torikai:
A Novel PWC Spiking Neuron Model: Neuron-Like Bifurcation Scenarios and Responses. IEEE Trans. Circuits Syst. I Regul. Pap. 59-I(11): 2678-2691 (2012) - [c46]Takashi Matsubara, Hiroyuki Torikai:
A Novel Bifurcation-Based Synthesis of Asynchronous Cellular Automaton Based Neuron. ICANN (1) 2012: 231-238 - [c45]Takashi Matsubara, Hiroyuki Torikai:
A generalized asynchronous digital spiking neuron: Theoretical analysis and compartmental model. IJCNN 2012: 1-8 - [c44]Yutaro Yamashita, Hiroyuki Torikai:
Bursting analysis and synapse mechanism of a piece-wise constant spiking neuron model. IJCNN 2012: 1-8 - [c43]Takumi Uramoto, Hiroyuki Torikai:
A calcium-based simplified model for a large diversity of spike-timing dependent plasticity. SCIS&ISIS 2012: 1447-1450 - 2011
- [j23]Kai Kinoshita, Hiroyuki Torikai:
A Self-Organizing Pulse-Coupled Network of Sub-Threshold Oscillating Spiking Neurons. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 94-A(1): 300-314 (2011) - [j22]Hirofumi Ijichi, Hiroyuki Torikai:
Analysis of m: n Lockings from Pulse-Coupled Asynchronous Sequential Logic Spiking Neurons. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 94-A(11): 2384-2393 (2011) - [j21]Takashi Matsubara, Hiroyuki Torikai, Tetsuya Hishiki:
A Generalized Rotate-and-Fire Digital Spiking Neuron Model and Its On-FPGA Learning. IEEE Trans. Circuits Syst. II Express Briefs 58-II(10): 677-681 (2011) - [j20]Tetsuya Hishiki, Hiroyuki Torikai:
A Novel Rotate-and-Fire Digital Spiking Neuron and its Neuron-Like Bifurcations and Responses. IEEE Trans. Neural Networks 22(5): 752-767 (2011) - [c42]Takashi Matsubara, Hiroyuki Torikai:
Dynamic Response Behaviors of a Generalized Asynchronous Digital Spiking Neuron Model. ICONIP (3) 2011: 395-404 - [c41]Yutaro Yamashita, Hiroyuki Torikai:
Generalized PWC Analog Spiking Neuron Model and Reproduction of Fundamental Neurocomputational Properties. ICONIP (3) 2011: 405-415 - [c40]Yutaro Yamashita, Hiroyuki Torikai:
A novel piece-wise constant analog spiking neuron model and its neuron-like excitabilities. IJCNN 2011: 717-724 - [c39]Takashi Matsubara, Hiroyuki Torikai:
A novel asynchronous digital spiking neuron model and its various neuron-like bifurcations and responses. IJCNN 2011: 741-748 - 2010
- [j19]Tetsuro Iguchi, Akira Hirata, Hiroyuki Torikai:
Theoretical and Heuristic Synthesis of Digital Spiking Neurons for Spike-Pattern-Division Multiplexing. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 93-A(8): 1486-1496 (2010) - [j18]Sho Hashimoto, Hiroyuki Torikai:
A Novel Hybrid Spiking Neuron: Bifurcations, Responses, and On-Chip Learning. IEEE Trans. Circuits Syst. I Regul. Pap. 57-I(8): 2168-2181 (2010) - [c38]Hirofumi Ijichi, Hiroyuki Torikai:
Theoretical Analysis of Various Synchronizations in Pulse-Coupled Digital Spiking Neurons. ICONIP (1) 2010: 107-115 - [c37]Tetsuya Hishiki, Hiroyuki Torikai:
Neural behaviors and nonlinear dynamics of a rotate-and-fire digital spiking neuron. IJCNN 2010: 1-8 - [c36]Tetsuro Iguchi, Akira Hirata, Hiroyuki Torikai:
Integrate-and-fire-type digital spiking neuron and its learning for spike-pattern-division multiplex communication. IJCNN 2010: 1-8
2000 – 2009
- 2009
- [j17]Hiroyuki Torikai, Toru Nishigami:
Response of a Chaotic Spiking Neuron to Various Periodic Inputs and Its Potential Applications. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 92-A(8): 2053-2060 (2009) - [j16]Hiroyuki Torikai, Toru Nishigami:
An artificial chaotic spiking neuron inspired by spiral ganglion cell: Paralleled spike encoding, theoretical analysis, and electronic circuit implementation. Neural Networks 22(5-6): 664-673 (2009) - [c35]Kai Kinoshita, Hiroyuki Torikai:
A Pulse-Coupled Network of SOM. ICONIP (2) 2009: 367-375 - [c34]Tetsuya Hishiki, Hiroyuki Torikai:
Bifurcation Analysis of a Resonate-and-Fire-Type Digital Spiking Neuron. ICONIP (2) 2009: 392-400 - [c33]Sho Hashimoto, Hiroyuki Torikai:
Bifurcation analysis of a reconfigurable hybrid spiking neuron and its novel online learning algorithm. IJCNN 2009: 1134-1141 - [c32]Hiroyuki Torikai, Toru Nishigami:
A novel chaotic spiking neuron and its paralleled spike encoding function. IJCNN 2009: 3132-3139 - 2008
- [j15]Hiroyuki Torikai, Aya Tanaka, Toshimichi Saito:
Artificial Spiking Neurons and Analog-to-Digital-to-Analog Conversion. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 91-A(6): 1455-1462 (2008) - [j14]Hiroyuki Torikai, Atsuo Funew, Toshimichi Saito:
Digital spiking neuron and its learning for approximation of various spike-trains. Neural Networks 21(2-3): 140-149 (2008) - [c31]Sho Hashimoto, Hiroyuki Torikai:
A Novel Hybrid Spiking Neuron: Response Analysis and Learning Potential. ICONIP (1) 2008: 145-152 - [c30]Hiroyuki Torikai, Toru Nishigami:
A Novel Artificial Model of Spiral Ganglion Cell and Its Spike-Based Encoding Function. ICONIP (1) 2008: 208-215 - [c29]Hiroyuki Torikai, Sho Hashimoto:
A hardware-oriented learning algorithm for a digital spiking neuron. IJCNN 2008: 2472-2479 - 2007
- [j13]Takahiro Kabe, Sukanya Parui, Hiroyuki Torikai, Soumitro Banerjee, Toshimichi Saito:
Analysis of Piecewise Constant Models of Current Mode Controlled DC-DC Converters. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 90-A(2): 448-456 (2007) - [j12]Masaru Takanashi, Hiroyuki Torikai, Toshimichi Saito:
An Approach to Collaboration of Growing Self-Organizing Maps and Adaptive Resonance Theory Maps. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 90-A(9): 2047-2050 (2007) - [j11]Hiroyuki Torikai:
Basic Characteristics and Learning Potential of a Digital Spiking Neuron. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 90-A(10): 2093-2100 (2007) - [j10]Toshimichi Saito, Takahiro Kabe, Yuki Ishikawa, Yusuke Matsuoka, Hiroyuki Torikai:
Piecewise Constant Switched Dynamical Systems in Power Electronics. Int. J. Bifurc. Chaos 17(10): 3373-3386 (2007) - [j9]Satoshi Akatsu, Hiroyuki Torikai, Toshimichi Saito:
Zero-Cross Instantaneous State Setting for Control of a Bifurcating H-Bridge inverter. Int. J. Bifurc. Chaos 17(10): 3571-3575 (2007) - [c28]Hiroyuki Torikai:
Fundamental Analysis of a Digital Spiking Neuron for Its Spike-Based Coding. ICONIP (2) 2007: 87-96 - [c27]Hiroyuki Torikai, Atsuo Funew, Toshimichi Saito:
Approximation of Spike-trains by Digital Spiking Neuron. IJCNN 2007: 2677-2682 - [c26]Tomohiro Inagaki, Toshimichi Saito, Hiroyuki Torikai:
Response of chaotic spiking circuit to periodic/nonperiodic inputs. IJCNN 2007: 2718-2722 - 2006
- [j8]Hiroyuki Torikai, Hiroshi Hamanaka, Toshimichi Saito:
Reconfigurable Digital Spiking Neuron and Its Pulse-Coupled Network: Basic Characteristics and Potential Applications. IEEE Trans. Circuits Syst. II Express Briefs 53-II(8): 734-738 (2006) - [j7]Hiroshi Hamanaka, Hiroyuki Torikai, Toshimichi Saito:
Quantized Spiking Neuron With A/D Conversion Functions. IEEE Trans. Circuits Syst. II Express Briefs 53-II(10): 1049-1053 (2006) - [c25]Takashi Yamamich, Toshimichi Saito, Hiroyuki Torikai:
Genetic Learning of Digital Three-Layer Perceptrons for Implementation of Binary Cellular Automata. IEEE Congress on Evolutionary Computation 2006: 2952-2957 - [c24]Tetsunari Oshime, Toshimichi Saito, Hiroyuki Torikai:
ART-Based Parallel Learning of Growing SOMs and Its Application to TSP. ICONIP (1) 2006: 1004-1011 - [c23]Takahiro Kabe, Hiroyuki Torikai, Toshimichi Saito:
Synchronization Via Multiplex Spike-Trains in Digital Pulse Coupled Networks. ICONIP (3) 2006: 1141-1149 - [c22]Hiroyuki Torikai, Yoshiaki Shimizu, Toshimichi Saito:
Various spike-trains from a digital spiking neuron: analysis of inter-spike intervals and their modulation. IJCNN 2006: 3860-3867 - [c21]Satoshi Akatsu, Hiroyuki Torikai, Toshimichi Saito:
Current-mode instantaneous state setting method and its application to an H-bridge inverter. ISCAS 2006 - [c20]Yusuke Matsuoka, Toshimichi Saito, Hiroyuki Torikai:
Complicated superstable behavior in a piecewise constant circuit with impulsive switching. ISCAS 2006 - [c19]Aya Tanaka, Hiroyuki Torikai, Toshimichi Saito:
A/D and D/A converters by spike-interval modulation of simple spiking neurons. ISCAS 2006 - 2005
- [j6]Hiroshi Hamanaka, Hiroyuki Torikai, Toshimichi Saito:
Analysis of Composite Dynamics of Two Bifurcating Neurons. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 88-A(2): 561-567 (2005) - [j5]Yoshio Kon'no, Toshimichi Saito, Hiroyuki Torikai:
Rich dynamics of pulse-coupled spiking neurons with a triangular base signal. Neural Networks 18(5-6): 523-531 (2005) - [j4]Toshimichi Saito, Shintaro Tasaki, Hiroyuki Torikai:
Interleaved Buck Converters Based on Winner-Take-All Switching. IEEE Trans. Circuits Syst. I Regul. Pap. 52-I(8): 1666-1672 (2005) - [c18]Yoshio Kon'no, Toshimichi Saito, Hiroyuki Torikai:
Rich spike-synchronization phenomena of pulse-coupled bifurcating neurons. ISCAS (3) 2005: 1927-1931 - [c17]Yusuke Matsuoka, Toshimichi Saito, Hiroyuki Torikai:
A piecewise constant switched chaotic circuit with rect-rippling return maps. ISCAS (4) 2005: 3411-3414 - 2004
- [j3]Hiroyuki Torikai, Toshimichi Saito:
Synchronization phenomena in pulse-coupled networks driven by spike-train inputs. IEEE Trans. Neural Networks 15(2): 337-347 (2004) - [c16]Hiroshi Hamanaka, Hiroyuki Torikai, Toshimichi Saito:
A Spiking Oscillator with Quantized State and Its Pulse Coding Characteristics. ICONIP 2004: 1123-1128 - [c15]Hiroshi Hamanaka, Hiroyuki Torikai, Toshimichi Saito:
Spike position map with quantized state and its application to algorithmic A/D converter. ISCAS (4) 2004: 673-676 - [c14]Hiroyuki Torikai, Hiroshi Hamanaka, Toshimichi Saito:
Pulse Codings of a Spiking Neuron Having Quantized State. KES 2004: 1002-1009 - 2002
- [j2]Toshimichi Saito, Fumitaka Komatsu, Hiroyuki Torikai:
Superstable Synchronous Phenomena of Switch-Coupled Relaxation Oscillators. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 85-A(10): 2318-2325 (2002) - [j1]Hiroyuki Torikai, Toshimichi Saito, Yoshinobu Kawasaki:
Analysis of a Quantized Chaotic System. Int. J. Bifurc. Chaos 12(5): 1207-1218 (2002) - [c13]Toshimichi Saito, M. Yoshizawa, Hiroyuki Torikai, Shintaro Tazaki:
Analysis of interleaved converters with WTA-based switching. ISCAS (3) 2002: 405-408 - [c12]Hiroshi Imamura, Toshimichi Saito, Hiroyuki Torikai:
An analog-to-digital converter with time-variant window. ISCAS (1) 2002: 505-508 - 2001
- [c11]Yoshinobu Kawasaki, Toshimichi Saito, Hiroyuki Torikai:
Quantized chaotic dynamics and communications systems. ISCAS (3) 2001: 133-136 - [c10]Fumitaka Komatsu, Hiroyuki Torikai, Toshimichi Saito:
Various superstable synchronous phenomena in switch-coupled relaxation oscillators. ISCAS (3) 2001: 696-699 - 2000
- [c9]Hiroyuki Torikai, Toshimichi Saito:
Pulse-Coupled Networks of Non-Autonomous Integrate-and-Fire Oscillators and Classification Functions. IJCNN (3) 2000: 291-295 - [c8]Fumitaka Komatsu, Hiroyuki Torikai, Toshimichi Saito:
A network of relaxation oscillators based on intermittently coupled capacitors. ISCAS 2000: 487-490 - [c7]Toshimichi Saito, Hiroyuki Torikai, Yoshikazu Nomoto:
A buck-boost converter controlled by periodic inputs. ISCAS 2000: 507-510 - [c6]Gousuke Izawa, Toshimichi Saito, Hiroyuki Torikai:
A dependent switched capacitor A/D converter for Farey series approximation. ISCAS 2000: 681-684
1990 – 1999
- 1999
- [c5]Hiroyuki Torikai, Toshimichi Saito:
Integrate-and-fire model with periodic inputs. IJCNN 1999: 717-720 - [c4]F. Komatsu, Hiroyuki Torikai, Toshimichi Saito:
A chaotic network based on intermittently coupled capacitors. ISCAS (5) 1999: 414-417 - 1998
- [c3]Hiroyuki Torikai, Toshimichi Saito:
Chaotic pulse-train separation and multiplex communication. ICECS 1998: 115-118 - 1995
- [c2]Hiroyuki Torikai, Toshimichi Saito:
Spatiotemporal pattern generation by control and synchronization of chaos. ICNN 1995: 1574-1577 - [c1]Toshimichi Saito, Hiroyuki Torikai, Kenya Jin'no:
Synchronization and Control of Chaos by Occasional Linear Connection. ISCAS 1995: 1013-1016
Coauthor Index
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