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ORCIDTakashi Kohno
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2020 – today
- 2024
[j28]Jérémy Cheslet, Romain Beaubois, Tomoya Duenki, Farad Khoyratee, Takashi Kohno, Yoshiho Ikeuchi, Timothée Levi:
Biomimetic snake locomotion using central pattern generators network and bio-hybrid robot perspective. Artif. Life Robotics 29(4): 479-485 (2024)- [c7]Ashish Gautam, Takashi Kohno, Prasanna Date, Robert M. Patton, Thomas E. Potok:
A Suppression-based STDP Rule Resilient to Jitter Noise in Spike Patterns for Neuromorphic Computing. ICONS 2024: 209-216 - [i1]Sai Deepesh Pokala, Marie Bernert, Takuya Nanami, Takashi Kohno, Timothée Levi, Blaise Yvert:
A frugal Spiking Neural Network for unsupervised classification of continuous multivariate temporal data. CoRR abs/2408.12608 (2024) - 2023
- [j27]Takuya Nanami, Takashi Kohno:
Improving Performance of Spike Pattern Detection Using Close-to-Biology Spiking Neuronal Network. J. Robotics Netw. Artif. Life 10(1): 66-70 (2023) - [j26]Ashish Gautam, Takashi Kohno:
Competitive Spike Pattern Detection for Neuromorphic systems. J. Robotics Netw. Artif. Life 10(2): 204-212 (2023) - [c6]Jérémy Cheslet, Romain Beaubois
, Ulysse Rançon, Landry Bailly, Marie Bernert, Takashi Kohno, Blaise Yvert, Timothée Levi:
FPGA implementation of a Spiking Neural Network for Real-Time Action Potential and Burst Detection. BioCAS 2023: 1-5 - 2022
- [c5]Tomoharu Kiyuna, Noriko Motoi, Hiroshi Yoshida, Hidehito Horinouchi, Tatsuya Yoshida, Takashi Kohno, Shun-ichi Watanabe, Yuichiro Ohe, Atsushi Ochiai:
Drug response prediction using deep neural network trained by adaptive resampling of histopathological images. Computer-Aided Diagnosis 2022 - 2020
- [j25]Jason Kamran Eshraghian, Seungbum Baek, Timothée Levi, Takashi Kohno, Said F. Al-Sarawi, Philip H. W. Leong, Kyoung-Rok Cho, Derek Abbott, Omid Kavehei:
Nonlinear retinal response modeling for future neuromorphic instrumentation. IEEE Instrum. Meas. Mag. 23(1): 21-29 (2020) - [j24]Ashish Gautam, Takashi Kohno:
Biomimetic Analog Silicon Synaptic Circuit with Tunable Reversal Potential. J. Robotics Netw. Artif. Life 7(1): 22-26 (2020) - [j23]Naruaki Takano, Takashi Kohno:
Neuromorphic Computing in Autoassociative Memory with a Regular Spiking Neuron Model. J. Robotics Netw. Artif. Life 7(1): 63-67 (2020) - [j22]Yang Xia, Timothée Levi, Takashi Kohno:
Digital Hardware Spiking Neuronal Network with STDP for Real-time Pattern Recognition. J. Robotics Netw. Artif. Life 7(2): 121-124 (2020)
2010 – 2019
- 2018
- [j21]Filippo Grassia, Timothée Levi, E. Doukkali, Takashi Kohno:
Spike pattern recognition using artificial neuron and spike-timing-dependent plasticity implemented on a multi-core embedded platform. Artif. Life Robotics 23(2): 200-204 (2018) - [j20]Timothée Levi, Yanchen Guo, Kazuyuki Aihara, Takashi Kohno:
Study of real-time biomimetic CPG on FPGA: behavior and evolution. J. Robotics Netw. Artif. Life 4(4): 299-302 (2018) - [j19]Takuya Nanami, Filippo Grassia, Takashi Kohno:
A Metaheuristic Approach for Parameter Fitting in Digital Spiking Silicon Neuron Model. J. Robotics Netw. Artif. Life 5(1): 32-36 (2018) - [j18]Atsuya Tange, Takashi Kohno:
Finding appropriate parameter voltages for driving a low-power analog silicon neuron circuit. J. Robotics Netw. Artif. Life 5(1): 71-74 (2018) - [j17]Timothée Levi, Takuya Nanami, Atsuya Tange, Kazuyuki Aihara, Takashi Kohno:
Development and Applications of Biomimetic Neuronal Networks Toward BrainMorphic Artificial Intelligence. IEEE Trans. Circuits Syst. II Express Briefs 65-II(5): 577-581 (2018) - 2017
- [j16]Ethan Green, Takashi Kohno:
A Multistage Heuristic Tuning Algorithm for an Analog Silicon Neuron Circuit. J. Robotics Netw. Artif. Life 4(1): 58-61 (2017) - [j15]Takuya Nanami, Filippo Grassia, Takashi Kohno:
A parameter optimization method for Digital Spiking Silicon Neuron model. J. Robotics Netw. Artif. Life 4(1): 97-101 (2017) - 2016
- [j14]Ethan Green, Takashi Kohno:
Compensating Temperature-Dependent Characteristics of a Subthreshold-MOSFET Analog Silicon Neuron. J. Robotics Netw. Artif. Life 2(4): 209-212 (2016) - [j13]Takuya Nanami, Takashi Kohno:
An FPGA-based cortical and thalamic silicon neuronal network. J. Robotics Netw. Artif. Life 2(4): 238-242 (2016) - 2015
- [j12]Yoshika Osawa, Takashi Kohno:
Associative Memory with Class I and II Izhikevich Model. J. Robotics Netw. Artif. Life 1(4): 312-315 (2015) - 2014
- [j11]Filippo Grassia, Timothée Levi, Takashi Kohno, Sylvain Saïghi:
Silicon neuron: digital hardware implementation of the quartic model. Artif. Life Robotics 19(3): 215-219 (2014) - [c4]Takashi Kohno, Kazuyuki Aihara:
A qualitative-modeling-based low-power silicon nerve membrane. ICECS 2014: 199-202 - 2013
- [j10]Takashi Kohno, Kazuyuki Aihara:
Improving noise resistance of intrinsic rhythms in a square-wave burster model. Biosyst. 112(3): 276-283 (2013) - 2012
- [j9]Filippo Grassia, Timothée Levi, Sylvain Saïghi, Takashi Kohno:
Bifurcation analysis in a silicon neuron. Artif. Life Robotics 17(1): 53-58 (2012) - 2011
- [j8]Nobuyuki Mizoguchi, Yuji Nagamatsu, Kazuyuki Aihara, Takashi Kohno:
A two-variable silicon neuron circuit based on the Izhikevich model. Artif. Life Robotics 16(3): 383-388 (2011) - [j7]Hitomu Saiki, Takanori Fukao, Takateru Urakubo, Takashi Kohno:
Hovering Control of Outdoor Blimp Robots Based on Path Following. J. Robotics Mechatronics 23(2): 207-214 (2011) - 2010
- [c3]Hitomu Saiki, Takanori Fukao, Takateru Urakubo, Takashi Kohno:
Hovering Control of Outdoor Blimp Robots based on Path Following. CCA 2010: 2124-2129
2000 – 2009
- 2009
- [c2]Hitomu Saiki, Takanori Fukao, Takashi Kohno:
Automatic Landing Control of Outdoor Blimp Robots. SyRoCo 2009: 32-37 - 2008
- [j6]Munehisa Sekikawa, Takashi Kohno, Kazuyuki Aihara:
An integrated circuit design of a silicon neuron and its measurement results. Artif. Life Robotics 13(1): 116-119 (2008) - [j5]Takashi Kohno, Kazuyuki Aihara:
Mathematical-model-based design of silicon burst neurons. Neurocomputing 71(7-9): 1619-1628 (2008) - 2007
- [j4]Takashi Takemoto, Takashi Kohno, Kazuyuki Aihara:
Circuit Implementation and Dynamics of a Two-Dimensional MOSFET Neuron Model. Int. J. Bifurc. Chaos 17(2): 459-508 (2007) - [j3]Takashi Kohno, Kazuyuki Aihara:
Bottom-up design of Class 2 silicon nerve membrane. J. Intell. Fuzzy Syst. 18(5): 465-475 (2007) - 2006
- [j2]Takashi Takemoto, Takashi Kohno, Kazuyuki Aihara:
MOSFET implementation of class I* neurons coupled by gap junctions. Artif. Life Robotics 10(1): 1-5 (2006) - 2005
- [j1]Takashi Kohno, Kazuyuki Aihara:
A MOSFET-based model of a class 2 nerve membrane. IEEE Trans. Neural Networks 16(3): 754-773 (2005) - [c1]Takashi Kohno:
Design of Neuromorphic Hardwares. CCA 2005: 377-378
Coauthor Index
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