Committee 
Date Time 
Place 
Paper Title / Authors 
Abstract 
Paper # 
CCS 
20200325 14:20 
Tokyo 
Hosei Univ. Ichigaya Campus (Cancelled but technical report was issued) 
A quadruped robot controlled by an asynchronous cellular automaton CPG Shou Komaki, Hiroyuki Torikai (Hosei Univ) CCS201934 
In this paper, we present a CPG (Central Pattern Generator) based on an asynchronous cellular automaton. Adjusting the c... [more] 
CCS201934 pp.14 
CCS 
20200325 14:55 
Tokyo 
Hosei Univ. Ichigaya Campus (Cancelled but technical report was issued) 
[Invited Talk]
Design of neuromorphic and biomimetic hardware based on asynchronous cellular automaton
 Nonlinear theories of asynchronous discretestate dynamical systems and their applications  Hiroyuki Torikai (Hosei Univ.) 
[more] 

CCS 
20200326 10:00 
Tokyo 
Hosei Univ. Ichigaya Campus (Cancelled but technical report was issued) 
Nonlinear response of a cochlea model based on asynchronous cellular automaton Shun Onodera, Hiroyuki Torikai (Hosei Univ.) CCS201937 
In this paper, we consider nonlinear response characteristics of a cochlea model based on an asynchronous cellular autom... [more] 
CCS201937 pp.1316 
CCS 
20200326 10:25 
Tokyo 
Hosei Univ. Ichigaya Campus (Cancelled but technical report was issued) 
Chaotic burst of a piecewize constant neuron model Yutaro Watanabe, Hiroyuki torikai (Hosei Univ.) CCS201938 
In this study, we consider burst firing of a neuron model with a piecewise constant vector field. For example, we analyz... [more] 
CCS201938 pp.1720 
CCS 
20191115 09:55 
Hyogo 
Kobe Univ. 
Basics characteristics asynchronous discrete state reservoir Masato Ishikawa, Hiroyuki Torikai (Hosei Univ.) CCS201930 
This paper studies a neuron model (somadendritespine model), the dynamics of which is described by an asynchronous ce... [more] 
CCS201930 pp.2932 
CCS 
20181122 13:00 
Hyogo 
Kobe Univ. 
On bifurcation phenomena of a spiking neuron model based on asynchronous cellular automaton Kentaro Takeda (Kyoto Sangyo Univ.), Hiroyuki Torikai (Hosei Univ.) CCS201833 
[more] 
CCS201833 pp.15 
CCS 
20181122 13:25 
Hyogo 
Kobe Univ. 
On characteristics of an asynchronous cellular automaton reservoir Taiki Naka (Kyoto Sangyo Univ.), Hiroyuki Torikai (Hosei Univ.) CCS201834 
[more] 
CCS201834 pp.710 
CCS 
20181122 13:50 
Hyogo 
Kobe Univ. 
On bifurcation phenomena of a gene network model based on asynchronous cellular automaton Takuya Yoshimoto (Kyoto Sangyo Univ.), Hiroyuki Torikai (Hosei Univ.) CCS201835 
In this paper, we consider a modeling method of a gene network, which simulates dynamics of repair of DNA damage, using ... [more] 
CCS201835 pp.1115 
CCS 
20181122 14:55 
Hyogo 
Kobe Univ. 
Analyses of burst phenomena of a piecewise constant neuron model Chiaki Matsuda (Kyoto Sangyo Univ.), Hiroyuki Torikai (Hosei Univ.) CCS201837 
In this paper, a modified piecewise constant (PWC) neuron model is studied. There are various bifur cation phenomena a... [more] 
CCS201837 pp.2327 
IN, CCS (Joint) 
20180802 13:25 
Hokkaido 
Kitayuzawa MorinoSoraniwa 
XOR learning by spiking neural network with infrared communications Kazuki Matsumoto (Chiba Univ.), Hiroyuki Torikai (Hosei Univ.), Hiroo Sekiya (Chiba Univ.) CCS201831 
[more] 
CCS201831 pp.2528 
CCS 
20171110 11:00 
Osaka 
Osaka Univ. 
Design of Analog Electronic Circuit Neuron Model based on Bifurcations of Piecewise Constant Vector Field Chiaki Matsuda, Hiroyuki Torikai (Kyoto Sangyo Univ.) CCS201728 
A piecewise constant neuron model is an electronic circuit neuron model having a piecewise constant vector field. By a... [more] 
CCS201728 pp.3943 
CCS 
20171110 11:25 
Osaka 
Osaka Univ. 
On a Classification Function of an Asynchronous Cellular Automaton Spiking Neural Network Taiki Naka, Hiroyuki Torikai (Kyoto Sangyo Univ.) CCS201729 
In this paper, we consider a spike neural network consisting of asynchronous cellular automaton neurons, which has trans... [more] 
CCS201729 pp.4548 
CCS 
20171110 14:05 
Osaka 
Osaka Univ. 
On Analysis and Application of Coupled Asynchronous Cellular Automaton Oscillators Kentaro Takeda, Hiroyuki Torikai (Kyoto Sangyo Univ.) CCS201731 
In this paper, a central pattern generator (CPG) model coupled by asynchronous cellular automaton oscillators is investi... [more] 
CCS201731 pp.5559 
CCS 
20171110 14:30 
Osaka 
Osaka Univ. 
On a DNA Damage Model based on Asynchronous Cellular Automaton Yoshimoto Takuya, Hiroyuki Torikai (Kyoto Sangyo Univ.) CCS201732 
In this paper, we consider a modeling method of a gene network, which simulates dynamics triggered by DNA damage, using... [more] 
CCS201732 pp.6166 
CCS 
20161104 10:00 
Kyoto 
Kyoto Sangyo Univ. (Musubiwaza Bldg.) 
A HardwareEfficient Gene Network Model based on Asynchronous Bifurcation Processor Takuya Yoshimoto, Hiroyuki Torikai (Kyoto Sangyo Univ.) CCS201629 
[more] 
CCS201629 pp.14 
CCS 
20161104 13:30 
Kyoto 
Kyoto Sangyo Univ. (Musubiwaza Bldg.) 
A Hopf Cochlea Model based on Asynchronous Bifurcation Processor Kentaro Takeda, Hiroyuki Torikai (Kyoto Sangyo Univ.) CCS201633 
[more] 
CCS201633 pp.1721 
CCS 
20161104 15:30 
Kyoto 
Kyoto Sangyo Univ. (Musubiwaza Bldg.) 
A Hardware Neuron Model based on PieceWise Constant Vector Field Chiaki Matsuda, Hiroyuki Torikai (Kyoto Sangyo Univ.) CCS201637 
[more] 
CCS201637 pp.3740 
CCS 
20161105 10:00 
Kyoto 
Kyoto Sangyo Univ. (Musubiwaza Bldg.) 
Basic conditioning learning in a multicompartment neuron model based on asynchronous bifurcation processor Taiki Naka, Hiroyuki Torikai (Kyoto Sangyo Univ.) CCS201641 
[more] 
CCS201641 pp.5558 
NLP 
20160324 13:00 
Kyoto 
Kyoto Sangyo Univ. 
Analysis of basic characteristics of a network of neuron model based on asynchronous bifurcation processor Kanata Isobe, Hiroyuki Torikai (Kyoto Sangyo Univ.) NLP2015142 
A novel network of asynchronous cellular automaton neuron models with spike timing dependent plasticity and a dopamine m... [more] 
NLP2015142 pp.15 
NLP 
20160324 13:50 
Kyoto 
Kyoto Sangyo Univ. 
A gene network model based on asynchronous bifurcation processor Ryota Araki, Hiroyuki Torikai (Kyoto Sangyo Univ.) NLP2015144 
The gene affects various behaviors of animals such as circadian rhythm, courtship behavior, motor behavior, visual behav... [more] 
NLP2015144 pp.1115 