Synchronization control for circadian rhythm of Drosophila with flatness-based adaptive control

被引:0
|
作者
Kusumi, Tetsuya [1 ]
Ohmori, Hiromitsu [2 ]
机构
[1] Keio Univ, Grad Sch Sci & Technol, Kanagawa, Japan
[2] Keio Univ, Dept Syst Design Engn, Kanagawa 108, Japan
来源
PROCEEDINGS OF SICE ANNUAL CONFERENCE, VOLS 1-8 | 2007年
关键词
system biology; circadian rhythm; synchronization control; adaptive control; flatness-based control;
D O I
暂无
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
Recently, developing molecular biology and system biology, the mechanism of the circadian rhythm in which the inside of the body rhythm of the living thing is ruled is being clarified at the cell level. On the other hand, it is said that various sicknesses are related in the medicine and pharmacology to the disorder of the circadian rhythm. Therefore, it is thought that to restore an altered rhythm is a goal of these therapies. In this paper, we study the 10-states circadian model of Drosophila and propose a close-loop control based on flatness-based adaptive control to achieve circadian rhythm restoration.
引用
收藏
页码:1254 / +
页数:2
相关论文
共 50 条
  • [31] Flatness-based adaptive fuzzy control of brushless doubly-fed reluctance machines
    Rigatos, Gerasimos
    Siano, Pierluigi
    Ademi, Sul
    2017 IEEE 26TH INTERNATIONAL SYMPOSIUM ON INDUSTRIAL ELECTRONICS (ISIE), 2017, : 1913 - 1920
  • [32] Flatness-Based Control in Successive Loops for Autonomous Quadrotors
    Rigatos, G.
    Abbaszadeh, M.
    Busawon, K.
    Dala, L.
    Pomares, J.
    Zouari, F.
    JOURNAL OF DYNAMIC SYSTEMS MEASUREMENT AND CONTROL-TRANSACTIONS OF THE ASME, 2024, 146 (02):
  • [33] Nonlinear Flatness-Based Observer for Vehicle Dynamics Control
    Goeltz, Simon
    Ossig, Daniel L.
    Fu, Weixin
    Sawodny, Oliver
    IECON 2021 - 47TH ANNUAL CONFERENCE OF THE IEEE INDUSTRIAL ELECTRONICS SOCIETY, 2021,
  • [34] A Digital Flatness-based Control System of a DC Motor
    Ayadi, Mounir
    Haggege, Jospeh
    Bouallegue, Soufiene
    Benrejeb, Mohamed
    STUDIES IN INFORMATICS AND CONTROL, 2008, 17 (02): : 201 - 214
  • [35] Flatness-based adaptive fuzzy control of electrostatically actuated MEMS using output feedback
    Rigatos, G.
    Zhu, G.
    Yousef, H.
    Boulkroune, A.
    FUZZY SETS AND SYSTEMS, 2016, 290 : 138 - 157
  • [36] Flatness-based control of the separately excited DC drive
    Hagenmeyer, V
    Kohlrausch, P
    Delaleau, E
    NONLINEAR CONTROL IN THE YEAR 2000, VOL 1, 2000, 258 : 439 - 452
  • [37] Flatness-based feedback control of an automotive solenoid valve
    Chung, Soon K.
    Koch, Charles Robert
    Lynch, Alan F.
    IEEE TRANSACTIONS ON CONTROL SYSTEMS TECHNOLOGY, 2007, 15 (02) : 394 - 401
  • [38] Flatness-based clutch control for automated manual transmissions
    Horn, J
    Bamberger, J
    Michau, P
    Pindl, S
    CONTROL ENGINEERING PRACTICE, 2003, 11 (12) : 1353 - 1359
  • [39] Flatness-based control of electrostatically actuated MEMS with application to adaptive optics:: A simulation study
    Zhu, Guchuan
    Levine, Jean
    Praly, Laurent
    Peter, Yves-Alain
    JOURNAL OF MICROELECTROMECHANICAL SYSTEMS, 2006, 15 (05) : 1165 - 1174
  • [40] Flatness-based adaptive fuzzy output tracking excitation control for power system generators
    Yousef, Hassan A.
    Hamdy, Mohamed
    Shafiq, Muhammad
    JOURNAL OF THE FRANKLIN INSTITUTE-ENGINEERING AND APPLIED MATHEMATICS, 2013, 350 (08): : 2334 - 2353
12345