Adjoint Method Provides Phase Response Functions for Delay-Induced Oscillations | Zendy

Kiyoshi Kotani | Zendy; Ikuhiro Yamaguchi | Zendy; Yutaro Ogawa | Zendy; Yasuhiko Jimbo | Zendy; Hiroya Nakao | Zendy; G. Bard Ermentrout | Zendy

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Adjoint Method Provides Phase Response Functions for Delay-Induced Oscillations

Author(s) -

Kiyoshi Kotani,

Ikuhiro Yamaguchi,

Yutaro Ogawa,

Yasuhiko Jimbo,

Hiroya Nakao,

G. Bard Ermentrout

Publication year - 2012

Publication title -

physical review letters

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 3.688

H-Index - 673

eISSN - 1079-7114

pISSN - 0031-9007

DOI - 10.1103/physrevlett.109.044101

Subject(s) - eigenfunction , limit (mathematics) , physics , phase (matter) , limit cycle , phase space , function (biology) , bilinear interpolation , mathematical analysis , statistical physics , mathematics , quantum mechanics , eigenvalues and eigenvectors , statistics , evolutionary biology , biology

Limit-cycle oscillations induced by time delay are widely observed in various systems, but a systematic phase-reduction theory for them has yet to be developed. Here we present a practical theoretical framework to calculate the phase response function Z(θ), a fundamental quantity for the theory, of delay-induced limit cycles with infinite-dimensional phase space. We show that Z(θ) can be obtained as a zero eigenfunction of the adjoint equation associated with an appropriate bilinear form for the delay differential equations. We confirm the validity of the proposed framework for two biological oscillators and demonstrate that the derived phase equation predicts intriguing multimodal locking behavior.

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