. . "8718" . "10.1080/00207160.2013.766332" . "Zhyrova, Anna" . . . . . "RIV/60076658:12520/14:43886877!RIV15-MSM-12520___" . . . "GB - Spojen\u00E9 kr\u00E1lovstv\u00ED Velk\u00E9 Brit\u00E1nie a Severn\u00EDho Irska" . "12520" . . "0020-7160" . . "000332146900002" . "10"^^ . "http://www.tandfonline.com/doi/abs/10.1080/00207160.2013.766332#.VKqdcHtlw80" . . "[E46468EA904F]" . "Construction of the phenomenological model of Belousov- Zhabotinsky reaction state trajectory" . . . "Zhyrova, Anna" . "trajectory; state; reaction; Zhabotinsky; Belousov-; model; phenomenological; the; Construction"@en . "1" . "P(ED2.1.00/01.0024), S" . . "\u0160tys, Dalibor" . "Construction of the phenomenological model of Belousov- Zhabotinsky reaction state trajectory"@en . . . "The Belousov-Zhabotinsky reaction is used as an example of a self-organizing system which is easily and intelligibly observable, and experimentally accessible. The analysis does not require elaborate reconstruction of series of three-dimensional images as in the case of bird flocks, fish schools or organ behaviour. The analysis of living cells microscopic image series is even more elaborate. Moreover, the experimenter in the case of the chemical clock has full control of the mechanical constraints imposed on the system. In this, contributions are reported using both experimental and theoretical results of the BZ reaction as an experimental tool for the analysis of behaviour of the self-organizing system. We have created a state trajectory using several selected image identifiers (point information gain entropy - Halfa). The Halfa values define an approximate state space which may be analysed using multivariate analysis. In this report we provide results of this analysis." . . "Construction of the phenomenological model of Belousov- Zhabotinsky reaction state trajectory" . "91" . "RIV/60076658:12520/14:43886877" . . "2"^^ . . "The Belousov-Zhabotinsky reaction is used as an example of a self-organizing system which is easily and intelligibly observable, and experimentally accessible. The analysis does not require elaborate reconstruction of series of three-dimensional images as in the case of bird flocks, fish schools or organ behaviour. The analysis of living cells microscopic image series is even more elaborate. Moreover, the experimenter in the case of the chemical clock has full control of the mechanical constraints imposed on the system. In this, contributions are reported using both experimental and theoretical results of the BZ reaction as an experimental tool for the analysis of behaviour of the self-organizing system. We have created a state trajectory using several selected image identifiers (point information gain entropy - Halfa). The Halfa values define an approximate state space which may be analysed using multivariate analysis. In this report we provide results of this analysis."@en . "INTERNATIONAL JOURNAL OF COMPUTER MATHEMATICS" . "2"^^ . . "Construction of the phenomenological model of Belousov- Zhabotinsky reaction state trajectory"@en . . .