Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A new set of conditions is established that can be used to verify whether an existing network synchronizes or to give guidelines to construct a new synthetic network of biological oscillators that synchronize. The methodology uses the so-called contraction theory from dynamical system theory and Gershgorin disk theorem. The strategy is validated on two examples: a model of glycolisis in yeast cells and a synthetic network of repressilators that synchronizes
Abstract This paper presents four kinds of phase synchronization in oscillator networks by con-struc...
The principles of event-based control appear to be a backbone of many self-coordinating natural syst...
Networks of interacting biomolecules carry out many essential functions in living cells, but the ‘de...
Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A n...
Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A n...
Synchronization is a fundamental mechanism in biological networks: examples include networks of neur...
Exploration of chronobiological systems emerges as a growing research field within bioinformatics fo...
We define a subclass of timed automata, called oscillator timed automata, suitable to model biologic...
Living organisms often display rhythmic and oscillatory behavior. We investigate here a challenge in...
AbstractWe define a subclass of timed automata, called oscillator timed automata, suitable to model ...
Le cycle de division cellulaire et l'horloge circadienne sont deux processus fondamentaux de la régu...
Circadian timing is structured in such a way as to receive information from the external and interna...
International audienceThe intercellular interactions between peripheral circadian clocks, located in...
Diverse biochemical rhythms are generated by thousands of cellular oscillators that somehow manage t...
Two examples each representing a biological network under oscillating conditions and in equilibrium ...
Abstract This paper presents four kinds of phase synchronization in oscillator networks by con-struc...
The principles of event-based control appear to be a backbone of many self-coordinating natural syst...
Networks of interacting biomolecules carry out many essential functions in living cells, but the ‘de...
Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A n...
Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A n...
Synchronization is a fundamental mechanism in biological networks: examples include networks of neur...
Exploration of chronobiological systems emerges as a growing research field within bioinformatics fo...
We define a subclass of timed automata, called oscillator timed automata, suitable to model biologic...
Living organisms often display rhythmic and oscillatory behavior. We investigate here a challenge in...
AbstractWe define a subclass of timed automata, called oscillator timed automata, suitable to model ...
Le cycle de division cellulaire et l'horloge circadienne sont deux processus fondamentaux de la régu...
Circadian timing is structured in such a way as to receive information from the external and interna...
International audienceThe intercellular interactions between peripheral circadian clocks, located in...
Diverse biochemical rhythms are generated by thousands of cellular oscillators that somehow manage t...
Two examples each representing a biological network under oscillating conditions and in equilibrium ...
Abstract This paper presents four kinds of phase synchronization in oscillator networks by con-struc...
The principles of event-based control appear to be a backbone of many self-coordinating natural syst...
Networks of interacting biomolecules carry out many essential functions in living cells, but the ‘de...