We present a new algorithm for estimating parameters in reaction–diffusion systems that display pattern formation via the mechanism of diffusion-driven instability. A Modified Discrete Optimal Control Algorithm (MDOCA) is illustrated with the Schnakenberg and Gierer–Meinhardt reaction–diffusion systems using PDE constrained optimization techniques. The MDOCA algorithm is a modification of a standard variable step gradient algorithm that yields a huge saving in computational cost. The results of numerical experiments demonstrate that the algorithm accurately estimated key parameters associated with stationary target functions generated from the models themselves. Furthermore, the robustness of the algorithm was verified by performing experim...
In an attempt to describe how patterns emerge in biological systems, Alan Turing proposed a mathemat...
We consider the classical Turing instability in a reaction-diffusion system as the secend part of ou...
AbstractIn this paper we study the numerical approximation of Turing patterns corresponding to stead...
We present a new algorithm for estimating parameters in reaction–diffusion systems that display patt...
We present a new algorithm for estimating parameters in reaction-diffusion systems that display patt...
The Turing pattern formation is modeled by reaction-diffusion (RD) type partial differential equatio...
Turing patterns have been studied for over 50 years as a pattern forming mechanism. To date the curr...
State feedback is used to stabilize the Turing instability at the unstable equilibrium point of a di...
The paper presents a result about the number of distinct stationary solutions of a reaction-diffusio...
A new bio-inspired method for optimizing the objective function on a parallelepiped set of admissibl...
We investigate a suitable application of Model Order Reduction (MOR) techniques for the numerical ap...
The modelling of pattern formation in biological systems using various models of reaction-diffusion ...
The aim of the present review is to provide a comprehensive explanation of Turing reaction–diffusion...
The modelling of pattern formation in biological systems using various models of reaction-diffusion ...
Many biological processes can be described in terms of chemical reactions and diffusion. In this the...
In an attempt to describe how patterns emerge in biological systems, Alan Turing proposed a mathemat...
We consider the classical Turing instability in a reaction-diffusion system as the secend part of ou...
AbstractIn this paper we study the numerical approximation of Turing patterns corresponding to stead...
We present a new algorithm for estimating parameters in reaction–diffusion systems that display patt...
We present a new algorithm for estimating parameters in reaction-diffusion systems that display patt...
The Turing pattern formation is modeled by reaction-diffusion (RD) type partial differential equatio...
Turing patterns have been studied for over 50 years as a pattern forming mechanism. To date the curr...
State feedback is used to stabilize the Turing instability at the unstable equilibrium point of a di...
The paper presents a result about the number of distinct stationary solutions of a reaction-diffusio...
A new bio-inspired method for optimizing the objective function on a parallelepiped set of admissibl...
We investigate a suitable application of Model Order Reduction (MOR) techniques for the numerical ap...
The modelling of pattern formation in biological systems using various models of reaction-diffusion ...
The aim of the present review is to provide a comprehensive explanation of Turing reaction–diffusion...
The modelling of pattern formation in biological systems using various models of reaction-diffusion ...
Many biological processes can be described in terms of chemical reactions and diffusion. In this the...
In an attempt to describe how patterns emerge in biological systems, Alan Turing proposed a mathemat...
We consider the classical Turing instability in a reaction-diffusion system as the secend part of ou...
AbstractIn this paper we study the numerical approximation of Turing patterns corresponding to stead...