Chemical waves in modified membranes I: developing the technique
Physica D - Special issue originating from the international workshop on dynamism and regulation in nonlinear chemical systems
Feynman Lectures on Computation
Feynman Lectures on Computation
Reaction-Diffusion Computers
Simulating neurons in reaction-diffusion chemistry
IPCAT'12 Proceedings of the 9th international conference on Information Processing in Cells and Tissues
Slimeware: Engineering devices with slime mold
Artificial Life
Using transition systems to describe and predict the behaviour of structured excitable media
Natural Computing: an international journal
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There are many ways in which a nonlinear chemical medium can be used for information processing. Here we are concerned with an excitable medium and the straightforward method of information coding: a single excitation pulse represents a bit of information and a group of excitations forms a message. Our attention is focused on a specific type of nonhomogeneous medium that has an intentionally introduced geometrical structure of regions characterized by different excitability levels. We show that in information processing applications the geometry plays an equally important role as the dynamics of the medium and allows one to construct devices that perform complex signal processing operations even for a relatively simple kinetics of the reactions involved. In the paper we review a number of published chemical realizations of simple information processing devices like logical gates or memory cells and we show that by combining these devices as building blocks the medium can perform complex operations like for example counting of arriving excitations. We also present a new, simple realizations of chemical signal diode that transmits pulses in one direction only.