Communications of the ACM
Journal of Computer and System Sciences
Field-Programmable Gate Array Technology
Field-Programmable Gate Array Technology
Hypercomputation: hype or computation?
Communications of the ACM - Evolving data mining into solutions for insights
Artificial chemistries—a review
Artificial Life
Membrane Computing: An Introduction
Membrane Computing: An Introduction
Theoretical Computer Science - Natural computing
The Blob: A Basic Topological Concept for "Hardware-Free" Distributed Computation
UMC '02 Proceedings of the Third International Conference on Unconventional Models of Computation
Proceedings of the eighth international conference on Artificial life
ICAL 2003 Proceedings of the eighth international conference on Artificial life
A POEtic architecture for bio-inspired hardware
ICAL 2003 Proceedings of the eighth international conference on Artificial life
The creation of novelty in artificial chemistries
ICAL 2003 Proceedings of the eighth international conference on Artificial life
An Algorithm for Group Formation and Maximal Independent Set in an Amorphous Computer
An Algorithm for Group Formation and Maximal Independent Set in an Amorphous Computer
Paradigms for Structure in an Amorphous Computer
Paradigms for Structure in an Amorphous Computer
Programmable self-assembly: constructing global shape using biologically-inspired local interactions and origami mathematics
Proceedings of the 1st conference on Computing frontiers
POEtic tissue: an integrated architecture for bio-inspired hardware
ICES'03 Proceedings of the 5th international conference on Evolvable systems: from biology to hardware
Computation for metaphors, analogy, and agents
Computation for metaphors, analogy, and agents
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The quest for novel and unconventional computing machines is mainly motivated by the man-machine dichotomy and by the belief that dealing with new physical computing substrates, new environments, and new applications will require new paradigms to organize, train, program, and to interact with them. The goal of this contribution is to delineate a possible way to address the general scientific challenge of seeking for further progress and new metaphors in computer science by means of unconventional approaches. Here we outline an amalgamation of (1) a particle-based, randomly interconnected, and reconfigurable substrate, (2) membrane systems, and (3) artificial chemistries in combination with (4) an unconventional adaptation paradigm.