. Yoshii, S., Inayoshi, H. and Kakazu, Y.: Atomoid: A New Prospect in ReactionFormation System, Spontaneous Hypercycles Guided by Dissipative Structural Properties, Artificial Life V (1996) 383-390  Home/Search   Document Details and Download   Summary   Related Articles   Check

....this category, but in particular I am referring to work which is specifically looking at the ideas of self replication and autopoiesis within this environment. So far no one has actually created such a system in which complex and evolving unities emerge, maintain themselves and reproduce. However, Yoshii, Inayoshi, and Kakazu (1996) report the emergence of hyper cycles, within their Atomoid universe, which sustain themselves when the system is supplied with an ordered energy input. 5 Similarly McMullin and Varela (1997) has explored autopoiesis in the context of an CA like implementation of an artificial chemistry, ....

Yoshii, S., Inayoshi, H., & Kakazu, Y. (1996). Atomoid: A new prospect in reaction-formation system: Spontaneous hypercycles guided by dissipative structural properties. In ALIFE96.

....macro conservative attractors emerge through the self compartmentation of hypercycles due to local interactions based on conservative potential energy in a physically inspired chemical evolution model. Section 2 outlines the simulation model for this chemical evolution, named the Atomoid [8], the reaction dynamics of which are analogous to those found in the physical world based on energy levels. In the Atomoid, the concept of energy is defined by a bonding hand structure for each atomic element and a photon. Some degree of control over atomic reactions in the Atomoid may be achieved ....

....the diversity of the genotypes. As a result, spontaneous hypercycles are autonomously compartmented. 2 Physically Inspired Computation Model Atomoid The Atomoid is a chemical evolution model whose method of computation is inspired physically to address self organization or self reproduction [8]. The reason why this paper attaches such importance to a physically inspired model is that Artificial Life requires a realistic epistemology on which to be based. There are many Artificial Life influx of energy efflux of waste H H H H H atomoid photon H hypercycle Fig. 1. Overview of ....

. Yoshii, S., Inayoshi, H. and Kakazu, Y.: Atomoid: A New Prospect in ReactionFormation System, Spontaneous Hypercycles Guided by Dissipative Structural Properties, Artificial Life V (1996) 383-390

....whereby macro conservative attractors emerge through the self compartmentation of hypercycles due to local interactions based on conservative potential energy in a physically inspired chemical evolution model. Section 2 outlines the simulation model for this chemical evolution, named the Atomoid [8], the reaction dynamics of which are analogous to those found in the physical world based on energy levels. In the Atomoid, the concept of energy is defined by a bonding hand structure for each atomic element and a photon. Some degree of control over atomic reactions in the Atomoid may be achieved ....

....the diversity of the genotypes. As a result, spontaneous hypercycles are autonomously compartmented. 2 Physically Inspired Computation Model Atomoid The Atomoid is a chemical evolution model whose method of computation is inspired physically to address self organization or self reproduction [8]. The reason why this paper attaches such importance to a physically inspired model is that Artificial Life requires a realistic epistemology on which to be based. There are many Artificial Life influx of energy efflux of waste H H H H H atomoid photon H hypercycle Fig. 1. Overview of Atomoid ....

. Yoshii, S., Inayoshi, H. and Kakazu, Y.: Atomoid: A New Prospect in ReactionFormation System, Spontaneous Hypercycles Guided by Dissipative Structural Properties, Artificial Life V (1996) 383-390

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