Key word "stochastic diffusion search"
al-Rifaie M. M., Leymarie F. F., Latham W. & Bishop M. J. (2017) Swarmic autopoiesis and computational creativity. Connection Science 29(4): 276–294. https://cepa.info/5027
al-Rifaie M. M., Leymarie F. F., Latham W. & Bishop M. J.
(
2017)
Swarmic autopoiesis and computational creativity.
Connection Science 29(4): 276–294.
Fulltext at https://cepa.info/5027
In this paper two swarm intelligence algorithms are used, the first leading the “attention” of the swarm and the latter responsible for the tracing mechanism. The attention mechanism is coordinated by agents of Stochastic Diffusion Search where they selectively attend to areas of a digital canvas (with line drawings) which contains (sharper) corners. Once the swarm’s attention is drawn to the line of interest with a sharp corner, the corresponding line segment is fed into the tracing algorithm, Dispersive Flies Optimisation which “consumes” the input in order to generate a “swarmic sketch” of the input line. The sketching process is the result of the “flies” leaving traces of their movements on the digital canvas which are then revisited repeatedly in an attempt to re-sketch the traces they left. This cyclic process is then introduced in the context of autopoiesis, where the philosophical aspects of the autopoietic artist are discussed. The autopoetic artist is described in two modalities: gluttonous and contented. In the Gluttonous Autopoietic Artist mode, by iteratively focussing on areas-of-rich-complexity, as the decoding process of the input sketch unfolds, it leads to a less complex structure which ultimately results in an empty canvas; therein reifying the artwork’s “death”. In the Contented Autopoietic Artist mode, by refocussing the autopoietic artist’s reflections on “meaning” onto different constitutive elements, and modifying her reconstitution, different behaviours of autopoietic creativity can be induced and therefore, the autopoietic processes become less likely to fade away and more open-ended in their creative endeavour.
Nasuto S. J., Bishop J. M. & de Meyer K. (2009) Communicating neurons: A connectionist spiking neuron implementation of stochastic diffusion search. Neurocomputing 72: 704–712.
Nasuto S. J., Bishop J. M. & de Meyer K.
(
2009)
Communicating neurons: A connectionist spiking neuron implementation of stochastic diffusion search.
Neurocomputing 72: 704–712.
An information-processing paradigm in the brain is proposed, instantiated in an artificial neural network using biologically motivated temporal encoding. The network will locate within the external world stimulus the target memory, defined by a specific pattern of micro-features. The proposed network is robust and efficient. Akin in operation to the Swarm Intelligence paradigm, Stochastic Diffusion Search, it will find the best-fit to the memory with linear time complexity. Information multiplexing enables neurons to process knowledge as “tokens” rather than “types.” The network illustrates the possible emergence of cognitive processing from low level interactions such as memory retrieval based on partial matching. Relevance: This paper outlines the implementation of a new metaphor for cognition; a metaphor grounded upon communication rather than computation.
Roesch E. B., Spencer M., Nasuto S. J., Tanay T. & Bishop J. M. (2013) Exploration of the Functional Properties of Interaction: Computer Models and Pointers for Theory. Constructivist Foundations 9(1): 26–33. https://constructivist.info/9/1/026
Roesch E. B., Spencer M., Nasuto S. J., Tanay T. & Bishop J. M.
(
2013)
Exploration of the Functional Properties of Interaction: Computer Models and Pointers for Theory.
Constructivist Foundations 9(1): 26–33.
Fulltext at https://constructivist.info/9/1/026
Context: Constructivist approaches to cognition have mostly been descriptive, and now face the challenge of specifying the mechanisms that may support the acquisition of knowledge. Departing from cognitivism, however, requires the development of a new functional framework that will support causal, powerful and goal-directed behavior in the context of the interaction between the organism and the environment. Problem: The properties affecting the computational power of this interaction are, however, unclear, and may include partial information from the environment, exploration, distributed processing and aggregation of information, emergence of knowledge and directedness towards relevant information. Method: We posit that one path towards such a framework may be grounded in these properties, supported by dynamical systems. To assess this hypothesis, we describe computational models inspired from swarm intelligence, which we use as a metaphor to explore the practical implications of the properties highlighted. Results: Our results demonstrate that these properties may serve as the basis for complex operations, yielding the elaboration of knowledge and goal-directed behavior. Implications: This work highlights aspects of interaction that we believe ought to be taken into account when characterizing the possible mechanisms underlying cognition. The scope of the models we describe cannot go beyond that of a metaphor, however, and future work, theoretical and experimental, is required for further insight into the functional role of interaction with the environment for the elaboration of complex behavior. Constructivist content: Inspiration for this work stems from the constructivist impetus to account for knowledge acquisition based on interaction.
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