Mathematical Foundations of Consciousness
Willard L. Miranker, Gregg J. Zuckerman
arXiv Preprint Archive October 23, 2008 Peer reviewed via arXiv
Summary
Consciousness, long considered beyond mathematical description, finds new ground in formal logic (math.LO) through an innovative framework using set theory. By applying non-well-founded sets and specialized operators, researchers demonstrate how consciousness might emerge from neural networks. The approach bridges abstract mathematics with brain function, showing how conscious experience could arise from underlying neural patterns.
Abstract
We employ the Zermelo-Fraenkel Axioms that characterize sets as mathematical primitives. The Anti-foundation Axiom plays a significant role in our development, since among other of its features, its replacement for the Axiom of Foundation in the Zermelo-Fraenkel Axioms motivates Platonic interpretations. These interpretations also depend on such allied notions for sets as pictures, graphs, decorations, labelings and various mappings that we use. A syntax and semantics of operators acting on sets is developed. Such features enable construction of a theory of non-well-founded sets that we use to frame mathematical foundations of consciousness. To do this we introduce a supplementary axiomatic system that characterizes experience and consciousness as primitives. The new axioms proceed through characterization of so- called consciousness operators. The Russell operator plays a central role and is shown to be one example of a consciousness operator. Neural networks supply striking examples of non-well-founded graphs the decorations of which generate associated sets, each with a Platonic aspect. Employing our foundations, we show how the supervening of consciousness on its neural correlates in the brain enables the framing of a theory of consciousness by applying appropriate consciousness operators to the generated sets in question.