From Digital computers to quantum computers based on biological paradigms and progress in particle physics

TL;DR

This paper explores a novel computing architecture inspired by biological processes and particle physics, integrating quantum and charge interactions for enhanced information processing and programmability.

Contribution

It introduces a new architecture combining biological paradigms with particle physics phenomena, including an algebraic design formalism for implementation.

Findings

Proposes a biologically inspired quantum computing architecture.

Demonstrates integration of particle physics interactions for information processing.

Provides a formal algebraic framework for the architecture.

Abstract

While several paths have emerged in microelectronics and computing as follow-ons to Turing architectures, and have been implemented using essentially silicon circuits, very little beyond Moore research has considered: (1) first biological processes instead of sequential instructions, and, (2) the implementation of these processes exploiting particle physics interactions. This last combination enables native spatial-temporal integration and correlation, but also powerful interference filtering, gating, splitting and more. These biological functions, their realization by quantum and charge carrier interactions, allow proposing a novel computing architecture, with interfaces, information storage, and programmability. The paper presents the underlying biological processes, the particle physics phenomena which are exploited, and the proposed architecture, as well as an algebraic design formalism.