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arxiv: 1211.7081 · v2 · pith:2Z6VCR5Bnew · submitted 2012-11-29 · 🪐 quant-ph · gr-qc· physics.hist-ph

The Universe is not a Computer

classification 🪐 quant-ph gr-qcphysics.hist-ph
keywords universeessaymodelsphysicalassumptioncomputationalcomputecomputer
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When we want to predict the future, we compute it from what we know about the present. Specifically, we take a mathematical representation of observed reality, plug it into some dynamical equations, and then map the time-evolved result back to real-world predictions. But while this computational process can tell us what we want to know, we have taken this procedure too literally, implicitly assuming that the universe must compute itself in the same manner. Physical theories that do not follow this computational framework are deemed illogical, right from the start. But this anthropocentric assumption has steered our physical models into an impossible corner, primarily because of quantum phenomena. Meanwhile, we have not been exploring other models in which the universe is not so limited. In fact, some of these alternate models already have a well-established importance, but are thought to be mathematical tricks without physical significance. This essay argues that only by dropping our assumption that the universe is a computer can we fully develop such models, explain quantum phenomena, and understand the workings of our universe. (This essay was awarded third prize in the 2012 FQXi essay contest; a new afterword compares and contrasts this essay with Robert Spekkens' first prize entry.)

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  1. Quantum Reconstruction and Phenomenology per the Relativity Principle

    quant-ph 2026-06 unverdicted novelty 3.0

    The relativity principle is shown to necessitate the discreteness requirement in quantum reconstruction programs when combined with Planck's radiation law, unifying the foundational explanations of special relativity ...