中文

Algorithmic Theories of Everything

量子物理 2007-05-23 v2 人工智能 计算复杂性 机器学习 高能物理 - 理论 数学物理 math.MP 计算物理

摘要

The probability distribution P from which the history of our universe is sampled represents a theory of everything or TOE. We assume P is formally describable. Since most (uncountably many) distributions are not, this imposes a strong inductive bias. We show that P(x) is small for any universe x lacking a short description, and study the spectrum of TOEs spanned by two Ps, one reflecting the most compact constructive descriptions, the other the fastest way of computing everything. The former derives from generalizations of traditional computability, Solomonoff's algorithmic probability, Kolmogorov complexity, and objects more random than Chaitin's Omega, the latter from Levin's universal search and a natural resource-oriented postulate: the cumulative prior probability of all x incomputable within time t by this optimal algorithm should be 1/t. Between both Ps we find a universal cumulatively enumerable measure that dominates traditional enumerable measures; any such CEM must assign low probability to any universe lacking a short enumerating program. We derive P-specific consequences for evolving observers, inductive reasoning, quantum physics, philosophy, and the expected duration of our universe.

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引用

@article{arxiv.quant-ph/0011122,
  title  = {Algorithmic Theories of Everything},
  author = {Juergen Schmidhuber},
  journal= {arXiv preprint arXiv:quant-ph/0011122},
  year   = {2007}
}

备注

10 theorems, 50 pages, 100 refs, 20000 words. Minor revisions: added references; improved readability