Does anyone know of any papers, texts, or other documents that discuss using a hypergraph to implement or represent a nondeterministic Turing machine? Are they in fact equivalent?
I'm pretty sure that a hypergraph is able to properly and completely represent the state transitions of a nondeterministic Turing machine, for instance. But I've so far been unable to find anything in print that can verify this. This seems to me like such an obvious relationship, however the fact that I'm not finding prior art makes me think I'm on the wrong track. (It could also be the case that what I'm finding is just not accessible enough for me to understand what it's saying.) ;-)
Why I ask: I'm working on an open-source package that does distributed data storage and distributed computation in a peer-to-peer network. I'm looking for the most primitive data structure that might support the functionality needed. So far, a distributed hypergraph looks promising. My reasoning is that, if a hypergraph can support something as general as a nondeterministic Turing machine, then it should be able to support a higher-level Turing-complete DSL. (There are other reasons the "nondeterministic" piece might be valuable to me as well, having to do with version control of the distributed data and/or computation results. Trying to avoid a dissertation here though.)
- The opencog folks had a tantalyzing discussion of how hypergraphs fit into different computing models; this apparently was related to the development of the HypergraphDB package: http://markmail.org/message/5oiv3qmoexvo4v5j
- Over on MathOverflow, there's a question discussing what hypergraphs can do -- no mention of turing yet, but I'm about to add it: http://mathoverflow.net/questions/13750/what-are-the-applications-of-hypergraphs
- If a hypergraph can represent a nondeterministic Turing machine, then I'd think a hypergraph with weighted edges would be equivalent to a probabalistic Turing machine. http://en.wikipedia.org/wiki/Probabilistic_Turing_machine