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Why don't we reduce the Planning Problem in AI to the TQBF Version of SAT in practical solvers.

Many planning problems are in practice "compiled down" or reduced to the SAT problem, which is in turn solved by SAT Solvers. The problem is that , since planning is PSPACE Complete, and SAT is NP Complete, an exponential number of literals may be required.

Why, then, do practical planners use this approach? Why don't we all solve TQBF SAT and then "compile" Planning down to TQBF, which should only take Polynomial time anyway?

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Can TQBF represent probabilistic models? Even with SAT, you still have to formula your problem. Real-world planning problems can be immensely complicated. I'm not sure what you mean when you say we should just "reduce it to TQBF". –  Cerin Sep 18 '10 at 0:20
There is no probability involved anywhere, I'm talking only about classical planning. By "reducing to TQBF", I mean "convert an instance of planning problem to an equiv. instance of TQBF". –  PKG Sep 18 '10 at 3:09
Are there any "efficient" TQBF solvers available which allow exploiting structure from compiled down planning problems? –  ziggystar Sep 18 '10 at 11:24
The phrases "no probability" and "practical planner" are mutually exclusive. –  Cerin Sep 18 '10 at 13:36

3 Answers 3

up vote 2 down vote accepted

This has already been done.

Generally TQBF is used to model conformant planning, but there do exist encodings of purely propositional logic planning problems to (polynomially-sized) TQBF formulae.

The main drawback is that, although we have a much smaller formula, it's not neccessarily easier to solve. TQBF solving is no way near as mature as the research into solving SAT, and Planning as TQBF is still some way behind in performance.

Here is one publication detailing such a transformation (mine):


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SAT solvers today are highly optimized and able to exploit structure inside the problems. They are very fast on most problems (but they can't be fast on all, because SAT is hard).

So by compiling down your planning problem into an instance of SAT, you are able to exploit all the work that went into the development of modern SAT solvers. You'll probably loose some structure related to the planning problem, which you could have exploited by writing a planner directly.

Maybe, when cleverly compiling down the planning problem and exploiting the planning structure in this step you'll be able to obtain easier SAT instances. But when doing so, one could say you're trying to solve the planning problem again, just by the means of another computation model (SAT-solver instead of random access memory machine or more indirectly LISP, whatever).

So why not TQBF?

Obviously, because no one has tried, yet (which I can't confirm). Maybe no one had this idea before or maybe no one thought that current TQBF-solvers are smart enough to quickly solve the compiled down planning problems - at least more quickly than the state-of-the-art planners.

I'm not well informed in the TQBF-solver scene. Actually, I've never heard of something like a general TQBF-solver before (excluding logic programming in general). I think it's way harder to do than SAT (which hasn't been proven yet, supposed Deolalikar is wrong).

So, go ahead and try it. You can post a link to your publication here if you succeed.

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If I understand what you're asking:

You want to know why we don't convert a high-level complex problem which has no known solution to a simpler one which we can more easily solve.

Well, consider this: To be able to do so, we'd first need to find an efficient compiler; chances are, it would be harder to run the compiler to convert than it would be to solve the problem.

And, even in a simpler format, there's no fewer computations to solve. Consider this analogy:

I use Conway's Game of Life as a processor. (Please look it up if you don't know what it is) Therefore, I am able to solve in 1 unit of time what a processor takes a long time to simulate (Conway's Game of Life). HOWEVER, if we wanted to have a modern processor SIMULATE A VIRTUAL MACHINE of Conway's Game of Life processor, it would be no faster.

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The author wants to reduce to a problem of similar complexity. –  ziggystar Sep 19 '10 at 20:02
What are you talking about? That reply makes no sense.... Similar complexity to WHAT? –  TaslemGuy Sep 19 '10 at 20:22

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