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The book Algorithms demonstrates the Fast Fourier Transform through a "circuit", using "wires" to carry data. What is a circuit? Is it simply a concept made up by the author of the book to better demonstrate the algorithm or is it a recognized computer science concept?

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Not to be flippant, but Google circuit computer science and you get a Wikiepdia page with the answer. –  Robert Cooper Jun 5 '12 at 2:58
...but there appear to be almost no questions on circuit complexity on Stack Overflow, so I withdraw my flippant remark. –  Robert Cooper Jun 5 '12 at 3:02
This question might be better served on Computer Science. Circuits are an academic sort of subject, not a software engineering one. –  Robert Cooper Jun 5 '12 at 3:08
@hotpaw2 I'm obviously familiar with the electronics version of a circuit. I do have a strong foundation in electronics. I was specifically asking about the computer science circuit's application in demonstrating theories, not the common electronic one. –  fdh Jun 5 '12 at 12:24

2 Answers 2

The answer to your question is, yes, "circuits" are a recognized concept in theoretical computer science, drawing on the related concept from electronics. A Boolean circuit is basically what it sounds like: A model for computation over binary strings, consisting of boolean logic gates strung together with wires. You can find a formal definition here, at Wikipedia.

Where they come in handy is, as you've seen, determining complexity of a particular problem. The FFT example is fairly accessible, but probably the most famous example is Cook's definition of NP-Completeness, which turns on the proof that determining whether a given Boolean circuit is satisfiable is NP-Complete.

Barrington and Maciel have a series of computation complexity lecture notes that introduce circuits in the first lecture and continue to use the concept throughout.

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Some problems are easy, and some are hard. In order to say what makes a problem easy and what makes it hard with more rigger, we use generally models of computer and place constraints on those models.

Turing Machines are one common model used to define classes of problems. For example, the complexity class P comprises problems such that there exists a Turing Machine that can solve the problem in O(n^p) time for some power p (polynomial time). We can get other complexity classes with other constraints on time or space bounds on the Turing Machine.

Non-deterministic Turing Machines are another model for computers. Alternating Turing machines are another. Many models for computers exist, and each are useful for defining different types of problems. Circuits are one of these models of computers.

Turing machines useful for modeling single-threaded computer programs. Circuits shine when modeling massively parallel computations. For example, Nick's class or NC comprise problems that can be solved "quickly" (poly-log time) with a polynomial number of processors.

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I just realized as I was writing that answer that you were talking about a Fast FFT. I dimly recall some diagrams with circuits involved in explaining that algorithm, but don't recall how they relate to the circuits I wrote about. There will probably be people on Computer Science that have forgotten dozens of times more about this sort of thing than I ever knew. –  Robert Cooper Jun 5 '12 at 3:41

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