Model of computation
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In computer science, and more specifically in computability theory and computational complexity theory, a model of computation is a model which describes how an output of a mathematical function is computed given an input. A model describes how units of computations, memories, and communications are organized.[1] The computational complexity of an algorithm can be measured given a model of computation. Using a model allows studying the performance of algorithms independently of the variations that are specific to particular implementations and specific technology.
Models
[edit]Models of computation can be classified into three categories: sequential models, functional models, and concurrent models.
Sequential models
[edit]Sequential models include:
- Finite state machines
- Post machines (Post–Turing machines and tag machines).
- Pushdown automata
- Register machines
- Turing machines
- Decision tree model
Functional models
[edit]Functional models include:
Concurrent models
[edit]Concurrent models include:
- Actor model
- Cellular automaton
- Interaction nets
- Kahn process networks
- Logic gates and digital circuits
- Petri nets
- Process calculus
- Synchronous Data Flow
Some of these models have both deterministic and nondeterministic variants. Nondeterministic models correspond to limits of certain sequences of finite computers, but do not correspond to any subset of finite computers;[citation needed] they are used in the study of computational complexity of algorithms.
Models differ in their expressive power; for example, each function that can be computed by a Finite state machine can also be computed by a Turing machine, but not vice versa.
Uses
[edit]In the field of runtime analysis of algorithms, it is common to specify a computational model in terms of primitive operations allowed which have unit cost, or simply unit-cost operations. A commonly used example is the random-access machine, which has unit cost for read and write access to all of its memory cells. In this respect, it differs from the above-mentioned Turing machine model.
See also
[edit]- Stack machine (0-operand machine)
- Accumulator machine (1-operand machine)
- Register machine (2,3,... operand machine)
- Random-access machine
- Abstract machine
- Cell-probe model
- Robertson–Webb query model
- Chomsky hierarchy
- Turing completeness
References
[edit]- ^ "Models of Computation" (PDF).
Further reading
[edit]- Fernández, Maribel (2009). Models of Computation: An Introduction to Computability Theory. Undergraduate Topics in Computer Science. Springer. ISBN 978-1-84882-433-1.
- Savage, John E. (1998). Models Of Computation: Exploring the Power of Computing. Addison-Wesley. ISBN 978-0201895391.