Difference between revisions of "Lambda calculus"

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* [[Church–Turing Thesis]]
 
* [[Church–Turing Thesis]]
 
* [[Categorical abstract machine]] – A model of computation applicable to lambda calculus
 
* [[Categorical abstract machine]] – A model of computation applicable to lambda calculus
* [[Combinatory logic]] – A notation for mathematical logic without variables
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* [[Combinatory logic]] – A notation for [[mathematical logic]] without variables
 
* [[Computability theory]]
 
* [[Computability theory]]
 
* [[Computation]]
 
* [[Computation]]
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* [[Simply typed lambda calculus]] - Version(s) with a single type constructor
 
* [[Simply typed lambda calculus]] - Version(s) with a single type constructor
 
* [[SKI combinator calculus]] – A computational system based on the S, K and I combinators
 
* [[SKI combinator calculus]] – A computational system based on the S, K and I combinators
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* [[Supercombinator]] - a [[Expression (mathematics)|mathematical expression]] which is fully bound and self-contained.
 
* [[System F]] – A typed lambda calculus with type-variables
 
* [[System F]] – A typed lambda calculus with type-variables
 
* [[Turing completeness]]
 
* [[Turing completeness]]

Latest revision as of 11:58, 1 September 2016

Lambda calculus (also written as λ-calculus) is a formal system in mathematical logic for expressing computation based on function abstraction and application using variable binding and substitution.

Description

First formulated by Alonzo Church to formalize the concept of effective computability, lambda calculus found early successes in the area of computability theory, such as a negative answer to David Hilbert's Entscheidungsproblem.

Lambda calculus is a conceptually simple universal model of computation.

Alan Turing showed in 1937 that Turing machines equated the lambda calculus in expressiveness.

Name

The name derives from the Greek letter lambda (λ) used to denote binding a variable in a function.

The letter itself is arbitrary and has no special meaning.

Computer science

Lambda calculus is taught and used in computer science because of its usefulness in showcasing functional thinking and iterative reduction.

Typed and untyped variants

Because of the importance of the notion of variable binding and substitution, there is not just one system of lambda calculus, and in particular there are typed and untyped variants.

Untyped lambda calculus

Historically, the most important system was the untyped lambda calculus, in which function application has no restrictions (so the notion of the domain of a function is not built into the system).

Church–Turing Thesis

In the Church–Turing Thesis, the untyped lambda calculus is claimed to be capable of computing all effectively calculable functions.

Typed lambda calculus

The typed lambda calculus is a variety that restricts function application, so that functions can only be applied if they are capable of accepting the given input's "type" of data.

Modern applications

Today, the lambda calculus has applications in many different areas in:

Computability theory

It is still used in the area of computability theory, although Turing machines are also an important computational model.

Programming language theory

Lambda calculus has played an important role in the development of the [[Programming language theory|theory of Programming language|programming languages.

Functional programming languages

Counterparts to lambda calculus in computer science are functional programming languages, which essentially implement the lambda calculus (augmented with some constants and data types).

Proof theory

Beyond programming languages, the lambda calculus also has many applications in proof theory.

See also

External links