In computability theory, an effective method (also called an effective procedure) is a procedure that reduces the solution of some class of problems to a series of rote steps which, if followed to the letter, and as far as may be necessary, is bound to:
An effective method for calculating the values of a function is an algorithm; functions with an effective method are sometimes called effectively calculable.
Several independent efforts to give a formal characterization of effective calculability led to a variety of proposed definitions (general recursion, Turing machines, λ-calculus) that later were shown to be equivalent; the notion captured by these definitions is known as (recursive) computability.
Church's thesis states that the two notions coincide: any number-theoretic function that is effectively calculable is recursively computable. Church's thesis is not a mathematical statement and cannot be proved by a mathematical proof.
A further elucidation of the term "effective method" may include the requirement that, when given a problem from outside the class for which the method is effective, the method may halt or loop forever without halting, but must not return a result as if it were the answer to the problem.
An essential feature of an effective method is that it does not require any ingenuity from any person or machine executing it.[1]