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In differential algebra, an elementary function is a function built from a finite number of exponentials, logarithms, constants, one variable, and roots of equations through composition and combinations using the four elementary operations (+ − × ÷). The trigonometric functions and their inverses are assumed to be included in the elementary functions by using complex variables (i = √-1) and the relations between the trigonometric functions and the exponential and logarithm functions. Wikipedia does not yet have an article with this exact name. ...
In mathematics, the trigonometric functions are functions of an angle, important when studying triangles and modeling periodic phenomena. ...
In mathematics, the trigonometric functions are functions of an angle, important when studying triangles and modeling periodic phenomena. ...
The roots of equations are the functions implicitly defined as solving a polynomial equation with constant coefficients. For polynomials of degree four and smaller there are explicit formulas for the roots (the formulas are elementary functions), but even for higher degree polynomials the fundamental theorem of algebra and the implicit function theorem assures the existence of a function that returns each one of the roots of a polynomial equation. In mathematics, the fundamental theorem of algebra states that every complex polynomial of degree n has exactly n zeroes, counted with multiplicity. ...
In mathematics, in the field of calculus of several variables, the implicit function theorem says that for a suitable set of equations, some of the variables are defined as a function of the others. ...
Examples of elementary functions include:
and - .
The domain of this last function does not include any real number. An example of a function that is not elementary is the error function a fact that cannot be seen directly from the definition of elementary function but can be proven using the Risch algorithm. The Risch algorithm is an algorithm for the calculus operation of indefinite integration (i. ...
Elementary functions where introduced by Joseph Liouville in a series of papers from 1833 to 1841. An algebraic treatment of elementary functions was started by Joseph Fels Ritt in the 1930s. Joseph Liouville (born March 24, 1809, died September 8, 1882) was a French mathematician. ...
1833 was a common year starting on Tuesday (see link for calendar). ...
1841 is a common year starting on Friday (link will take you to calendar). ...
Events and trends Technology Jet engine invented First atom was split with a particle accelerator Golden Age of radio begins in U.S. Disney adopts a three-color Technicolor process for cartoons First Kit Kat in UK The photocopier is invented by Carlson Air mail service across the Atlantic Science...
Differential algebra The mathematical definition of an elementary function is done in the context of differential algebra. A differential algebra is an algebra with the extra operation of derivation (algebraic version of differentiation). Using the derivation operation new equations can be written and their solutions used in extensions of the algebra. By starting with the field of rational functions, two special types of transcendental extensions (the logarithm and the exponential) can be added to the field building a tower containing elementary functions. Wikipedia does not yet have an article with this exact name. ...
In abstract algebra, an extension of a field K is a field L which contains K as a subfield. ...
A differential field F is a field F0 (rational functions over the rationals Q for example) together with a derivation map u → ∂u. (Here ∂u is a new function. Sometimes the notation u ′ is used.) The derivation captures the properties of differentiation, so that for any two elements of the base field, the derivation is linear
and satisfies the Leibniz' product rule In mathematics, the product rule of calculus, which is also called Leibnizs law (see derivation), governs the differentiation of products of differentiable functions. ...
An element h is a constant if ∂h = 0. If the base field is over the rationals, care must be taken when extending the field to add the needed transcendental constants.
A function u of a differential extension F[u] of a differential field F is an elementary function over F if the function u
- is algebraic over F, or
- is an exponential, that is, ∂u = u ∂a for a ∈ F, or
- is a logarithm, that is, ∂u = ∂a / a for a ∈ F.
Reference Maxwell Rosenlicht (1972). "Integration in finite terms". American Mathematical Monthly, 79, 963-972. | 
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