In mathematics, Liouville's theorem, originally formulated by French mathematician Joseph Liouville in 1833 to 1841,[1][2][3] places an important restriction on antiderivatives that can be expressed as elementary functions.
These are called nonelementary antiderivatives.
A standard example of such a function is
whose antiderivative is (with a multiplier of a constant) the error function, familiar from statistics.
Other examples include the functions
Liouville's theorem states that elementary antiderivatives, if they exist, are in the same differential field as the function, plus possibly a finite number of applications of the logarithm function.
is called a logarithmic extension of
is a simple transcendental extension of
This has the form of a logarithmic derivative.
in which case, this condition is analogous to the ordinary chain rule.
is not necessarily equipped with a unique logarithm; one might adjoin many "logarithm-like" extensions to
Similarly, an exponential extension is a simple transcendental extension that satisfies
is called an elementary differential extension of
if there is a finite chain of subfields from
where each extension in the chain is either algebraic, logarithmic, or exponential.
is an elementary differential extension of
In other words, the only functions that have "elementary antiderivatives" (that is, antiderivatives living in, at worst, an elementary differential extension of
Thus, on an intuitive level, the theorem states that the only elementary antiderivatives are the "simple" functions plus a finite number of logarithms of "simple" functions.
A proof of Liouville's theorem can be found in section 12.4 of Geddes, et al.[4] See Lützen's scientific bibliography for a sketch of Liouville's original proof [5] (Chapter IX.
Integration in Finite Terms), its modern exposition and algebraic treatment (ibid.
of rational functions in a single variable has a derivation given by the standard derivative with respect to that variable.
The constants of this field are just the complex numbers
do, however, exist in the logarithmic extension
do not seem to satisfy the requirements of the theorem, since they are not (apparently) sums of rational functions and logarithms of rational functions.
However, a calculation with Euler's formula
shows that in fact the antiderivatives can be written in the required manner (as logarithms of rational functions).
Liouville's theorem is sometimes presented as a theorem in differential Galois theory, but this is not strictly true.
The theorem can be proved without any use of Galois theory.
Furthermore, the Galois group of a simple antiderivative is either trivial (if no field extension is required to express it), or is simply the additive group of the constants (corresponding to the constant of integration).
Thus, an antiderivative's differential Galois group does not encode enough information to determine if it can be expressed using elementary functions, the major condition of Liouville's theorem.