In algebra, a period is a number that can be written an integral of an algebraic function over an algebraic domain. More specifically, a period is a real number
 |
where 
is a polynomial and 
is a rational function on 
with rational coefficients.
Periods (which are countable) were defined to fill in a gap between algebraic numbers (which do not contain many mathematical constants) and the transcendental numbers (which are not countable). In particular, any algebraic number is a period and any number that is not a period is a transcendental number (Waldschmidt 2006), so there is a "gap" between those two statements in the sense that algebraic periods may be algebraic or transcendental. As a result, Kontsevich and Zagier (2001) propose their Principle 1: "Whenever you meet a new number, and have decided (or convinced yourself) that it is transcendental, try to figure out whether it is a period."
Periods form a ring since sums and products of periods are also periods. However, this class of numbers is larger and less well understood than the ring of algebraic numbers. However, its elements are constructible and it is conjectured that equality of any two numbers which have been expressed as periods can be verified. Most of the important constants of mathematics belong to the class of periods (Kontsevich and Zagier 2001).
Examples of periods include
 |
for 
a positive integer where 
is the Riemann zeta
function, 
for 
positive integers, and ![[Gamma(p/q)]^q](/images/equations/AlgebraicPeriod/Inline9.svg)
.
Chaitin's constant 
is not a period.
It is not known if 
,
, or the Euler-Mascheroni
constant 
are periods, though it it conjectured that 
and 
are not.
