- See also moment (physics).
The concept of moment in mathematics evolved from the
concept of moment in physics. The nth moment of a
real-valued function f(x) of a real variable is
-
The problem of moments seeks characterizations of sequences { μ′n :
n = 1, 2, 3, ... } that are sequences of moments of some function f.
If (lower-case) f is a probability
density function, then the value integral above is called the nth moment of the probability distribution. More generally, if (capital)
F is a cumulative probability
distribution function of any probability distribution, which may not have a density function, then the nth moment of
the probability distribution is given by the Riemann-Stieltjes integral
-
where X is a random variable that has this
distribution.
The nth central moment of
the probability distribution of a random variable X is
- μn = E((X - μ1')n).
The second central moment is the variance.
The central momemts are clearly translation-invariant, i.e., the nth central moment of X is the same as that
of X + c for any constant c (in this context "constant" means a non-random quantity).
The first moment and the second and third central moments are linear in the sense that
- μ1(X + Y) = μ1(X) +
μ1(Y)
and
-
and
- μ3(X + Y) = μ3(X) +
μ3(Y)
if X and Y are independent
random variables (independence is not needed for the first of these three identities; for the second it can be weakened to
uncorrelatedness).
The central moments beyond the third lack this linearity; in that respect they differ from the cumulants (the first three cumulants are the same as the first moment and the second and third central
moments; the higher cumulants have a more complicated relationship with the central moments).
Like the cumulants, the factorial moments of a probability
distribution are also polynomial functions of the moments.
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