Codimension is a term used in a number of algebraic and geometric contexts to indicate the difference between the dimension of certain objects
and the dimension of a smaller object contained in
it. This rough definition applies to vector spaces
(the codimension of the subspace 
in 
is 
) and to topological spaces
(with respect to the Euclidean topology and the Zariski
topology, the codimension of a sphere in 
is 
).
The first example is a particular case of the formula
 |
(1)
|
which gives the codimension of a subspace 
of a finite-dimensional abstract
vector space 
.
The second example has an algebraic counterpart in ring theory. A sphere in the three-dimensional
real Euclidean space is defined by the following
equation in Cartesian coordinates
 |
(2)
|
where the point 
is the center and 
is the radius. The Krull dimension of the polynomial
ring ![R[x,y,z]](/images/equations/Codimension/Inline10.svg)
is 3, the Krull dimension of the quotient
ring
![R[x,y,z]/[(x-x_0)^2+(y-y_0)^2+(z-z_0)^2-r^2]](/images/equations/Codimension/NumberedEquation3.svg) |
(3)
|
is 2, and the difference 
is also called the codimension of the ideal
 |
(4)
|
According to Krull's principal ideal theorem, its height is also equal to 1. On the other
hand, it can be shown that for every proper ideal 
in a polynomial
ring over a field, 
. This is a consequence of the fact that these
rings are all Cohen-Macaulay rings. In a ring
not fulfilling this assumption, only the inequality 
is true in general.
