In mathematics, an isometry (or congruence, or congruent transformation) is a distance-preserving transformation between metric spaces, usually assumed to be bijective. The word isometry is derived from the Ancient Greek: ἴσος isos meaning "equal", and μέτρον metron meaning "measure". If the transformation is from a metric space to itself, it is a kind of geometric transformation known as a motion.
Given a metric space (loosely, a set and a scheme for assigning distances between elements of the set), an isometry is a transformation which maps elements to the same or another metric space such that the distance between the image elements in the new metric space is equal to the distance between the elements in the original metric space. In a two-dimensional or three-dimensional Euclidean space, two geometric figures are congruent if they are related by an isometry;the isometry that relates them is either a rigid motion (translation or rotation), or a composition of a rigid motion and a reflection.
Isometries are often used in constructions where one space is embedded in another space. For instance, the completion of a metric space
M
M
M',
M.
M
An isometric surjective linear operator on a Hilbert space is called a unitary operator.
Let
X
Y
a,b\inX
dX(a,b)=dY\left(f(a),f(b)\right).
An isometry is automatically injective; otherwise two distinct points, a and b, could be mapped to the same point, thereby contradicting the coincidence axiom of the metric d, i.e.,
d(a,b)=0
a=b
A global isometry, isometric isomorphism or congruence mapping is a bijective isometry. Like any other bijection, a global isometry has a function inverse. The inverse of a global isometry is also a global isometry.
Two metric spaces X and Y are called isometric if there is a bijective isometry from X to Y. The set of bijective isometries from a metric space to itself forms a group with respect to function composition, called the isometry group.
There is also the weaker notion of path isometry or arcwise isometry:
A path isometry or arcwise isometry is a map which preserves the lengths of curves; such a map is not necessarily an isometry in the distance preserving sense, and it need not necessarily be bijective, or even injective. This term is often abridged to simply isometry, so one should take care to determine from context which type is intended.
x\mapsto|x|
R
The following theorem is due to Mazur and Ulam.
Definition: The midpoint of two elements and in a vector space is the vector .
Given two normed vector spaces
V
W,
A:V\toW
\|Av\|W=\|v\|V
v\inV.
In an inner product space, the above definition reduces to
\langlev,v\rangleV=\langleAv,Av\rangleW
for all
v\inV,
A\daggerA=\operatorname{Id}V.
\langleAu,Av\rangleW=\langleu,A\daggerAv\rangleV=\langleu,v\rangleV
Linear isometries are not always unitary operators, though, as those require additionally that
V=W
AA\dagger=\operatorname{Id}V
A
By the Mazur–Ulam theorem, any isometry of normed vector spaces over
R
A linear isometry also necessarily preserves angles, therefore a linear isometry transformation is a conformal linear transformation.
Cn
An isometry of a manifold is any (smooth) mapping of that manifold into itself, or into another manifold that preserves the notion of distance between points. The definition of an isometry requires the notion of a metric on the manifold; a manifold with a (positive-definite) metric is a Riemannian manifold, one with an indefinite metric is a pseudo-Riemannian manifold. Thus, isometries are studied in Riemannian geometry.
A local isometry from one (pseudo-)Riemannian manifold to another is a map which pulls back the metric tensor on the second manifold to the metric tensor on the first. When such a map is also a diffeomorphism, such a map is called an isometry (or isometric isomorphism), and provides a notion of isomorphism ("sameness") in the category Rm of Riemannian manifolds.
Let
R=(M,g)
R'=(M',g')
f:R\toR'
f
g=f*g',
where
f*g'
g'
f
f*,
v,w
M
TM
g(v,w)=g'\left(f*v,f*w\right).
If
f
g=f*g',
f
A collection of isometries typically form a group, the isometry group. When the group is a continuous group, the infinitesimal generators of the group are the Killing vector fields.
The Myers–Steenrod theorem states that every isometry between two connected Riemannian manifolds is smooth (differentiable). A second form of this theorem states that the isometry group of a Riemannian manifold is a Lie group.
Riemannian manifolds that have isometries defined at every point are called symmetric spaces.
f\colonX\toY
x,x'\inX
|dY(f(x),f(x'))-dX(x,x')|<\varepsilon,
y\inY
x\inX
dY(y,f(x))<\varepsilon
That is, an -isometry preserves distances to within and leaves no element of the codomain further than away from the image of an element of the domain. Note that -isometries are not assumed to be continuous.
a\inak{A}
a* ⋅ a=1.
Note that as mentioned in the introduction this is not necessarily a unitary element because one does not in general have that left inverse is a right inverse.
M=(I-W)\top(I-W)
M\equivYY\top