Quotient space (linear algebra)

Formally, the construction is as follows.^[1] Let ${\displaystyle V}$  be a vector space over a field ${\displaystyle \mathbb {K} }$ , and let ${\displaystyle N}$  be a subspace of ${\displaystyle V}$ . We define an equivalence relation ${\displaystyle \sim }$  on ${\displaystyle V}$  by stating that ${\displaystyle x\sim y}$  if ${\displaystyle x-y\in N}$ . That is, ${\displaystyle x}$  is related to ${\displaystyle y}$  if one can be obtained from the other by adding an element of ${\displaystyle N}$ . From this definition, one can deduce that any element of ${\displaystyle N}$  is related to the zero vector; more precisely, all the vectors in ${\displaystyle N}$  get mapped into the equivalence class of the zero vector.

The equivalence class – or, in this case, the coset – of ${\displaystyle x}$  is often denoted

${\displaystyle [x]=x+N}$ 

since it is given by

${\displaystyle [x]=\{x+n:n\in N\}}$ 

The quotient space ${\displaystyle V/N}$  is then defined as ${\displaystyle V/_{\sim }}$ , the set of all equivalence classes induced by ${\displaystyle \sim }$  on ${\displaystyle V}$ . Scalar multiplication and addition are defined on the equivalence classes by^[2][3]

• ${\displaystyle \alpha [x]=[\alpha x]}$  for all ${\displaystyle \alpha \in \mathbb {K} }$ , and
• ${\displaystyle [x]+[y]=[x+y]}$ .

It is not hard to check that these operations are well-defined (i.e. do not depend on the choice of representatives). These operations turn the quotient space ${\displaystyle V/N}$  into a vector space over ${\displaystyle \mathbb {K} }$  with ${\displaystyle N}$  being the zero class, ${\displaystyle [0]}$ .

The mapping that associates to ${\displaystyle v\in V}$  the equivalence class ${\displaystyle [v]}$  is known as the quotient map.

Alternatively phrased, the quotient space ${\displaystyle V/N}$  is the set of all affine subsets of ${\displaystyle V}$  which are parallel to ${\displaystyle N}$ .^[4]

Lines in Cartesian Plane edit

Let X = R² be the standard Cartesian plane, and let Y be a line through the origin in X. Then the quotient space X/Y can be identified with the space of all lines in X which are parallel to Y. That is to say that, the elements of the set X/Y are lines in X parallel to Y. Note that the points along any one such line will satisfy the equivalence relation because their difference vectors belong to Y. This gives a way to visualize quotient spaces geometrically. (By re-parameterising these lines, the quotient space can more conventionally be represented as the space of all points along a line through the origin that is not parallel to Y. Similarly, the quotient space for R³ by a line through the origin can again be represented as the set of all co-parallel lines, or alternatively be represented as the vector space consisting of a plane which only intersects the line at the origin.)

Subspaces of Cartesian Space edit

Another example is the quotient of Rⁿ by the subspace spanned by the first m standard basis vectors. The space Rⁿ consists of all n-tuples of real numbers (x₁, ..., x_n). The subspace, identified with R^m, consists of all n-tuples such that the last n − m entries are zero: (x₁, ..., x_m, 0, 0, ..., 0). Two vectors of Rⁿ are in the same equivalence class modulo the subspace if and only if they are identical in the last n − m coordinates. The quotient space Rⁿ/R^m is isomorphic to R^n−m in an obvious manner.

Polynomial Vector Space edit

Let ${\displaystyle {\mathcal {P}}_{3}(\mathbb {R} )}$  be the vector space of all cubic polynomials over the real numbers. Then ${\displaystyle {\mathcal {P}}_{3}(\mathbb {R} )/\langle x^{2}\rangle }$  is a quotient space, where each element is the set corresponding to polynomials that differ by a quadratic term only. For example, one element of the quotient space is ${\displaystyle \{x^{3}+ax^{2}-2x+3:a\in \mathbb {R} \}}$ , while another element of the quotient space is ${\displaystyle \{ax^{2}+2.7x:a\in \mathbb {R} \}}$ .

General Subspaces edit

More generally, if V is an (internal) direct sum of subspaces U and W,

${\displaystyle V=U\oplus W}$ 

then the quotient space V/U is naturally isomorphic to W.^[5]

Lebesgue Integrals edit

An important example of a functional quotient space is an L^p space.

There is a natural epimorphism from V to the quotient space V/U given by sending x to its equivalence class [x]. The kernel (or nullspace) of this epimorphism is the subspace U. This relationship is neatly summarized by the short exact sequence

${\displaystyle 0\to U\to V\to V/U\to 0.\,}$ 

If U is a subspace of V, the dimension of V/U is called the codimension of U in V. Since a basis of V may be constructed from a basis A of U and a basis B of V/U by adding a representative of each element of B to A, the dimension of V is the sum of the dimensions of U and V/U. If V is finite-dimensional, it follows that the codimension of U in V is the difference between the dimensions of V and U:^[6][7]

${\displaystyle \mathrm {codim} (U)=\dim(V/U)=\dim(V)-\dim(U).}$ 

Let T : V → W be a linear operator. The kernel of T, denoted ker(T), is the set of all x in V such that Tx = 0. The kernel is a subspace of V. The first isomorphism theorem for vector spaces says that the quotient space V/ker(T) is isomorphic to the image of V in W. An immediate corollary, for finite-dimensional spaces, is the rank–nullity theorem: the dimension of V is equal to the dimension of the kernel (the nullity of T) plus the dimension of the image (the rank of T).

The cokernel of a linear operator T : V → W is defined to be the quotient space W/im(T).

If X is a Banach space and M is a closed subspace of X, then the quotient X/M is again a Banach space. The quotient space is already endowed with a vector space structure by the construction of the previous section. We define a norm on X/M by

${\displaystyle \|[x]\|_{X/M}=\inf _{m\in M}\|x-m\|_{X}=\inf _{m\in M}\|x+m\|_{X}=\inf _{y\in [x]}\|y\|_{X}.}$ 

Examples edit

Let C[0,1] denote the Banach space of continuous real-valued functions on the interval [0,1] with the sup norm. Denote the subspace of all functions f ∈ C[0,1] with f(0) = 0 by M. Then the equivalence class of some function g is determined by its value at 0, and the quotient space C[0,1]/M is isomorphic to R.

If X is a Hilbert space, then the quotient space X/M is isomorphic to the orthogonal complement of M.

Generalization to locally convex spaces edit

The quotient of a locally convex space by a closed subspace is again locally convex.^[8] Indeed, suppose that X is locally convex so that the topology on X is generated by a family of seminorms {p_α | α ∈ A} where A is an index set. Let M be a closed subspace, and define seminorms q_α on X/M by

${\displaystyle q_{\alpha }([x])=\inf _{v\in [x]}p_{\alpha }(v).}$ 

Then X/M is a locally convex space, and the topology on it is the quotient topology.

If, furthermore, X is metrizable, then so is X/M. If X is a Fréchet space, then so is X/M.^[9]

• Quotient group
• Quotient module
• Quotient set
• Quotient space (topology)

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