Subspace

In three-dimensional Euclidean space, all the original planes and straight lines through the origin form sub-vector spaces.

A subspace , part vector space , linear subspace or linear subspace is in mathematics a subset of a vector space , which is a vector space itself again. The vector space operations vector addition and scalar multiplication are inherited from the initial space to the sub-vector space. Each vector space contains itself and the zero vector space as trivial sub-vector spaces.

Each subspace is the product of a linearly independent subset of vectors of the output space . The sum and the intersection of two sub-vector spaces results in a sub-vector space, the dimensions of which can be determined using the dimensional formula . Each subspace has at least one complementary space , so that the output space is the direct sum of the subspace and its complement. Furthermore, a factor space can be assigned to each sub-vector space , which is created in that all elements of the output space are projected in parallel along the sub-vector space .

If a vector space is over a body , then a subset forms a sub- vector space of if and only if it is not empty and closed with regard to vector addition and scalar multiplication . So it has to ${\ displaystyle (V, +, \ cdot)}$ ${\ displaystyle K}$${\ displaystyle U \ subseteq V}$${\ displaystyle V}$

hold for all vectors and all scalars . The vector addition and the scalar multiplication in the sub-vector space are the restrictions of the corresponding operations of the output space . ${\ displaystyle u, w \ in U}$${\ displaystyle \ alpha \ in K}$${\ displaystyle U}$${\ displaystyle V}$

With the help of these three criteria it can be checked whether a given subset of a vector space also forms a vector space without having to prove all vector space axioms. A subspace is often referred to as a “subspace” for short when it is clear from the context that it is a linear subspace and not a more general subspace . ${\ displaystyle U}$${\ displaystyle V}$

Examples

The set of vectors for which applies forms a subspace of the Euclidean plane.${\ displaystyle (x, y)}$${\ displaystyle x = y}$

Concrete examples

The set of all vectors of the real number plane forms a vector space with the usual component-wise vector addition and scalar multiplication. The subset of the vectors for which applies forms a subspace of , because it applies to all : ${\ displaystyle (x, y)}$${\ displaystyle V = \ mathbb {R} ^ {2}}$${\ displaystyle U}$${\ displaystyle x = y}$${\ displaystyle V}$${\ displaystyle a, b, c \ in \ mathbb {R}}$

• the coordinate origin is in${\ displaystyle (0,0)}$${\ displaystyle U}$
• ${\ displaystyle (a, a) + (b, b) = (a + b, a + b) \ in U}$
• ${\ displaystyle c \ cdot (a, a) = (c \ cdot a, c \ cdot a) \ in U}$

As a further example one can consider the vector space of all real functions with the usual pointwise addition and scalar multiplication. In this vector space the set of linear functions forms a sub-vector space, because it holds for : ${\ displaystyle V = \ mathbb {R} ^ {\ mathbb {R}}}$ ${\ displaystyle f \ colon \ mathbb {R} \ to \ mathbb {R}}$${\ displaystyle U}$ ${\ displaystyle f (x) = ax + b}$${\ displaystyle a, b, c, d \ in \ mathbb {R}}$

• Each vector space contains itself and the zero vector space , which only consists of the zero vector, as trivial sub-vector spaces.${\ displaystyle \ {0 \}}$
• In the vector space of real numbers , the set and whole are the only subspaces.${\ displaystyle \ mathbb {R}}$${\ displaystyle \ {0 \}}$${\ displaystyle \ mathbb {R}}$
• In the vector space of complex numbers , the set of real numbers and the set of imaginary numbers are subspaces.${\ displaystyle \ mathbb {R}}$ ${\ displaystyle \ mathbb {C}}$${\ displaystyle \ mathbb {R}}$${\ displaystyle i \ mathbb {R}}$
• In the Euclidean plane , all straight lines through the zero point form sub-vector spaces.${\ displaystyle \ mathbb {R} ^ {2}}$
• In Euclidean space , all straight lines through the origin and planes of origin form sub-vector spaces.${\ displaystyle \ mathbb {R} ^ {3}}$
• In the vector space of all polynomials , the set of polynomials of maximum degree forms a sub-vector space for every natural number .${\ displaystyle k}$${\ displaystyle k \ geq 0}$
• In the vector space of the square matrices , the symmetrical and the skew-symmetrical matrices each form sub-vector spaces.
• In the vector space of the real functions over an interval , the integrable functions , the continuous functions and the differentiable functions each form sub-vector spaces.
• In the vector space of all mappings between two vector spaces over the same body, the set of linear mappings forms a sub-vector space.

properties

Vector space axioms

The three subspace criteria are indeed sufficient and necessary for the validity of all vector space axioms. Because of the closed nature of the set, the following applies to all vectors by setting${\ displaystyle U}$${\ displaystyle u \ in U}$${\ displaystyle \ alpha = -1}$

${\ displaystyle (-1) \ cdot u = -u \ in U}$

and thus continue by setting ${\ displaystyle w = -u}$

${\ displaystyle 0 = uu \ in U}$.

The set thus contains in particular the zero vector and the additively inverse element for each element . So it is a subgroup of and therefore especially an Abelian group . The associative law , the commutative law , the distributive laws and the neutrality of one are transferred directly from the starting space . With that it satisfies all vector space axioms and is also a vector space. Conversely, every subspace must meet the three criteria given, since vector addition and scalar multiplication are the restrictions of the corresponding operations of . ${\ displaystyle U}$${\ displaystyle u}$ ${\ displaystyle -u}$${\ displaystyle (U, +)}$${\ displaystyle (V, +)}$${\ displaystyle V}$${\ displaystyle U}$${\ displaystyle (U, +, \ cdot)}$${\ displaystyle U}$${\ displaystyle V}$

presentation

The linear hull of a vector in the Euclidean plane${\ displaystyle \ langle a \ rangle}$${\ displaystyle a}$

Each subset of vectors of a vector space spans by forming all possible linear combinations${\ displaystyle X = \ {v_ {1}, \ ldots, v_ {n} \}}$${\ displaystyle V}$

${\ displaystyle \ langle X \ rangle = \ operatorname {span} \ {v_ {1}, \ ldots, v_ {n} \} = \ {\ alpha _ {1} v_ {1} + \ ldots + \ alpha _ {n} v_ {n} \ mid \ alpha _ {1}, \ ldots, \ alpha _ {n} \ in K \}}$,

a subspace of on, which is called the linear envelope of . The linear hull is the smallest subspace that includes the set and is equal to the average of all subspaces of that include. Conversely, every subspace is the product of a subset of , that is, it holds ${\ displaystyle V}$${\ displaystyle X}$${\ displaystyle X}$${\ displaystyle V}$${\ displaystyle X}$${\ displaystyle U}$${\ displaystyle X}$${\ displaystyle V}$

where the set is called a generating system of . A minimal generating system consists of linearly independent vectors and is called the basis of a vector space. The number of elements of a basis indicates the dimension of a vector space. ${\ displaystyle X}$${\ displaystyle U}$

is again a subspace, namely the smallest subspace that contains. Which applies to the sum of two finite-dimensional subspaces dimension formula${\ displaystyle U_ {1} \ cup U_ {2}}$

${\ displaystyle \ dim \ left (U_ {1} + U_ {2} \ right) = \ dim U_ {1} + \ dim U_ {2} - \ dim \ left (U_ {1} \ cap U_ {2} \ right)}$,

from which, conversely, the dimension of the intersection of two sub-vector spaces can also be read. Section and sum bases of sub-vector spaces of finite dimensions can be calculated with the Zassenhaus algorithm .

Direct sum

If the intersection of two sub-vector spaces consists only of the zero vector , then the sum is called an inner direct sum${\ displaystyle U_ {1}, U_ {2}}$${\ displaystyle U_ {1} \ cap U_ {2} = \ {0 \}}$

${\ displaystyle U_ {1} \ oplus U_ {2}}$,

because it is isomorphic to the outer direct sum of the two vector spaces. In this case there are uniquely certain vectors for each , with . It then follows from the set of dimensions that the zero vector space is zero-dimensional, for the dimension of the direct sum ${\ displaystyle u \ in U_ {1} \ oplus U_ {2}}$ ${\ displaystyle u_ {1} \ in U_ {1}}$${\ displaystyle u_ {2} \ in U_ {2}}$${\ displaystyle u = u_ {1} + u_ {2}}$

The preceding operations can also be generalized to more than two operands. If is a family of subspaces of , where is any index set , then these subspaces are averaged ${\ displaystyle (U_ {i}) _ {i \ in I}}$${\ displaystyle V}$${\ displaystyle I}$

applies. Each such complementary space corresponds exactly to one projection onto the sub-vector space , i.e. an idempotent linear mapping with the ${\ displaystyle P}$${\ displaystyle U}$${\ displaystyle P \ colon V \ to V}$

holds, where is the identical figure . In general, there are several complementary spaces to a sub-vector space, none of which is distinguished by the vector space structure. In scalar product spaces , however, it is possible to speak of mutually orthogonal sub-vector spaces. If finite dimensional, then for each sub-vector space there exists a uniquely determined orthogonal complementary space , which is precisely the orthogonal complement of , and it then applies ${\ displaystyle \ operatorname {Id}}$${\ displaystyle V}$${\ displaystyle U}$ ${\ displaystyle U ^ {\ perp}}$${\ displaystyle U}$

A factor space can be assigned to each sub-vector space of a vector space , which is created in that all elements of the sub-vector space are identified with one another and thus the elements of the vector space are projected in parallel along the sub-vector space . The factor space is formally defined as the set of equivalence classes${\ displaystyle U}$${\ displaystyle V}$${\ displaystyle V / U}$

${\ displaystyle V / U = \ {\, [v] \ mid v \ in V \}}$

of vectors in , being the equivalence class of a vector ${\ displaystyle v \ in V}$

${\ displaystyle [v] = v + U = \ {v + u \ mid u \ in U \}}$

is the set of vectors in that differ by only one element of subspace . The factor space forms a vector space if the vector space operations are defined representative, but it is not itself a subspace of . The following applies to the dimension of the factor space ${\ displaystyle V}$${\ displaystyle v}$${\ displaystyle u}$${\ displaystyle U}$${\ displaystyle V}$

${\ displaystyle \ dim V = \ dim U + \ dim V / U}$.

The subspaces of are exactly the factor spaces , where subspace of is with . ${\ displaystyle V / U}$${\ displaystyle W / U}$${\ displaystyle W}$${\ displaystyle V}$${\ displaystyle U \ subseteq W \ subseteq V}$

Annihilator room

The dual space of a vector space over a body is the space of the linear mappings from to and thus a vector space itself. For a subset of , the set of all functionals that vanish on forms a subspace of the dual space, the so-called annihilator space ${\ displaystyle V ^ {\ ast}}$${\ displaystyle V}$${\ displaystyle K}$${\ displaystyle V}$${\ displaystyle K}$${\ displaystyle X}$${\ displaystyle V}$${\ displaystyle X}$

${\ displaystyle X ^ {0} = \ lbrace f \ in V ^ {\ ast} \ mid f (x) = 0 {\ mbox {for all}} x \ in X \ rbrace}$.

If is finite dimensional, then the dimension of the annihilator space is a subspace of${\ displaystyle V}$${\ displaystyle U}$${\ displaystyle V}$

${\ displaystyle \ dim V = \ dim U + \ dim U ^ {0}}$.

The dual space of a subspace is isomorphic to the factor space . ${\ displaystyle U ^ {\ ast}}$${\ displaystyle U}$${\ displaystyle V ^ {\ ast} / U ^ {0}}$

Subspaces in linear algebra

Linear maps

If there is a linear mapping between two vector spaces and over the same body, then forms the core of the mapping ${\ displaystyle T \ colon V \ to W}$${\ displaystyle V}$${\ displaystyle W}$

a subspace of and the image of the mapping ${\ displaystyle V}$

a subspace of . Furthermore, the graph of a linear mapping is a subspace of the product space . If the vector space is finite-dimensional, then the rank theorem applies to the dimensions of the spaces involved${\ displaystyle W}$ ${\ displaystyle V \ times W}$${\ displaystyle V}$

If again a linear mapping between two vector spaces over the same field is the solution set of the homogeneous linear equation ${\ displaystyle T \ colon V \ to W}$

on the other hand, if it is not empty, with is an affine-linear subspace of , which is a consequence of the superposition property . The dimension of the solution space is then also equal to the dimension of the core of . ${\ displaystyle b \ neq 0}$${\ displaystyle V}$${\ displaystyle T}$

Is now a linear mapping of a vector space in itself, i.e. an endomorphism , with an associated eigenvalue problem ${\ displaystyle T \ colon V \ to V}$

then everyone is eigenspace belonging to an eigenvalue ${\ displaystyle \ lambda}$

a subspace of whose elements different from the zero vector are exactly the associated eigenvectors . The dimension of the eigen-space corresponds to the geometric multiplicity of the eigen-value; it is at most as large as the algebraic multiplicity of the eigenvalue. ${\ displaystyle V}$${\ displaystyle v}$

If there is an endomorphism again , then a subspace of invariant is called under or -invariant for short , if ${\ displaystyle T \ colon V \ to V}$${\ displaystyle U}$${\ displaystyle V}$ ${\ displaystyle T}$${\ displaystyle T}$

applies, that is, if the picture is also in for everyone . The image from below is then a subspace of . The trivial subspaces and , but also , and all eigenspaces of are always invariant under . Another important example of invariant subspaces are the main spaces , which are used, for example, to determine the Jordanian normal form . ${\ displaystyle u \ in U}$${\ displaystyle T (u)}$${\ displaystyle U}$${\ displaystyle U}$${\ displaystyle T}$${\ displaystyle U}$${\ displaystyle \ {0 \}}$${\ displaystyle V}$${\ displaystyle \ operatorname {ker} T}$${\ displaystyle \ operatorname {im} T}$${\ displaystyle T}$${\ displaystyle T}$

In a half- normalized space , the vectors with half-normal zero form a sub-vector space. A normalized space as a factor space is obtained from a semi-normalized space by considering equivalence classes of vectors that do not differ with regard to the semi-norm. If the semi-normalized space is complete, this factor space is then a Banach space. This construction is used in particular in L ^p spaces and related function spaces .