Complementary subspace

Two subspaces of a vector space are said to be complementary if their direct sum gives the entire vector space as a result.

Table of contents

Preliminaries
Definition
The complementary subspace is not necessarily unique
Characterization in terms of bases

Preliminaries

Let be a linear space and $S_{1}$ and $S_{2}$ two subspaces of .

Remember that the sum $S_{1}+S_{2}$ is the subspace that contains all the vectors that can be written as sums of a vector from $S_{1}$ and another vector from $S_{2}$ :

Moreover, $S_{1}+S_{2}$ is said to be a direct sum, and it is denoted by $S_{1}oplus S_{2}$ , if and only if one of the following equivalent conditions is met:

;
two non-zero vectors $s_{1}$ and $s_{2}$ are linearly independent whenever $s_{1}in S_{1}$ and $s_{2}in S_{2}$ ;
the only way to choose $s_{1}in S_{1}$ and $s_{2}in S_{2}$ such that $s_{1}+s_{2}=0$ is to choose $s_{1}=s_{2}=0$ ;
for any , there exists a unique couple $s_{1}in S_{1}$ and $s_{2}in S_{2}$ such that $s=s_{1}+s_{2}$ .

Definition

We are now ready to provide a definition of complementary subspace.

Definition Let be a linear space. Let $S_{1}$ and $S_{2}$ be two subspaces of . $S_{1}$ is said to be complementary to $S_{2}$ if and only if

Complementarity, as defined above, is clearly symmetric. If $S_{1}$ is complementary to $S_{2}$ , then $S_{2}$ is complementary to $S_{1}$ and we can simply say that $S_{1}$ and $S_{2}$ are complementary.

Thus, when $S_{1}$ and $S_{2}$ are complements, there is a unique way to "decompose" a vector into a component $s_{1}in S$ and another component $s_{2}in S_{2}$ , where the decomposition is

Let us see a simple example.

Example Let be the space of all column vectors. Let $S_{1}$ be the space spanned by the vector [eq6] that is, $S_{1}$ contains all scalar multiples of $e_{1}$ . Let $S_{2}$ be the space spanned by the vector [eq7] No non-zero vector of $S_{2}$ is a scalar multiple of a vector of $S_{1}$ . Therefore, and the sum $S_{1}+S_{2}$ is a direct sum. Moreover, any vector [eq9] can be written aswhere and . Thus, which means that $S_{1}$ and $S_{2}$ are complementary.

The complementary subspace is not necessarily unique

A complementary subspace is not necessarily unique.

Example Let , $S_{1}$ and $S_{2}$ be as in the previous example. Let $S_{3}$ be the space spanned by the vector [eq14] No non-zero vector of $S_{3}$ is a scalar multiple of a vector of $S_{1}$ . Therefore, and the sum $S_{1}+S_{3}$ is a direct sum. Moreover, any vector [eq16] can be written aswhere and . Thus, and $S_{2} eq S_{3}$ , which shows that there is no unique complementary subspace of $S_{1}$ .

Characterization in terms of bases

The following proposition characterizes complementary subspaces in terms of their bases.

Proposition Let be a finite-dimensional linear space. Let $S_{1}$ and $S_{2}$ be two subspaces of . Then, $S_{1}$ and $S_{2}$ are complementary if and only if, for any basis of $S_{1}$ and any basis of $S_{2}$ , their union is a basis for .

Proof

Let us prove the "only if" part, starting from the hypothesis that $S_{1}$ and $S_{2}$ are complementary. Any vector can be written uniquely aswhere $s_{1}in S_{1}$ and $s_{2}in S_{2}$ . Moreover, by the uniqueness of the representation in terms of a basis, where the scalars are unique. Similarly,Thus has a unique representation in terms of :We have established that spans . We still need to prove that it is linearly independent in order to prove that it is a basis. Suppose thatSince , it must be thatandSince and , being bases, are linearly independent sets, the two equations above imply andThus, the only linear combination of the vectors of the set giving the zero vector as a result has all coefficients equal to zero. This means that is linearly independent. Hence, is a basis for . We can now prove the "if" part, starting from the hypothesis that, for any bases of $S_{1}$ and of $S_{2}$ , the union is a basis for . Choose the two bases arbitrarily (they are guaranteed to exist because we have assumed that is finite-dimensional). The fact that is a basis for implies that any vector can be uniquely written as a linear combination Since is a basis for $S_{1}$ , we have thatandTherefore, any vector can be uniquely represented aswhere $s_{1}in S_{1}$ and $s_{2}in S_{2}$ . Thus, .

How to cite

Please cite as:

Taboga, Marco (2021). "Complementary subspace", Lectures on matrix algebra. https://www.statlect.com/matrix-algebra/complementary-subspace.