Steinitz exchange lemma

The Steinitz exchange lemma is a basic theorem in linear algebra used, for example, to show that any two bases for a finite-dimensional vector space have the same number of elements. The result is named after the German mathematician Ernst Steinitz. The result is often called the Steinitz–Mac Lane exchange lemma, also recognizing the generalization^[1] by Saunders Mac Lane of Steinitz's lemma to matroids.^[2]

Let ${\displaystyle U}$ and ${\displaystyle W}$ be finite subsets of a vector space ${\displaystyle V}$. If ${\displaystyle U}$ is a set of linearly independent vectors, and ${\displaystyle W}$ spans ${\displaystyle V}$, then:

1. ${\displaystyle |U|\le |W|}$;

2. There is a set ${\displaystyle W^{\prime }\subseteq W}$ with ${\displaystyle |W^{\prime }|=|W|-|U|}$ such that ${\displaystyle U\cup W^{\prime }}$ spans ${\displaystyle V}$.

Suppose ${\displaystyle U=\{u_1,\dots ,u_m\}}$ and ${\displaystyle W=\{w_1,\dots ,w_n\}}$. We wish to show that ${\displaystyle m\le n}$, and that after rearranging the ${\displaystyle w_j}$ if necessary, the set ${\displaystyle \{u_1,\dots ,u_m,w_{m+1},\dots ,w_n\}}$ spans ${\displaystyle V}$. We proceed by induction on ${\displaystyle m}$.

For the base case, suppose ${\displaystyle m}$ is zero. In this case, the claim holds because there are no vectors ${\displaystyle u_i}$, and the set ${\displaystyle \{w_1,\dots ,w_n\}}$ spans ${\displaystyle V}$ by hypothesis.

For the inductive step, assume the proposition is true for ${\displaystyle m-1}$. By the inductive hypothesis we may reorder the ${\displaystyle w_i}$ so that ${\displaystyle \{u_1,\dots ,u_{m-1},w_m,\dots ,w_n\}}$ spans ${\displaystyle V}$. Since ${\displaystyle u_m\in V}$, there exist coefficients ${\displaystyle {\mu }_1,\dots ,{\mu }_n}$ such that

${\displaystyle u_m={\displaystyle \sum _{i=1}^{m-1}}{\mu }_i{u}_i+{\displaystyle \sum _{j=m}^n}{\mu }_j{w}_j}$.

At least one of the ${\displaystyle {\mu }_j}$ must be non-zero, since otherwise this equality would contradict the linear independence of ${\displaystyle \{u_1,\dots ,u_m\}}$; it follows that ${\displaystyle m\le n}$. By reordering ${\displaystyle {\mu }_m{w}_m,\dots ,{\mu }_n{w}_n}$ if necessary, we may assume that ${\displaystyle {\mu }_m}$ is nonzero. Therefore, we have

${\displaystyle w_m=\frac{1}{{\mu }_m}(u_m-{\displaystyle \sum _{j=1}^{m-1}}{\mu }_j{u}_j-{\displaystyle \sum _{j=m+1}^n}{\mu }_j{w}_j)}$.

In other words, ${\displaystyle w_m}$ is in the span of ${\displaystyle \{u_1,\dots ,u_m,w_{m+1},\dots ,w_n\}}$. Since this span contains each of the vectors ${\displaystyle u_1,\dots ,u_{m-1},w_m,w_{m+1},\dots ,w_n}$, by the inductive hypothesis it contains ${\displaystyle V}$.

The Steinitz exchange lemma is a basic result in computational mathematics, especially in linear algebra and in combinatorial algorithms.^[3]

• Julio R. Bastida, Field extensions and Galois Theory, Addison–Wesley Publishing Company (1984).

• Mizar system proof: http://mizar.org/version/current/html/vectsp_9.html#T19

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