Union and intersection of vector spaces – Serlo

Motivation

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We know various operations to construct a new set from given sets. If   is a family of sets, we can, for example, form the average   or the union  . Assume that the   are also subspaces of a larger vector space  . This means that the   are non-empty subsets of  , which are closed under addition and scalar multiplication. Are the average and the union of   then also subspaces of  ?

Intersection of vector spaces

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Is the intersection of subspaces of a vector space again a subspace? To answer this question, let us first consider the case of two subspaces and look at examples in  .

  1. Let us first look at the two planes   and   (the y-z-plane). In the image we can see that its intersection is the z-axis  , i.e. a subspace of  .
  2. The second image shows that the intersection of the line   with the y-z plane   is also a line, namely  .
  3. If we intersect the y-z plane   with the line   instead, we see that the intersection only contains the zero vector. This is also a subspace of  .


In the examples, the intersection of the two subspaces is always a subspace of  . We now show that this also applies to general subspaces of any vector space.

Theorem (Intersection of vector spaces)

Let   and   be two subspaces of a vector space  . The intersection   of   and   is a subspace of  .

Proof (Intersection of vector spaces)

First, we have to establish the three subspace criteria:

Proof step:   is not empty

Since   and   are subspaces, we have   and  . Thus,  , and therefore  .

Proof step:   is closed under addition.

Let now   be arbitrary. Then   and   apply. As the subspaces   and   are closed under addition, we get   and  . This also means  .

Proof step:   is closed under scalar multiplication.

Let   and   be arbitrary. Then we have   and  . Since the subspaces   and   are closed under scalar multiplication, we obtain  and  . Thus, also  .

Hint

We have seen that   is a subspace of  . Because  , the intersection is also a subspace  . From this we get  . Similarly,   follows from  . This makes intuitively sense: if we intersect one subspace with another, its dimension cannot possibly become larger.

We have shown that the intersection of two subspaces is again a subspace. However, at no point in the proof is it relevant that there are only two or finitely many subspaces involved. In fact, the statement applies to any family of subspaces.

Exercise (Arbitrary intersection of vector spaces)

Let   be an arbitrary index set and   a family of subspaces of a vector space  . Then, the intersection   is a subspace of  .

Solution (Arbitrary intersection of vector spaces)

Let   and let   be subspaces of the  -vector space  . The intersection   of all vector spaces   is again a vector space.

Proof step:   is not empty.

Since the   are subspaces, we have   for all   and therefore  . Thus   is not empty.

Proof step:   is closed under Addition.

Let  . Then   holds for all  . Because the   are vector spaces, they are closed under addition and hence   is valid for all  . This means  .

Proof step:   is closed under scalar multiplication.

Let   and  . Then   holds for all  . Since the   are vector spaces, they are closed under scalar multiplication and   is valid for all  . Hence  .

Union of vector spaces

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Is the union of subspaces of a vector space a vector space again? Let us first look at an example.

Example (Coordinate axis cross is not a subspace)

Let  . We choose the coordinate axes   and   as subspaces. Their union is the axis cross in  . Based on the figure, we can already surmise that this is not a subspace of  : There are two "directions", but at the same time   is not the two-dimensional plane. And indeed, the two vectors   and   are in  , but their sum   is not in the union. Therefore,   is not a subspace of  .

 
Union of two lines in two-dimensional real space

So we see that the union of two subspaces is generally not a subspace. Is this always the case?

Example (Union of vector spaces is again a vector space)

We consider the two subspaces   and   of  . As   we have  . Therefore   and the union of the two subspaces is again a subspace.

 
Union of a line with a plane in three-dimensional space

The union of two subspaces is therefore in some cases, but not always, a subspace. In the example,   was contained in  , so that   was a subspace. This always works: If two subspaces are given and one of them is contained in the other, then the union is equal to the larger of the two, i.e. a subspace again.

This is indeed the only case in which the union of two subspaces is again a subspace, as the first example with the coordinate axes makes clear: If   and  , then the union will not be closed under addition. There will then always exist two vectors   with   and  . The sum   thus contains a part that is not in   and therefore cannot be in  : Otherwise,   would also be true. The same applies to  .

We therefore have the following criterion for determining when the union of two subspaces is a subspace.

Theorem (Condition for the union of two vector spaces to be a vector space again)

Let   be a vector space over a field   and let   and   be two subspaces of  . Then   is a subspace of   if and only if   or   holds.

Proof (Condition for the union of two vector spaces to be a vector space again)

Proof step: If   is a subspace of  , then we have   or  .

We prove the statement by contradiction: Assume that neither   nor   is true. We show that   is then not a subspace of  . Instead, we find two elements  , so that  :

Since  , there exists an element   that is not contained in  . Similarly, since  , there exists a   that is not contained in  .

Thus,  . But the sum   is neither in   nor in  : If  , then  , in contradiction to the choice of  . Here we have used the fact that   implies also   and that   is closed under addition. In the same way, you can see that   does not lie in  .

Therefore,   applies. This means that the union   is not closed under addition, i.e. it is not a subspace.

Proof step: If   or  , then   is a vector space

If  , then  , so the union is a subspace. Similarly, it follows from   that   is a subspace.

The proof of the theorem shows that the property of being a subspace fails due to addition. The scalar multiplication on   was not relevant in the proof. In fact,   is always closed under scalar multiplication, even if the union is not a subspace: If   and  , say  , then   holds, since   is closed under scalar multiplication as a subspace. The case   is analogous.

Since   is a vector space and   are subspaces,   forms a group and   subgroups. We have thus effectively shown that   is a subgroup of   if and only if   or   holds. There is a more general statement about (not necessarily commutative) groups. The proof is quite analogous to the proof for subspaces that we have seen above.

Theorem (Union of subgroups)

Let   be a group and   subgroups. Then   is a subgroup of   if and only if   or   holds.

The union of subspaces   and   is generally not a subspace. However, you can define the smallest subspace that contains  . This subspace is the subspace sum  .