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I know about the fact that $\operatorname{rank}(A+B) \leq \operatorname{rank}(A) + \operatorname{rank}(B)$, where $A$ and $B$ are $m \times n$ matrices.

But somehow, I don't find this as intuitive as the multiplication version of this fact. The rank of $A$ plus the rank of $B$ could have well more than the columns of $(A+B)$! How can I show to prove that this really is true?

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4 Answers 4

If $f,g:V\to W$ are linear maps, then we have $$(f+g)(V)\subset f(V)+g(V),$$ which implies $$\mathrm{rk}(f+g)=\dim\ (f+g)(V)\le\dim\ (f(V)+g(V))$$ $$\le\dim f(V)+\dim g(V)=\mathrm{rk}(f)+\mathrm{rk}(g).$$ To justify the first display, note that a vector of $W$ is in $(f+g)(V)$ if and only if it is equal to $f(v)+g(v)$ for some $v$ in $V$, whereas it is in $f(V)+g(V)$ if and only if it is equal to $f(v)+g(v')$ for some $v$ and $v'$ in $V$.

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Interesting. Now this is a high road, isn't it? :-D –  user1551 Aug 24 '11 at 16:49

An intuitive picture:

Use the following characterisation of the rank: decompose $A$ into its component column vectors. That is, $A = (a_1, a_2, \ldots, a_n)$, where each $a_i$ is a $m\times 1$ column vector. Then the rank of $A$ is equal to the dimensional of the vector subspace generated by $a_1, \ldots, a_n$.

A vector in the image of $A+B$ is going to be a linear combination of $a_1, \ldots, a_n$ and $b_1, \ldots, b_n$. So we have that the rank of $A+B$ is at most the size of the linear subspace generated by those $2n$ vectors.

But the size of that linear subspace is given by the maximum number of linearly independent vectors one can choose among them. We can choose at most $rank(A)$ many from the $a_i$, and at most $rank(B)$ many from the $b_i$. So this gives an upper bound of $rank(A)+rank(B)$.

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How is $rank(A)+rank(B)$ the upper bound of the rank? The number of independent vectors are surely be less or equals to the number of columns in $(A+B)$. There is this feeling that when $A+B$, the numbers in them add together may be totally off from the original vector direction in $A$ and $B$. –  xenon Aug 24 '11 at 15:25
An over-generous upper bound is still an upper bound. Think of the case where $A$ is the projection onto the $x$ axis, and $B$ the projection onto the $y$ axis, then $rank(A+B) = 2 = 1 + 1 = rank(A) + rank(B)$. Of course you also have trivially that $rank(A+B) \leq \min(m,n)$ just by definition. So you could, if you want, combine the two estimates into $rank(A+B) \leq \min (m,n,rank(A)+rank(B))$. –  Willie Wong Aug 24 '11 at 15:35
ahh..Thanks a lot! :) –  xenon Aug 24 '11 at 15:57

Let the columns of $A$ and $B$ be $a_1, \ldots, a_n$ and $b_1, \ldots, b_n$ respectively. By definition, the rank of $A$ and $B$ are the dimensions of the linear spans $\langle a_1, \ldots, a_n\rangle$ and $\langle b_1, \ldots, b_n\rangle$. Now the rank of $A + B$ is the dimension of the linear span of the columns of $A + B$, i.e. the dimension of the linear span $\langle a_1 + b_1, \ldots, a_n + b_n\rangle$. Since $\langle a_1 + b_1, \ldots, a_n + b_n\rangle \subseteq \langle a_1, \ldots, a_n, b_1, \ldots, b_n\rangle$ the result follows.

Edit: Let me elaborate on the last statement. Any vector $v$ in $\langle a_1 + b_1, \ldots, a_n + b_n\rangle$ can be written as some linear combination $v = \lambda_1 (a_1 + b_1) + \ldots + \lambda_n (a_n + b_n)$ for some scalars $\lambda_i$. But then we can also write $v = \lambda_1 (a_1) + \ldots + \lambda_n (a_n) + \lambda_1 (b_1) + \ldots + \lambda_n (b_n)$. This implies that also $v \in \langle a_1, \ldots, a_n, b_1, \ldots, b_n\rangle$. We can do this for any vector $v$, so

$$\forall v \in \langle a_1 + b_1, \ldots, a_n + b_n\rangle: v \in \langle a_1, \ldots, a_n, b_1, \ldots, b_n\rangle$$

This is equivalent to saying $\langle a_1 + b_1, \ldots, a_n + b_n\rangle \subseteq \langle a_1, \ldots, a_n, b_1, \ldots, b_n\rangle$.

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How is it that $\langle a_1 + b_1, \ldots, a_n + b_n\rangle \subseteq \langle a_1, \ldots, a_n, b_1, \ldots, b_n\rangle$? It feels like the $a_i + b_i$ may totally change the angle in the subspace and may not be of any multiple of $\langle a_1, \ldots, a_n, b_1, \ldots, b_n\rangle$ and not a subset. –  xenon Aug 24 '11 at 15:13
@xEnOn: The span allows linear combinations. You may wish to review the definition of the linear span. –  Willie Wong Aug 24 '11 at 15:36
+1. Nice answer! [But I slightly prefer the version before the edit: If $V$ is a vector space, and $v_1,...,v_m,w_1,...,w_n$ are vectors of $V$, then $\langle v_1,...,v_m\rangle\subset\langle w_1,...,w_n\rangle$ just means that each $v_i$ is a linear combination of the $w_j$. - It's not really necessary to mention the linear combinations of the $v_i$. (But that's a detail.)] –  Pierre-Yves Gaillard Aug 24 '11 at 18:01

It suffices to show that, Row rank $(A + B)$ ≤ Row rank $A + $Row rank $B$ $(see~here)$

i.e. to show $\dim <a_1 + b_1, a_2 + b_2, …, a_n + b_n>$$\leq \dim <a_1, a_2, … , a_n>$$+\dim <b_1, b_2,$$..., b_n>$ [Letting the row vectors of A and B as $a_1, a_2, … , a_n$ and $b_1, b_2,…, b_n$ respectively]

Let $\{A_1, A_2, …, A_p\}$ & $\{B_1, B_2, … , B_q\}$ be the bases of & respectively.

Case I: $p, q ≥ 1$ Choose $v\in<a_1 + b_1, a_2 + b_2, …, a_n + b_n>$ Then $v = c_1(a_1 + b_1) + … + c_n(a_n + b_n) [$for some scalars $c_i] = ∑c_i (∑g_jA_j) + ∑c_i(∑h_kB_k)$ [for some scalars $g_j, h_k$] i.e. $dim <a_1 + b_1, a_2 + b_2, …, a_n + b_n> \le p + q$. Hence etc.

Case II: $p = 0$ or $q = 0$: One of the bases is empty & the corresponding matrix becomes zero. Rest follows immediately.

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