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If $S$ is the subspace of $M_7(R)$ consisting of all upper triangular matrices, then $dim(S)$ = ?

So if I have an upper triangular matrix $ \begin{bmatrix} a_{11} & a_{12} & . & . & a_{17}\\ . & a_{22} & . & . & a_{27}\\ . & . & . & . & .\\ 0 & . & . & . & a_{77}\\ \end{bmatrix} $

It looks to me that this matrix can potentially have 7 pivots, therefore it is linearly independent and so it will take all 7 column vectors to span it. But that answer is marked as incorrect when I enter it so what am I missing here?

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    You shouldn't be thinking of the dimension of the row or column space - how might you write a matrix in co-ordinates? In other words, how many values do you have to specify in order to uniquely determine an upper triangular matrix in $M_7(R)$?2012-03-19

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I guess the answer is 1+2+3+...+7=28. Because every element in matrices in S can be a base in that space.

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    A basis of $M_7(R)$ is given by the set of matrices with a $1$ in a single entry and $0$s elsewhere - there are $49$ of these. As you have no restrictions on the values of $a_{11},a_{12},\ldots,a_{77}$, the same argument works here and you can just count the number of entries which can be non-zero.2012-03-19
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In general, an $n\times n$ matrix has $n(n-1)/2$ off-diagonal coefficients and $n$ diagonal coefficients. Thus the dimension of the subalgebra of upper triangular matrices is equal to $n(n-1)/2+n=n(n+1)/2$.

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First you need to check whether it is a subspace. If yes, in order to determine the dimension, no need to find a basis. Just count the degree of freedoms, which is equal to the dimension. I think this method applies to more complicated spaces.