first, I know that there exists a similar question to mine which is in here, and it is actually very well explained. However, there is just one part that I do not understand. That is the conclusion. First, how did they conclude that norm of Matrix $A$ is less than the maximum column sum of matrix $A$? Then how did they conclude that it did not the inequality turned into equality?
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The one-norm of $A=(a_{ij})$ is defined as the maximum of $\Vert Ax\Vert_{1}$ with respect to all vectors $x$ which are unit in the one-norm. In other words, $$ \Vert A\Vert_{1}=\max_{\Vert x\Vert_{1}=1}\Vert Ax\Vert_{1}. $$ In the answer you link to, the author first shows that for any vector $x$ satisfying $\Vert x \Vert_1 = 1$, $$ \Vert Ax\Vert_{1}\leq\max_{j}\sum_{i}|a_{ij}|=\sum_{i}|a_{im}| $$ where $j=m$ is some index that maximizes the expression on the right hand side of the above inequality. Next, the author notes that the standard basis vector $e_{m}$ (i.e., the vector whose $m$-th entry is 1 and whose other entries are zero) satisfies $$ \Vert e_{m}\Vert_{1}=1\qquad\text{and}\qquad\Vert Ae_{m}\Vert_{1}=\sum_{i}|a_{im}|. $$ Putting this all together, $$ \sum_{i}|a_{im}|=\Vert Ae_{m}\Vert_{1}\leq\Vert A\Vert_{1}\leq\max_{j}\sum_{i}|a_{ij}|=\sum_{i}|a_{im}|. $$ Since the leftmost and rightmost expressions are identical, it follows that all of the inequalities above must be equalities. The desired result follows.
parsiad
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1Probably you want to write $\vert a_{ij}\vert$ instead of $a_{ij}$. – Jens Schwaiger Feb 04 '19 at 07:49
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Heyy, really like your answer, if you could help with an exercise, would really appreciate it :) https://math.stackexchange.com/questions/3096022/normed-vector-space-schauder-basis-exercise – Homaniac Feb 04 '19 at 08:42
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@JensSchwaiger: +1. Thanks for catching that. – parsiad Feb 04 '19 at 18:07