2
$\begingroup$

In order to prove a larger assumption, I need to find a vector norm over $M_n$ such that $\|I\| < 1$. None of the standard $p$-norms, nor the infinity norm work. I know that for matrix norms, this is impossible, but I think it should be possible with a vector norm since I don't have to worry about submultiplicativity.

Any hints would be greatly appreciated. Proving an example is in fact a norm is within my grasp, I just need some idea about how to construct an example.

  • 0
    @brc: you're welcome2011-11-01

1 Answers 1

1

If I do understand you correct, you're trying to find a norm $\|\cdot\|$on $n$-dim vector space $V_n$ such that the corespondent matrix norm is given by \|A\|' := \sup\limits_{v\in V_n\setminus\{0\}}\frac{\|Av\|}{\|v\|}. If $A = I$ (which is identity matrix I assume) then \|I\|' = 1 since the fraction is always $1$ because$Iv = v$ for any $v\in V_n$.

If you're looking for a norm on the space of $n$-dim matrices $M_n$ then you can just put a norm $\|A\| = \frac1{2n}\sum\limits_{ij}|a_{ij}|.$

  • 0
    I think the OP's statement "I know that for matrix norms, this is impossible" shows the OP understands this, and he or she isn't looking for such norms.2011-11-01