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If $A, \phi \in \mathsf{GL}(V)$ where $V$ is a normed vector space and we are using the operator norm on $\mathsf{GL}(V)$, I'm trying to show that

$ \frac{ \|\phi^{-1}\|^{2} \| A - \phi \| }{1 - \| \phi^{-1}(A - \phi) \|} < \| \phi^{-1} \|^2 \|A - \phi\| $

whenever

$ \|A - \phi \| < \frac{1}{ \|\phi^{-1}\|} $

I have tried various approaches to this but none of them seem to work out. About the only thing I've been able to conclude is that the denominator is nonnegative but this doesn't seem to help with the estimation. I'm sure there's some algebra trick I could employ to see this but, if so, I cannot see it and would appreciate any constructive pointers on how to proceed.

If it helps, the context of this is a proof to show that the function that carries an operator to its inverse is continuous.

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    If somebody on here tells me one more time that something is "obvious", I'm going to change my username to ItsNotFreakingObvious. In fact, I'm going to do that anyway, no need to wait. If it were "obvious" to me I would not have asked the question in the first place.2012-03-11

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Observe that $\|\phi^{-1}(A-\phi)\|\leq \| \phi^{-1}\| \| A-\phi\|<1$. Thus, for $A\ne \phi$, it follows that $0<\| \phi^{-1}(A-\phi)\|<1$. Hence the opposite inequality holds by multiplying each side by the denominator and cancelling common factors.

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    The equation you are trying to prove has the term $\| \phi^{-1}\|^2\| A-\phi\|$ on both sides of the inequality. So you can cancel them if they are positive.2012-03-11