I have a matrix $$A(x) = \frac{-1}{(1+\|x\|_2^2)^{\frac{3}{2}}}xx^T + \frac{1}{(1+\|x\|_2^2)^{\frac{1}{2}}}I$$ I see that $$\|A(x)\|_2 \le 1 \ \forall x$$
But is $\|A(x)\| \le 1$ in general $\forall x$ and if so, how to show this?.
Yes indeed [Iosif Pinelis] and [Denis Serre], i switched the order. Yes, I am referring to operator norm. Is it correct that $\|A(x)\| \le 1 \forall x$?
$\newcommand\R{\mathbb R}$As noted by Denis Serre and Christian Remling, the exponents $1/2$ and $3/2$ must be interchanged -- otherwise, $\|A(x)\|_2\to\infty$ if $x=tu$, $u$ is a fixed unit vector, and $t\to\infty$.
So, the meaningful re-interpretation of the question is as follows:
Let $$A(x) := \frac{-xx^T}{(1+\|x\|_2^2)^{3/2}} + \frac{I}{(1+\|x\|_2^2)^{1/2}}$$ for $x\in\R^n$. Is it true that $\|A(x)\|\le1$ for all $x\in\R^n$, where $\|\cdot\|$ is an operator norm?
The answer to this question is no, even if the same norm is used on the domain and the co-domain of the linear operator corresponding to the matrix $A(x)$. (If different norms are allowed to be used for the domain and the co-domain, then the no answer is quite obvious.)
For instance, suppose that $n=5$, $\|\cdot\|$ is the operator norm induced by the $\ell^\infty$ norm on $\R^5$, $x=\frac1{1000}(160, 159, 197, -159, -160)$, and $y=(1, 1, -1, -1, -1)$. Then $\|y\|_\infty=1$ but $$\|A(x)\|\ge\|A(x)y\|_\infty=1.0076\ldots>1.$$
However, since $0\le xx^T\le\|x\|_2^2\,I$, we have $0\le(1+\|x\|_2^2)^{-3/2}\,I\le A(x)\le(1+\|x\|_2^2)^{-1/2}\,I$ and hence $\|A(x)\|_2\le(1+\|x\|_2^2)^{-1/2}\le1$, for all $x\in\R^n$.
