somewhere near the beginning.

Musings on the matrix problem

Filed under: Mathematics — Alex @ 8:56 am 6/15/2006

In the last post, I asked if there exist square matrices A,B such that AB-BA = I. This came up in class just after we discussed the spectral mapping theorem, so I was attempting to use that to attack this, but it turns out (as Shikha pointed out) the easiest way is to just look at the trace of both sides. I still haven’t figured out a proof using spectrums, but Dr. Singh assures us the proof will be straightforward once we see a little more machinery.

I found out something interesting this morning, while browsing through ‘Vector Calculus, Linear Algebra, and Differential Forms’ by Hubbard and Hubbard. Recall that the Frechet derivative of a function f : X \rightarrow Y at x\in X, where X,Y are normed linear spaces, is the unique linear transformation Df(x) : X \rightarrow Y satisfying

\displaystyle \lim_{h\rightarrow 0} \frac{\|f(x+h)-f(x)-Df(h)\|_Y}{\|x\|_X} = 0.

You can show that if you consider M_n (the set of square matrices of order n) as a normed space and look at the squaring function S: M_n \rightarrow M_n defined by S(A)=A^2, then

[DS(A)](B) = AB - BA.

This shines a new light on the fact that there are no A,B such that AB-BA = I, but what are the consequences of this fact on DS and S?

On a not-so-related note, the same book shows a nice generalization of the derivation of the convergence of geometric series to matrices. If \|A\| < 1 and S_n = \sum_{k=0}^n A^k, then S_n \rightarrow (I-A)^{-1}. Pretty neat!

(In all the arguments above, they used the Frobenius norm-- I don't think that matters, however, since M_n is finite-dimensional, so all norms are equivalent.)

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