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Title: Extending x^x Post by Icarus on Feb 9th, 2008, 4:38pm Oddly enough, this question was not inspired by other appearances of xx lately: If we restrict ourselves to the real numbers, the function f(x) = xx is generally considered for x >=0 only. However values can also be defined for x < 0 when x is a rational number with odd denominator (in lowest terms). If we restrict the numerator to evens, the values of xx are even positive. Since rationals with even numerators and odd denominators are dense, we can use this to extend f(x) to the entire real line. In particular, let D = { 2p/q : gcd(2p,q) = 1}, and consider xx defined on D. For all t http://www.ocf.berkeley.edu/~wwu/YaBBImages/symbols/in.gif http://www.ocf.berkeley.edu/~wwu/YaBBImages/symbols/bbr.gif, define f(t) = limxhttp://www.ocf.berkeley.edu/~wwu/YaBBImages/symbols/subto.gift; xhttp://www.ocf.berkeley.edu/~wwu/YaBBImages/symbols/subin.gifD xx. How differentiable is f? I.e., for what values of k is f http://www.ocf.berkeley.edu/~wwu/YaBBImages/symbols/in.gifCk? Is f analytic? |
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Title: Re: Extending x^x Post by Obob on Feb 10th, 2008, 11:42am For all x in D, we have xx=|x|x since the numerator of x is even. But |x|x is defined and continuous on the whole negative real axis, so f=|x|x. Clearly then f is infinitely differentiable on the whole negative real axis. In fact, f is analytic. For on the negative real axis we can write |x|x=(-x)x. The function (-z)z is a multi-valued analytic function on the punctured complex plane C-{0} which is single-valued on the negative real axis and coincides with f there. |
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Title: Re: Extending x^x Post by temporary on Feb 10th, 2008, 12:22pm on 02/09/08 at 16:38:40, Icarus wrote:
Since when is f(x)=x^x only defined to x>=0? |
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Title: Re: Extending x^x Post by Icarus on Feb 10th, 2008, 12:47pm You might want to try some reading comprehension courses, temporary. You don't seem to be very good at it. I didn't say that x^x was only defined for x > 0. In fact a part of what I said is that it can be defined for some x < 0. |
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Title: Re: Extending x^x Post by Icarus on Feb 10th, 2008, 12:49pm on 02/10/08 at 11:42:33, Obob wrote:
I seem to be overly complicating things lately. I should have put this in Easy, not Putnam! |
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Title: Re: Extending x^x Post by Obob on Feb 10th, 2008, 1:29pm I suppose I did gloss over one point: f is not differentiable at 0. But this shouldn't be surprising, since limx->0+ d(xx)/dx = -infty. |
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