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July 28

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"Root mean-n-power"

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Let A be a (finite) sequence of b nonnegative real numbers with nth term denoted by an. Define .

For m = 1, is simply the ordinary mean, while is the root mean square. We know that where max(A) is the biggest number of A, as can be demonstrated by L'hôpital's rule, assuming there is a unique maximum (i.e. there are not two numbers for max(A)).

My question is then whether I can claim the same in the continuous case. Let f(x) be a continuous function on the positive real line that doesn't take negative values. Then, over an interval [c, d] somewhere on the positive real line with d > c, ; d could possibly be infinite, in which case it must be assumed that f vanishes sufficiently quickly for the integral to always converge. Unfortunately, my technique using L'hôpital's rule fails to resolve the question because in a quotient of integrals (as I obtain) you cannot cancel factors in the integrands. I do know that integrals are defined as the limit of finite Riemann sums, each of which can have the discrete method for F applied, but I am also wary of the interchange of limiting operations.--Jasper Deng (talk) 19:16, 28 July 2015 (UTC)[reply]

See also Power mean inequality. --JBL (talk) 19:39, 28 July 2015 (UTC)[reply]
Thanks, I had been looking for the name of the discrete case. And it turns out that it's not even necessary for max(A) to be unique.--Jasper Deng (talk) 19:44, 28 July 2015 (UTC)[reply]
Since f is continuous on a closed interval it has a maximum M and some x for which (I'll assume but the proof is the same if x is c or d). For every there is such that . Then . So . Since the second term goes to 1 as , . This is true for every so . It is obviously not greater, so it is equal to the maximum. -- Meni Rosenfeld (talk) 07:48, 29 July 2015 (UTC)[reply]
Thanks. What an elegant proof that didn't even rely on interchanging limits!--Jasper Deng (talk) 08:29, 29 July 2015 (UTC)[reply]
More generally, a similar proof will show that for any measurable function f on a finite measure space (X,μ), tends to the essential supremum of f as . (It's also true for an integrable function, without the assumption that the measure space is finite.) Sławomir
Biały
11:22, 29 July 2015 (UTC)[reply]