Replace “has three cube roots” by “has three or more cube roots” in what I wrote. Jim Propp On Wednesday, May 30, 2018, James Propp <jamespropp@gmail.com> wrote:
There’s a fun resemblance between the sums of squares game and the sums of palindromes game. In both cases, the number of special numbers up to N is about sqrt(N), arbitrarily large numbers can’t be written as the sum of three special numbers, and every sufficiently large number can be written as the sum of four special numbers.
Here’s a somewhat forced way to continue the story, but maybe it leads somewhere. Given a modulus m such that Z/mZ has three cube roots of 1, say that an (m-1)-digit integer is a “3-drome” if the ith digit equals the jth digit whenever i^3 and j^3 are congruent mod m. The number of 3-dromes up to N is about N^(1/3), as is the number of positive perfect cubes up to N; are the additive number theory properties of the set of all 3-dromes analogous to the additive number theory properties of the set of all positive perfect cubes?
My guess is “no”, as I expect that there are big gaps in the set of 3-dromes, corresponding to long runs of moduli m for which 1 does not have 3 cube roots. But maybe someone can see a way to fix my definition to make the analogy work.
Jim Propp
On Wednesday, May 30, 2018, Eugene Salamin via math-fun < math-fun@mailman.xmission.com> wrote:
https://www.ams.org/journals/proc/1957-008-02/S0002-9939-19 57-0085275-8/S0002-9939-1957-0085275-8.pdf
A positive integer is the sum of three squares unless it is of the form 4^a (8n+7).
-- Gene
On Wednesday, May 30, 2018, 5:40:02 PM PDT, Allan Wechsler < acwacw@gmail.com> wrote:
I remembered that somebody had asked, but I couldn't remember in what forum. I should have searched. And I don't think anybody mentioned, at the time, that the corresponding problem for 2 cubes was completely solved. (I believe that sums of 3 squares have been characterized completely, am I right?)
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