Is there any known theory for equations like $a_1 x^{y_1} + a_2 x^{y_2} +..a_nx^{y_n}=0$ where the $y_i$'s are arbitrary irrationals? Can you say anything about the disposition of roots?
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2$\begingroup$ Note that even an absurdly simple special case, $x^{\pi}=1$, has an infinity of solutions, $x=e^{2ni}$, $n=0,\pm1,\pm2,\dots$. $\endgroup$– Gerry MyersonCommented Nov 5, 2010 at 20:56
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1$\begingroup$ @Gerry: ...which implies, by the way, that $\pi$ is not a rational number.:) $\endgroup$– user6976Commented Nov 5, 2010 at 21:19
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$\begingroup$ Does the Gauss-Lucas theorem hold for such polynomials? $\endgroup$– J.C. OttemCommented Nov 5, 2010 at 21:56
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$\begingroup$ A side remark about the tag: if $y_i$'s are arbitrary irrationals, are the expressions still polynomials? $\endgroup$– Willie WongCommented Nov 6, 2010 at 0:10
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$\begingroup$ Well, I always thought that tagging in MathOverflow (unlike StackOverflow) was a matter of "best approximation". $\endgroup$– GaneshCommented Nov 8, 2010 at 17:57
1 Answer
Note that these are simply a special case (generalization? depending on terminology) of exponential polynomials.
Or rather, to be more accurate, they can be treated as such. Let $t=\ln x$, and then your monomials become $a_i e^{ty_i}$. The change of variables does introduce some technical issues, obviously (in dimension $n$, you need to do it separately for each of the $2^n$ quadrants, and then possibly iterate on the coordinate zero hyperplanes).
Over the complexes, as was pointed out by Gerry, there is potentially infinitely many roots. Over the reals, the number of roots is still finite, and some of the elementary results like Descartes's rule of signs do translate fairly well to that setting. (The fact that for ordinary polynomials, the derivative is either 0 or has fewer roots is not so crucial in many applications).
In several variables, the theory of fewnomials developed by Khovanskii gives some (pessimistic) upper bounds on the number of real roots (it also gives some restrictions on the patterns of the complex roots).
None of this is overly difficult, but I don't see the point of going into more details without a more specific question.
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$\begingroup$ @Thierry: Perhaps I do not understand something in your answer, but why $x^{\sqrt{2}}$ an exponential polynomial? $\endgroup$– user6976Commented Nov 6, 2010 at 1:35
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$\begingroup$ @Mark: You're right, my original answer is a bit sloppy. I'll fix this. $\endgroup$ Commented Nov 6, 2010 at 1:47
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1$\begingroup$ @Thierry: By definition an exponential polynomial is $P(x_1,...,x_k, e^{y_1},...,e^{y_m}$, where $P$ is a polynomial. So $e^{t\sqrt{2}}$ is not an exponential polynomial? Right? $\endgroup$– user6976Commented Nov 6, 2010 at 9:17
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1$\begingroup$ @Mark: Oh I see: it's a terminology issue. Many people use "exponential polynomial" for any polynomial that shows up in Khovanskii theory, i.e. of the form $\exp \langle a \mid y \rangle$, because in that context, there's no reason to distinguish between exponential of a variable and of a linear combination of variables. Sorry for the confusion... $\endgroup$ Commented Nov 6, 2010 at 15:21
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$\begingroup$ Terminology continued: here is another example of a recent question using the more generalized meaning of exponential polynomial: mathoverflow.net/questions/45031/… $\endgroup$ Commented Nov 6, 2010 at 15:35