English

The d'Alembert Inevitability Theorem

Classical Analysis and ODEs 2026-04-22 v2

Abstract

We study functions satisfying the composition law F(xy)+F(x/y)=P(F(x),F(y))F(xy)+F(x/y)=P(F(x),F(y)) with a symmetric polynomial combiner PP. We prove that symmetry together with a quadratic degree bound on PP forces a composition law of d'Alembert type. We establish a degree mismatch exclusion criterion showing that symmetric polynomial combiners with \mboxdegP(u,v)3\mbox{deg} P(u,v) \ge 3 do not admit nonconstant continuous solutions, provided the leading term does not cancel (Theorem 3.1.). For continuous nonconstant functions F:R>0RF:\mathbb{R}_{>0}\to\mathbb{R} with F(1)=0F(1)=0 satisfying the composition law with a symmetric polynomial PP of degree at most two, the combiner is necessarily of the form P(u,v)=2u+2v+cuvP(u,v)=2u+2v+c\,uv, cRc\in\mathbb{R} (Theorem 3.3.). The equation reduces in logarithmic coordinates to the classical d'Alembert functional equation. For c0c\neq 0, one obtains hyperbolic or trigonometric branches, while c=0c=0 yields the squared-logarithm family. Under the cost-function assumptions F0F\ge 0 and convexity, only the hyperbolic branch with c>0c>0 remains. A unit log-curvature calibration selects the canonical value c=2c=2, which yields the canonical reciprocal cost F(x)=12(x+x1)1F(x)=\tfrac12(x+x^{-1})-1. For c0c\neq0, the result extends to R>0n\mathbb{R}_{>0}^n: every solution depends only on a single linear combination of coordinate logarithms; for c=0c=0, the solution is a general quadratic form i,jaijlnxilnxj\sum_{i,j}a_{ij}\ln x_i\ln x_j. In either case, nontrivial coordinate-wise separable costs are excluded.

Keywords

Cite

@article{arxiv.2603.16237,
  title  = {The d'Alembert Inevitability Theorem},
  author = {Jonathan Washburn and Milan Zlatanović and Elshad Allahyarov},
  journal= {arXiv preprint arXiv:2603.16237},
  year   = {2026}
}
R2 v1 2026-07-01T11:23:45.970Z