The convergence condition for improper short integrals in terms of Newton polytopes

The article considers multidimensional improper integrals of functions that are the product of generalized polynomials in some degrees. Such integrals are found in many branches of
mathematics and theoretical physics. In particular, they include Feynman integrals arising in the study of various objects of quantum field theory. The exact calculation of these integrals is a
difficult and not always possible task; therefore, determining the conditions for their convergence and obtaining their asymptotic expansion in one of the parameters is of considerable practical
interest. The convergence conditions for the integrals considered in the article can still be used, for example, in the study of multiple series representing the sum of the values of a rational
function at the nodes of an integer lattice.
The article considers the problem when the integration area is R+^n, and the generalized polynomials included in the integrand are either positive everywhere except zero or have positive
coefficients. The convergence set of these integrals is described and the equivalence of the convergence condition to the condition on the Newton polytopes of polynomials in integrands
is proved.

The convergence criterion proved in the paper coincides in formulation with the corresponding result of the work of A. K. Tsikh and T. O. Ermolaeva, but it was obtained by other
methods and for a slightly wider set of integrands.
The proofs of the statements in the paper are based on the simplest properties of convex polytopes and basic facts from the theory of improper multiple integrals.

1. Hwa, R., Teplitz, V. 1966, “Homology and Feynman integrals“, New York, Amsterdam.

2. Pham, F. 1967, “ Introduction a l’etude topologique des singularites de Landau“, Gauthiervillars Editeur, Paris.

3. Beneke, M., Smirnov, V. A. 1998, “Asymptotic expansion of Feynman integrals near threshold“, Nuclear Physics B, vol. 522, pp. 321-344.

4. Pak, A., Smirnov, A. V. 2011, “Geometric approach to asymptotic expansion of Feynman integrals“, European Physical Journal C, vol. 71, pp. 1626-1631.

5. Lee, R. N., Pomeransky, A. A. 2013, “Critical points and number of master integrals“, Journal of High Energy Physics, vol. 165, pp. 1311-1326.

6. Semenova, T. Yu . 2019, “Asymptotics of Feynman integrals in one-dimensional case“, Moscow University Mathematics Bulletin, vol. 74, no. 4, pp. 163-166.

7. Semenova, T. Yu. 2020, “Asymptotic series for a Feynman integral in the one-dimensional case“, Russian Journal of Mathematical Physics, vol. 27, no. 1, pp. 126-136.

8. Zubchenkova, E. V. 2011, “ Integral convergence criterion for the multiple series“, Journal of Siberian Federal University. Mathematics & Physics, 4 (3), pp. 344–349.

9. Zubchenkova, E. V. 2014, “On the integral criterion of convergence for multidimensional Dirichlet series“, Siberian Electronic Mathematical Reports, no. 11, pp. 76-86.

10. Semenova, T. Yu., Smirnov, A. V. & Smirnov, V. A. 2019, “On the status of expansion by regions“, European Physical Journal C, vol. 79, pp. 136-147.

11. Tsikh, A. K. 1989, “Integrals of rational functions over space 𝑅𝑛“, Proceedings of the USSR Academy of Sciences, vol. 307, no. 6, pp. 1325-1329.

12. Ermolaeva, T. O., Tsikh, A. K. 1996, “Integration of rational functions over 𝑅𝑛 by means of toric compactifications and multidimensional residues“, Sb. Math., 187 (9), pp. 1301-1318.

13. Rockafellar, R. 1973, “Convex analysis“, Princeton, New Jersey, Princeton University Press.

14. Alexandrov, A. D. 1950, “Convex polytopes“, Moscow, World.

15. Brøndsted, A. 1983, “An introduction to convex polytopes“, New York–Heidelberg–Berlin, Springer-Verlag.

16. Gr¨unbaum, B. 1967, “Convex polytopes“, London, Interscience Publ. 17. Hardy, G., Littlewood, J. & Polia, G. 2008, “Inequalities“, Moscow, URSS.