On the regular convergence of multiple series of numbers and multiple integrals of locally integrable functions over m+

Abstract

We investigate the regular convergence of the m-multiple series Σ∞j1=0 Σ∞j2=0...Σ∞jm=0 \ cj1, j2,..., jm≤no(*) of complex numbers, where m 2 is a fixed integer. We prove Fubini's theorem in the discrete setting as follows. If the multiple series (*) converges regularly, then its sum in Pringsheim's sense can be computed by successive summation. We introduce and investigate the regular convergence of the m-multiple integral ∫∞0 ∫∞0...∫∞0 f(t1, t2,..., tm) dt1 dt2...dtm,≤no(**) where f: m+ is a locally integrable function in Lebesgue's sense over the closed positive octant m+:= [0, ∞)m. Our main result is a generalized version of Fubini's theorem on successive integration formulated in Theorem 4.1 as follows. If f∈ L1 (m+), the multiple integral (**) converges regularly, and m=p+q, where m, p∈ +, then the finite limit vp+1,..., vm ∞ ∫v1u1 ∫v2u2...∫vpup ∫vp+10...∫vm0 f(t1, t2,..., tm) dt1 dt2...dtm =:J(u1, v1; u2, v2;...; up, vp), 0 uk vk<∞, \ k=1,2,..., p, exists uniformly in each of its variables, and the finite limit v1, v2,..., vp ∞ J(0, v1; 0, v2;...; 0, vp)=I also exists, where I is the limit of the multiple integral (**) in Pringsheim's sense.