Abstract <p> We study multidimensional integral equations with monotonic and odd nonlinearity. These equations have applications in the dynamic theory of <InlineEquation ID="IEq2"> <EquationSource Format="TEX">\(p\)</EquationSource> </InlineEquation>-adic strings. In particular, when the nonlinearity is power-law and the kernels are represented as Gaussian distributions, these equations describe the dynamics (rolling) of <InlineEquation ID="IEq3"> <EquationSource Format="TEX">\(p\)</EquationSource> </InlineEquation>-adic open or open–closed strings for a scalar tachyon field. Under certain restrictions on nonlinearity and kernels, we prove the constructive solvability of the equation in the space of continuous and bounded functions. We establish the uniform convergence of the corresponding successive approximations (with a rate of infinitely decreasing geometric progression) to the solution. We prove that the equation under study can simultaneously have alternating and sign-preserving bounded solutions. The results obtained are applied to specific problems in the dynamic theory of <InlineEquation ID="IEq4"> <EquationSource Format="TEX">\(p\)</EquationSource> </InlineEquation>-adic strings and in solving a nonlinear boundary value problem for the heat conduction equation. </p>

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On the constructive solvability of a class of nonlinear multidimensional integral equations in the theory of \(p\)-adic strings

  • A. Kh. Khachatryan,
  • Kh. A. Khachatryan,
  • H. S. Petrosyan

摘要

Abstract

We study multidimensional integral equations with monotonic and odd nonlinearity. These equations have applications in the dynamic theory of \(p\) -adic strings. In particular, when the nonlinearity is power-law and the kernels are represented as Gaussian distributions, these equations describe the dynamics (rolling) of \(p\) -adic open or open–closed strings for a scalar tachyon field. Under certain restrictions on nonlinearity and kernels, we prove the constructive solvability of the equation in the space of continuous and bounded functions. We establish the uniform convergence of the corresponding successive approximations (with a rate of infinitely decreasing geometric progression) to the solution. We prove that the equation under study can simultaneously have alternating and sign-preserving bounded solutions. The results obtained are applied to specific problems in the dynamic theory of \(p\) -adic strings and in solving a nonlinear boundary value problem for the heat conduction equation.