Peetre conjecture on real interpolation spaces of Besov spaces and Grid K functional

Abstract

In this paper, Peetre's conjecture about the real interpolation space of Besov space is solved completely by using the classification of vertices of cuboids defined by wavelet coefficients and wavelet's grid structure. Littlewood-Paley analysis provides only a decomposition of the function on the ring. We extend Lorentz's rearrangement function and Hunt's Marcinkiewicz interpolation theorem to more general cases. We use the method of calculating the topological quantity of the grid to replace the traditional methods of data classification such as gradient descent method and distributed algorithm. We developed a series of new techniques to solve this longstanding open problem. These skills make up for the deficiency of Lions-Peetre iterative theorem in dealing with strong nonlinearity. Using the properties of wavelet basis, a series of functional nonlinearities are studied. Using the lattice property of wavelet, we study the lattice topology. By three kinds of topology nonlinearities, we give the specific wavelet expression of K functional.