Testing the Instanton Approach to the Large Amplification Limit of a Diffraction-Amplification Problem

Abstract

The validity of the instanton analysis approach is tested numerically in the case of the diffraction-amplification problem ∂z -i2m∂2x2 =g S2\, for U 1, where U=(0,L)2. Here, S(x,z) is a complex Gaussian random field, z and x respectively are the axial and transverse coordinates, with 0 z L, and both m 0 and g>0 are real parameters. We consider a class of S, called the `one-max class', for which we devise a specific biased sampling procedure. As an application, p(U), the probability distribution of U, is obtained down to values less than 10-2270 in the far right tail. We find that the agreement of our numerical results with the instanton analysis predictions in Mounaix (2023 J. Phys. A: Math. Theor. 56 305001) is remarkable. Both the predicted algebraic tail of p(U) and concentration of the realizations of S onto the leading instanton are clearly confirmed, which validates the instanton analysis numerically in the large U limit for S in the one-max class.