Explicit Inverse Confluent Vandermonde Matrices with Applications to Exponential Quantum Operators

TL;DR

This paper presents a compact formula for the inverse of confluent Vandermonde matrices, enabling explicit solutions for exponential quantum operators and time evolution in finite quantum systems, simplifying complex matrix functions.

Contribution

It introduces a highly compact, single-equation formula for the inverse of confluent Vandermonde matrices, facilitating explicit solutions in quantum dynamics and matrix functions.

Findings

Explicit inverse formula for confluent Vandermonde matrices

Simplified solutions for exponential quantum operators

Explicit solutions for Schrödinger and von Neumann equations

Abstract

The Cayley-Hamilton problem of expressing functions of matrices in terms of only their eigenvalues is well-known to simplify to finding the inverse of the confluent Vandermonde matrix. Here, we give a highly compact formula for the inverse of any matrix, and apply it to the confluent Vandermonde matrix, achieving in a single equation what has only been achieved by long iterative algorithms until now. As a prime application, we use this result to get a simple formula for explicit exponential operators in terms of only their eigenvalues, with an emphasis on application to finite discrete quantum systems with time dependence. This powerful result permits explicit solutions to all Schr\"odinger and von Neumann equations for time-commuting Hamiltonians, and explicit solutions to any degree of approximation in the non-time-commuting case. The same methods can be extended to general finite discrete open systems to get explicit quantum operations for time evolution using effective joint systems, and the exact solution of all finite discrete Baker-Campbell-Hausdorff formulas.