Explore an efficient quantum algorithm for solving dissipative nonlinear differential equations in this 38-minute lecture by Andrew Childs from the University of Maryland. Delve into the challenges of applying quantum computing to nonlinear problems and discover how Carleman linearization can be used to overcome these obstacles. Learn about the algorithm's improved performance compared to classical methods, its potential applications in biology, fluid dynamics, and plasma physics, and understand the theoretical limits of quantum algorithms for quadratic differential equations. Gain insights into the convergence theorem for Carleman linearization, discretization techniques, and the use of the forward Euler method in combination with the quantum linear system algorithm.
Efficient Quantum Algorithm for Dissipative Nonlinear Differential Equations
Institute for Pure & Applied Mathematics (IPAM) via YouTube
Overview
Syllabus
Introduction
Background
Classical vs Quantum Computing
Quantum Linear Systems
Linear Differential Equations
Nonlinear Differential Equations
Algorithm
Linearization
Taught by
Institute for Pure & Applied Mathematics (IPAM)
