Geometric Optimization of Quantum Control with Minimum Cost

We study the optimization of quantum control from the perspective of differential geometry. Here, optimal quantum control takes the minimum cost of transporting a quantum state. By defining a cost function, we quantify the cost by the length of a trajectory in the relevant Riemannian manifold. We demonstrate the optimization protocol using SU(2) and SU(1,1) dynamically symmetric systems, which cover a large class of physical scenarios. For these systems, time evolution is visualized in the three-dimensional manifold. Given the initial and final states, the minimum-cost quantum control corresponds to the geodesic of the manifold. When the trajectory linking the initial and final states is specified, the minimum-cost quantum control corresponds to the geodesic in a sub-manifold embedded in the three-dimensional manifold. Optimal quantum control in this situation provides a geometrical means of optimizing shortcuts to adiabatic driving.
Comment: 7 pages, 4 figures