TY - JOUR
T1 - Optimal control with accelerated convergence
T2 - Combining the Krotov and quasi-Newton methods
AU - Eitan, Reuven
AU - Mundt, Michael
AU - Tannor, David J.
N1 - Minerva Foundation; EU Marie-Curie-Network EMALI; National Science Foundation [PHY05-51164]This work was supported by the Minerva Foundation and by the EU Marie-Curie-Network EMALI. The authors would like to thank KITP for the generous hospitality during a program on Quantum Control of Light and Matter during which a collective effort was initiated to compare the efficiency of quantum control algorithms. Particular thanks are due to Dr. Ilya Kuprov who drew our attention to the BFGS method. This research was supported in part by the National Science Foundation under Grant No. PHY05-51164, KITP preprint no. NSF-KITP-10-157. This research was made possible in part by the historic generosity of the Harold Perlman family.
PY - 2011/5/24
Y1 - 2011/5/24
N2 - One of the most popular methods for solving numerical optimal control problems is the Krotov method, adapted for quantum control by Tannor and coworkers. The Krotov method has the following three appealing properties: (1) monotonic increase of the objective with iteration number, (2) no requirement for a line search, leading to a significant savings over gradient (first-order) methods, and (3) macrosteps at each iteration, resulting in significantly faster growth of the objective at early iterations than in gradient methods where small steps are required. The principal drawback of the Krotov method is slow convergence at later iterations, which is particularly problematic when high fidelity is desired. We show here that, near convergence, the Krotov method degenerates to a first-order gradient method. We then present a variation on the Krotov method that has all the advantages of the original Krotov method but with significantly enhanced convergence (second-order or quasi-Newton) as the optimal solution is approached. We illustrate the method by controlling the three-dimensional dynamics of the valence electron in the Na atom.
AB - One of the most popular methods for solving numerical optimal control problems is the Krotov method, adapted for quantum control by Tannor and coworkers. The Krotov method has the following three appealing properties: (1) monotonic increase of the objective with iteration number, (2) no requirement for a line search, leading to a significant savings over gradient (first-order) methods, and (3) macrosteps at each iteration, resulting in significantly faster growth of the objective at early iterations than in gradient methods where small steps are required. The principal drawback of the Krotov method is slow convergence at later iterations, which is particularly problematic when high fidelity is desired. We show here that, near convergence, the Krotov method degenerates to a first-order gradient method. We then present a variation on the Krotov method that has all the advantages of the original Krotov method but with significantly enhanced convergence (second-order or quasi-Newton) as the optimal solution is approached. We illustrate the method by controlling the three-dimensional dynamics of the valence electron in the Na atom.
UR - http://www.scopus.com/inward/record.url?scp=79961073689&partnerID=8YFLogxK
U2 - https://doi.org/10.1103/PhysRevA.83.053426
DO - https://doi.org/10.1103/PhysRevA.83.053426
M3 - مقالة
SN - 1050-2947
VL - 83
JO - Physical Review A - Atomic, Molecular, and Optical Physics
JF - Physical Review A - Atomic, Molecular, and Optical Physics
IS - 5
M1 - 053426
ER -