Optimal control of quantum systems with SU(1, 1) dynamical symmetry

被引：4

作者：

Dong W. ^{[1
,2
]}

Wu R. ^{[1
,2
]}

Wu J. ^{[3
]}

Li C. ^{[1
,2
]}

Tarn T.-J. ^{[2
,4
]}

机构：

[1] Department of Automation, Tsinghua University, Beijing

[2] Center for Quantum Information Science and Technology, Tsinghua National Laboratory for Information Science and Technology (TNlist), Beijing

[3] Beijing Aerospace Automatic Control Institute, Beijing

[4] Electrical and Systems Engineering Department, Washington University in St. Louis, Missouri, St. Louis

来源：

Control Theory and Technology | 2015年 / 13卷 / 3期

关键词：

dynamical symmetry; optimal control; Quantum control;

D O I：

10.1007/s11768-015-4128-0

中图分类号：

学科分类号：

摘要：

SU(1, 1) dynamical symmetry is of fundamental importance in analyzing unbounded quantum systems in theoretical and applied physics. In this paper, we study the control of generalized coherent states associated with quantum systems with SU(1, 1) dynamical symmetry. Based on a pseudo Riemannian metric on the SU(1, 1) group, we obtain necessary conditions for minimizing the field fluence of controls that steer the system to the desired final state. Further analyses show that the candidate optimal control solutions can be classified into normal and abnormal extremals. The abnormal extremals can only be constant functions when the control Hamiltonian is non-parabolic, while the normal extremals can be expressed by Weierstrass elliptic functions according to the parabolicity of the control Hamiltonian. As a special case, the optimal control solution that maximally squeezes a generalized coherent state is a sinusoidal field, which is consistent with what is used in the laboratory. © 2015, South China University of Technology, Academy of Mathematics and Systems Science, Chinese Academy of Sciences and Springer-Verlag Berlin Heidelberg.

引用

页码：211 / 220

页数：9

共 40 条

[1]

Lan C., Tarn T.-J., Chi Q.-S., Analytic controllability of timedependent quantum control systems, (2005)

[2]

Berrondo M., Palma A., Group theory of the morse potential, Group Theoretical Methods in Physics, pp. 3-7, (1980)

[3]

El-Orany F., Hassan S., Abdalla M., Squeezing evolution with non-dissipative SU(1, 1) systems, Journal of Optics B: Quantum and Semiclassical Optics, 5, 5, pp. 396-404, (2003)

[4]

Dong S.-H., Lara-Rosano F., Sun G.-H., The controllability of the pure states for the Morse potential with a dynamical group SU(1, 1), Physics Letters A, 325, 3, pp. 218-225, (2004)

[5]

Martinez-y-Romero R.P., Nunez-Yepez H.N., Salas-Brito A.L., An su(1, 1) algebraic method for the hydrogen atom, Journal of Physics A: Mathematical and General, 38, 40, pp. 8579-8588, (2005)

[6]

Thilagam A., Lohe M.A., Coherent state polarons in quantum wells, Physica E, 25, 4, pp. 625-635, (2005)

[7]

Wodkiewicz K., Eberly J.H., Coherent states, squeezed fluctuations, and the SU(2) and SU(1, 1) groups in quantumoptics applications, Journal of the Optical Society of America B: Optical Physics, 2, 3, pp. 458-466, (1985)

[8]

Alhassid Y., Gursey F., Iachello F., Group theory approach to scattering, Annals of Physics, 148, 2, pp. 346-380, (1983)

[9]

Dothan Y., Finite-dimensional spectrum-generating algebras, Physical Review D, 2, 12, pp. 2944-2954, (1970)

[10]

Dukelsky J., Dussel G.G., Esebbag C., Exactly solvable models for atom-molecule hamiltonians, (2004)

← 1 2 3 4 →