Synthesis of Linear Coherent Quantum Control Systems Using A Differential Evolution Algorithm

Harno, Hendra G.; Petersen, Ian R.

doi:10.1109/tac.2014.2329382

Cited by 12 publications

(10 citation statements)

References 17 publications

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“…Currently, DE has been successfully applied to solve optimization problems in a considerable number of fields, such as electrical and power systems [24], [25], manufacturing science and operational research [26], [27], automotive design [28], and controller design [13], [14], [15].…”

Section: B Differential Evolution (De)mentioning

confidence: 99%

“…In terms of both the modified DE/rand-to-best/1/bin and DE/current-to-best/1/bin, the information of the "best" individual in the population is utilized to guide the search, thus accelerating the convergence. As shown in Equation (14), the modified DE/rand-to-best/1/bin is derived by replacing the second x t r1 in Equation (5) with a randomly selected individual x t r2 from the population:…”

Section: B Search Algorithmmentioning

confidence: 99%

“…Note that no other single algorithm can accomplish this [12]. More importantly, its search ability has been demonstrated in many real-world applications [13], [14], [15].…”

mentioning

confidence: 99%

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Composite Differential Evolution for Constrained Evolutionary Optimization

Wang

et al. 2019

IEEE Trans. Syst. Man Cybern, Syst.

138

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Abstract-When solving constrained optimization problems by evolutionary algorithms, the search algorithm plays a crucial role. In general, we expect that the search algorithm has the capability to balance not only diversity and convergence but also constraints and objective function during the evolution. For this purpose, this paper proposes a composite differential evolution for constrained optimization, which includes three different trial vector generation strategies with distinct advantages. In order to strike a balance between diversity and convergence, one of these three trial vector generation strategies is able to increase diversity, and the other two exhibit the property of convergence. In addition, to accomplish the tradeoff between constraints and objective function, one of the two trial vector generation strategies for convergence is guided by the individual with the least degree of constraint violation in the population, and the other is guided by the individual with the best objective function value in the population. After producing offspring by the proposed composite differential evolution, the feasibility rule and the ε constrained method are combined elaborately for selection in this paper. Moreover, a restart scheme is proposed to help the population jump out of a local optimum in the infeasible region for some extremely complicated constrained optimization problems. By assembling the above techniques together, a constrained composite differential evolution is proposed. The experiments on two sets of benchmark test functions with various features, i.e., 24 test functions from IEEE CEC2006 and 18 test functions with 10 dimensions and 30 dimensions from IEEE CEC2010, have demonstrated that the proposed method shows better or at least competitive performance against other state-of-the-art methods.

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Section: B Differential Evolution (De)mentioning

confidence: 99%

Section: B Search Algorithmmentioning

confidence: 99%

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Composite Differential Evolution for Constrained Evolutionary Optimization

Wang

et al. 2019

IEEE Trans. Syst. Man Cybern, Syst.

138

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“…A numerical procedure for finding suboptimal controllers for this problem was proposed in [21], and algebraic equations for the optimal CQLQG controller were obtained in [33]. We also mention that coherent quantum LQG control settings were considered in [15] for a class of quantum systems (with annihilation operators only), in the context of evolutionary optimization for entanglement control [7], and also for different scenarios of plant-controller coupling in [35]. Despite the previous results, the CQLQG control problem does not lend itself to an "elegant" solution (for example, in the form of decoupled Riccati equations as in the classical case [12]) and remains a subject of research.…”

Section: Introductionmentioning

confidence: 99%

A numerical approach to optimal coherent quantum LQG controller design using gradient descent

2017

Self Cite

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This paper is concerned with coherent quantum linear quadratic Gaussian (CQLQG) control. The problem is to find a stabilizing measurement-free quantum controller for a quantum plant so as to minimize a mean square cost for the fully quantum closed-loop system. The plant and controller are open quantum systems interconnected through bosonic quantum fields. In comparison with the observation-actuation structure of classical controllers, coherent quantum feedback is less invasive to the quantum dynamics. The plant and controller variables satisfy the canonical commutation relations (CCRs) of a quantum harmonic oscillator and are governed by linear quantum stochastic differential equations (QSDEs). In order to correspond to such oscillators, these QSDEs must satisfy physical realizability (PR) conditions in the form of quadratic constraints on the state-space matrices, reflecting the CCR preservation in time. The symmetry of the problem is taken into account by introducing equivalence classes of coherent quantum controllers generated by symplectic similarity transformations. We discuss a modified gradient flow, which is concerned with norm-balanced realizations of controllers. A line-search gradient descent algorithm with adaptive stepsize selection is proposed for the numerical solution of the CQLQG control problem. The algorithm finds a local minimum of the LQG cost over the parameters of the Hamiltonian and coupling operators of a stabilizing coherent quantum controller, thus taking the PR constraints into account. A convergence analysis of the algorithm is presented. Numerical examples of designing locally optimal CQLQG controllers are provided in order to demonstrate the algorithm performance.

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“…In the past decades, there have been intensive applications in quantum control theory, such as quantum computation [1], nuclear magnetic resonance (NMR) [2], quantum chemistry [3], and quantum optics [4,5]. Increasing research activities have appeared in the field of quantum control, for example, controllability of quantum systems [6,7], coherent control [8,9], optimal control [10,11], Lyapunov control [12][13][14][15][16][17][18][19][20][21][22], sliding mode control [23,24], robust control [25], switching control [26], learning control [27], and closed-loop feedback control [28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Implicit Lyapunov‐based control strategy for closed quantum systems with dipole and polarizability coupling

Zhao

Lin

Zhou

2017

Intl J Robust & Nonlinear

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Summary In this paper, the state transfer of finite dimensional closed quantum systems with dipole and polarizability coupling in non‐ideal cases is investigated. Two kinds of non‐ideal systems are considered, where the internal Hamiltonian of the system is not strongly regular and not all the eigenvectors of the internal Hamiltonian are directly coupled with the target state. Such systems often exist in practical quantum systems such as the one‐dimensional oscillator and coupled two‐spin system. An implicit Lyapunov‐based control strategy is proposed here with convergence analysis for quantum systems modeled by finite dimensional bilinear Schrödinger equations. Specifically, two kinds of Lyapunov functions are defined via implicit functions, and their existences are guaranteed with the help of a fixed point theorem. Then, the local convergence analysis is investigated with the explicit characterization of the largest invariant set by LaSalle invariance principle. Finally, the performance of the feedback design is illustrated by numerical simulations. Copyright © 2017 John Wiley & Sons, Ltd.

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Synthesis of Linear Coherent Quantum Control Systems Using A Differential Evolution Algorithm

Cited by 12 publications

References 17 publications

Composite Differential Evolution for Constrained Evolutionary Optimization

Composite Differential Evolution for Constrained Evolutionary Optimization

A numerical approach to optimal coherent quantum LQG controller design using gradient descent

Implicit Lyapunov‐based control strategy for closed quantum systems with dipole and polarizability coupling

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