A fast multi-objective optimization design method for emergency libration point orbits transfer between the Sun–Earth and the Earth–Moon systems

Tsourdos

Xia

et al. 2020

IEEE Trans. Cybern.

Highly constrained trajectory optimization problems are usually difficult to solve. Due to some real-world requirements, a typical trajectory optimization model may need to be formulated containing several objectives. Because of the discontinuity or nonlinearity in the vehicle dynamics and mission objectives, it is challenging to generate a compromised trajectory that can satisfy constraints and optimize objectives. To address the multi-objective trajectory planning problem, this study applies a specific multiple-shooting discretization technique with the newest NSGA-III optimization algorithm and constructs a new evolutionary optimal control solver. In addition, three constraint handling algorithms are incorporated in this evolutionary optimal control framework. The performance of using different constraint handling strategies is detailed and analyzed. The proposed approach is compared with other well-developed multiobjective techniques. Experimental studies demonstrate that the present method can outperform other evolutionary-based solvers investigated in this paper with respect to convergence ability and distribution of the Pareto-optimal solutions. Therefore, the present evolutionary optimal control solver is more attractive and can offer an alternative for optimizing multi-objective continuous-time trajectory optimization problems.

Section: Flight Trajectory Problem Without No-fly Zone Constraintmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Solving Multiobjective Constrained Trajectory Optimization Problem by an Extended Evolutionary Algorithm

Tsourdos

Xia

et al. 2020

IEEE Trans. Cybern.

“…For this type of problem, the different objectives have a trade-off relationship, so there is no single optimal solution but a set of optimal solutions called the Pareto-optimal solution or noninferior solution. Common optimization algorithms include the MOGA, NPGA, PAES, and NSGA-II, and on this basis, for the trajectory optimization problem, a variety of optimization models are derived to effectively improve the algorithm performance [26][27][28]. In this paper, from the perspective of the solution convergence and diversity, the MOPSO algorithm proposed by Coello et al [29], which has shown outstanding performance, is used.…”

Section: B Multi-objective Optimization Model Solution Based On Mopsomentioning

confidence: 99%

Multi-Objective Trajectory Planning Method for a Redundantly Actuated Parallel Manipulator Under Hybrid Force and Position Control

Feng

Han

et al. 2020

IEEE Access

A multi-objective trajectory planning method for redundantly actuated parallel manipulator under hybrid force and position control is proposed considering the coordination of its driving forces. Combining inverse kinematics analysis, the driving force coordination of the manipulator is analyzed using the virtual work principle. On this basis, the B-spline curve is used to plan the motion trajectory of the endeffector of the manipulator in the Cartesian space. Subsequently, the driving force coordination, total motion time, and maximum absolute value of the jerk impulse of the actuator are defined as objective functions, and a multi-objective optimization problem is solved using the multi-objective particle swarm algorithm (MOPSO). Finally, the potential optimal solution is selected by constructing a comprehensive optimal evaluation function. The trajectory simulation results verify that the trajectory planning method is effective and universal. INDEX TERMS Redundantly actuated parallel manipulator, trajectory planning, driving force coordination, multi-objective optimization.

“…Weighted-sum method (WS) [85] Physical programming method (PP) [86] Fuzzy physical programming (FPP) [33] Interactive physical programming (IPP) [87] Interactive fuzzy physical programming (IFPP) [88] Goal programming (GP) [89] Fuzzy goal programming (FGP) [75] Fuzzy satisfactory goal programming (FSGP) [32] Adaptive surrogate model (ASM) [90] hard to find a solution that can optimize all the objectives, it is then interesting to find all the pareto-optimal solutions and create the pareto-optimal set.…”

Section: Multi-objective Transcription-based Techniquesmentioning

confidence: 99%

A review of optimization techniques in spacecraft flight trajectory design

Tsourdos

Progress in Aerospace Sciences

et al. 2019

111

For most atmospheric or exo-atmospheric spacecraft flight scenarios, a welldesigned trajectory is usually a key for stable flight and for improved guidance and control of the vehicle. Although extensive research work has been carried out on the design of spacecraft trajectories for different mission profiles and many effective tools were successfully developed for optimizing the flight path, it is only in the recent five years that there has been a growing interest in planning the flight trajectories with the consideration of multiple mission objectives and various model errors/uncertainties. It is worth noting that in many practical spacecraft guidance, navigation and control systems, multiple performance indices and different types of uncertainties must frequently be considered during the path planning phase. As a result, these requirements bring the development of multi-objective spacecraft trajectory optimization methods as well as stochastic spacecraft trajectory optimization algorithms. This paper aims to broadly review the state-of-the-art development in numerical multi-objective trajectory optimization algorithms and stochastic trajectory planning techniques for spacecraft flight operations. A brief description of the mathematical formulation of the problem is firstly introduced. Following that, various optimization methods that can be effective for solving spacecraft trajectory planning problems are reviewed, including the gradient-based methods, the convexification-based methods, and the evolutionary/metaheuristic methods. The multi-objective