Abstract
Due to the fact that intelligent algorithms such as Particle Swarm Optimization (PSO) and Differential Evolution (DE) are susceptible to local optima and the efficiency of solving an optimal solution is low when solving the optimal trajectory, this paper uses the Sequential Quadratic Programming (SQP) algorithm for the optimal trajectory planning of a hydraulic robotic excavator. To achieve high efficiency and stationarity during the operation of the hydraulic robotic excavator, the trade-off between the time and jerk is considered. Cubic splines were used to interpolate in joint space, and the optimal time-jerk trajectory was obtained using the SQP with joint angular velocity, angular acceleration, and jerk as constraints. The optimal angle curves of each joint were obtained, and the optimal time-jerk trajectory planning of the excavator was realized. Experimental results show that the SQP method under the same weight is more efficient in solving the optimal solution and the optimal excavating trajectory is smoother, and each joint can reach the target point with smaller angular velocity, and acceleration change, which avoids the impact of each joint during operation and conserves working time. Finally, the excavator autonomous operation becomes more stable and efficient.
Highlights
The following problems persist regarding the process of work: (1) the high intensity of labor required from the operators, (2) a dangerous working environment, and (3) the large amounts of money, material resources, and time required for an operator to develop the requisite skill
Generally overlap, but from the trajectory of the first and fourth segments shown in the Figure 10, it can be clearly seen that the best trajectory of the time-jerk
The performance indexes considering both jerk and time are established, and the optimal cubic spline interpolation trajectory concerning the problems of time and jerk are obtained by using the three algorithms of the Sequential Quadratic Programming (SQP), Particle Swarm Optimization (PSO), and Differential Evolution (DE)
Summary
Hydraulic excavators are widely used in extremely harsh environments for mining, transportation, and civil engineering.[1,2] the following problems persist regarding the process of work: (1) the high intensity of labor required from the operators, (2) a dangerous working environment, and (3) the large amounts of money, material resources, and time required for an operator to develop the requisite skill. To ensure the efficiency and stability of the excavator in the working process, this paper takes the angular velocity, angular acceleration, and jerks as the constraints, and uses the SQP, PSO,[28] and DE29 algorithms to optimize the timejerk optimal cubic spline interpolation trajectory.
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