This paper presents a new approach for automated path planning of cooperative crane manipulators using a genetic algorithm (GA). The inverse kinematic problem, i.e., determining the joint angle configuration for the cooperative crane manipulator system in moving the object from pick location to place location, is defined as an optimization problem and solved using GA. For generating the collision-free path, GA with an interference detection algorithm is employed and search is made in the manipulator joint angle space (configuration space). The effectiveness of the proposed approach for automated path planning is demonstrated by comparing the performance of the present approach with the earlier heuristic search proposed by Sivakumar et al. The GA approach finds a near-optimal path with lower path cost and less computational time than earlier heuristic searches. © ASCE.

N. Ramesh Babu

Department of Mechanical Engineering

Koshy Varghese

Department Of Civil Engineering

Construction equipment

Evolutionary algorithms

Genetic algorithms

Heuristic methods

Inverse kinematics

Manipulators

Motion planning

Optimization

Risk assessment

Robotics

CONSTRUCTION PLANNING

Cooperation

HEAVY LIFT PLANNING

CRANES

IIT Madras is a public technical and research university located in Chennai, Tamil Nadu. Founded in 1959, it is recognised as an Institute of National Importance.

IIT Madras has been ranked as the top engineering institute in India for four years in a row by the National Institutional Ranking Framework of the MHRD

It currently offers undergraduate, postgraduate and research degrees across 16 disciplines in Engineering, Sciences, Humanities and Management. About 596 faculty belonging to science and engineering departments and centres of the Institute are engaged in teaching, research and industrial consultancy.

IIT Madras

Collision free path planning of cooperative crane manipulators using genetic algorithm

Journal of Computing in Civil Engineering

In this paper, a practically viable approach for conflict free, coordinated motion planning of multiple robots is proposed. The presented approach is a two phase decoupled method that can provide the desired coordination among the participating robots in offline mode. In the first phase, the collision free path with respect to stationary obstacles for each robot is obtained by employing an A* algorithm. In the second phase, the coordination among multiple robots is achieved by resolving conflicts based on a path modification approach. The paths of conflicting robots are modified based on their position in a dynamically computed path modification sequence (PMS). To assess the effectiveness of the developed methodology, the coordination among robots is also achieved by different strategies such as fixed priority sequence allotment for motion of each robot, reduction in the velocities of joints of the robot, and introduction of delay in starting of each robot. The performance is assessed in terms of the length of path traversed by each robot, time taken by the robot to realize the task and computational time. The effectiveness of the proposed approach for multi-robot motion planning is demonstrated with two case studies that considered the tasks with three and four robots. The results obtained from realistic simulation of multi-robot environment demonstrate that the proposed approach assures rapid, concurrent and conflict free coordinated path planning for multiple robots. © 2011 Elsevier B.V. All rights reserved.

Robotics and Autonomous Systems

Conflict free coordinated path planning for multiple robots using a dynamic path modification sequence

The use of cooperative cranes can improve the cost effectiveness of heavy lift operations. However, the complexity in developing a reliable lift plan prevents the widespread use of cooperative crane lifts. The availability of a computer-aided planning system can improve planning efficiency and reliability. Path planning is an important subtask of the lift planning process. This paper presents work done to develop a computer aided path planner for two crane lifts. Two heuristic search methods, hill climbing and A*, were implemented for automating the path-planning task. Search space was represented using the concept of configuration space. The effectiveness of the search methods was evaluated by solving three problems with increasing levels of complexity. The formulation of these problems was based on the type of movement of cooperative cranes (in synchronous or asynchronous manner) and the presence of trapping space. It was found that while the hill climbing approach found feasible paths in a few seconds or minutes, these paths were far from optimal in situations containing trapping space. In contrast, the A* search resulted in near optimal paths, but the execution time was of the order of hours. © ASCE.

Automated path planning of cooperative crane lifts using heuristic search

This paper presents the work done toward developing a computerized heavy lift planning system (HELPS) for planning crane lifts. Initially, a survey of the industry was carried out to define the heavy lift planning process and identify the developments necessary to improve the process. This survey identified eight tasks in the lift planning process. Based on these tasks, a logical framework representing the planning process was developed. The scope of the current work was limited to developing a tool for planning three of these tasks. A visualization environment - Walkthru - was selected to implement the heavy lift planning system. Although Walkthm provided many of the features required for the system, critical functions had to be added. The developmental work for this study focused on (1) developing a shell that could control the visualization environment and related files to provide seamless access to the library of cranes and (2) providing features to perform critical lift planning functions. The resulting prototype system was tested on sample lifts, and all the functions worked as designed. © 1997 Microcomputers in Civil Engineering. Published by Blackwell Publishers,.

Journal	Journal of Computing in Civil Engineering
ISSN	08873801
Open Access	No