Modeling and Simulation for a Five DOF Robotic Arm Manipulator

Han He

doi:10.54097/hset.v43i.7433

Authors

Han He

DOI:

https://doi.org/10.54097/hset.v43i.7433

Keywords:

Service robot, Forward and inverse kinematics, Robotic arm simulation.

Abstract

Nowadays, service robots are used in a large number of applications in the service industry. With the booming service industry in third world countries, service robots are expected to be used in a wider range of applications, so it is of great importance to conduct research on service robots. This paper develops the model of a kinematic models for a 5 DOF robotic arm that used in service industry in SolidWorks. The robotic arm’s mathematical model is predicated on Denavit-Hartemberg (DH) method, which determine the robot joints angle vector. The procedure aims at describing the forward and inverse kinematic analysis, and finally determine the end effector’s position and orientation through the corresponding joints angle related to the coordinate system (CS), in order to control the robotic arm to reach the designated location in space. A simulation model of the robotic arm was built using the Matlab Robotics Toolbox to verify the correctness of forward and inverse kinematics, which also can simplify the calculation and analysis.

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References

Yang J, Wang C, Jiang B, et al. Visual perception enabled industry intelligence: state of the art, challenges and prospects [J]. IEEE Transactions on Industrial Informatics, 2020, 17 (3): 2204 - 2219.

Dahlin E. Are robots stealing our jobs? [J]. Socius, 2019, 5: 2378023119846249.

Wirtz J, Patterson P G, Kunz W H, et al. Brave new world: service robots in the frontline [J]. Journal of Service Management, 2018.

Campeau-Lecours A, Lamontagne H, Latour S, et al. Kinova modular robot arms for service robotics applications [M]//Rapid Automation: Concepts, Methodologies, Tools, and Applications. IGI global, 2019: 693 - 719.

Zuo J, Zhu X, Peng Y, et al. A new method of posture recognition based on WiFi signal [J]. IEEE Communications Letters, 2021, 25 (8): 2564 - 2568.

Hock O, Drgoňa P, Paškala M. Simulation model of adjustable arm using Denavit-Hartenberg parameters[C]//2014 ELEKTRO. IEEE, 2014: 176 - 179.

Elfasakhany A, Yanez E, Baylon K, et al. Design and development of a competitive low-cost robot arm with four degrees of freedom[J]. Modern mechanical engineering, 2011, 1(02): 47.

Jadeja Y, Pandya B. Design and Development Of 5-DOF Robotic Arm Manipulators[J]. International Journal of Scientific & Technology Research, 2019, 8 (11): 2158 - 2167.

Deshpande V, George P M. Kinematic modelling and analysis of 5 DOF robotic arm[J]. International Journal of Robotics Research and Development (IJRRD), 2014, 4 (2): 17 - 24.

Shah J, Rattan S S, Nakra B C. End-effector position analysis using forward kinematics for 5 DOF pravak robot arm [J]. International Journal of Robotics and Automation, 2013, 2 (3): 112 - 116.

Rocha C R, Tonetto C P, Dias A. A comparison between the Denavit–Hartenberg and the screw-based methods used in kinematic modeling of robot manipulators [J]. Robotics and Computer-Integrated Manufacturing, 2011, 27 (4): 723 - 728.

Corke P I. A robotics toolbox for MATLAB [J]. IEEE Robotics & Automation Magazine, 1996, 3 (1): 24- 32.