The dynamic model and characterization of a two-link fl exible manipulator as an alternative for manipulator robot to achieve the effi ciency on consuming electrical energy comparing with rigid manipulator. A planar two-link fl exible manipulator was combined with structural damping, hub inertia and payload that moving horizontally. A dynamic model system was developed using the combination of Euler-Lagrange and assumed mode methods. Armed with the developed model, then some simulations were done to examine the dynamic model and the response of the system on the hub and the end point of both link that were presented and analyzed in function of time and frequency. The results show that the bang-bang input of 0.15 volt can move the link 1 on 55 0 and link-2 on 122 respectively. It means that the dynamic model uses more effi cient energy compared with rigid manipulator robot which required bigger input for moving.

Alam, M.S ., & Tokhi, M. 2007. Dynamic Modelling of A Single-Link Flexible 98 Manipulator System: A Particle Swarm Optimisation Approach. Journal of Low Frequency Noise, Vibration and Active Control, 26, 57-72.

Aoustin Y., Chevallereau, C., Glumineau, A., & Moog C.H. 1994. Experimental Results for The End-Effector Control of A Single Flexible Robotic Arm. IEEE Transactions on Control SystemsTechnology, 2, 371-381.

De Luca, A., & Siciliano, B. 1991. ClosedForm Dynamic Model of Planar Multi-Link Lightweight Robots. IEEE Transactions on Systems, Man, and Cybernetics, 21, 826-839.

Dwivedy, S.K., & Eberhard, P. 2006. Dynamic Analysis of Flexible Manipulators, A Literature Review. Mechanism and Machine Theory, 41, 749777.

Khairudin, M., Mohamed, Z., Husain, A.R., & Mamat, R. 2014. Dynamic Characterisation of a Two-Link Flexible Manipulator: Theory and Experiments. International Journal of Advances in Robotics Research, 1(1), 061-079.

Martins, J.M., Mohamed, Z., Tokhi, M.O., Sa da Costa, J., & Botto, M.A. 2003. Approaches for Dynamic Modelling of Flexible Manipulator Systems. IEE Proc-Control Theory and Application, 150, 401-411.

Morris A.S., & Madani, A. 1996. Inclusion of Shear Deformation Term to Improve Accuracy in Flexible-Link Robot Modelling. Mechatronics, 6, 631-647.

Pratiher, B., & Dwivedy, S.K. 2007. Non-Linear Dynamics of A Flexible Single Link Cartesian Manipulator. International Journal of Non-Linear Mechanics, 42, 1062- 073.

Subudhi, B., & Morris, A.S. 2002. Dynamic Modelling, Simulation and Control of A Manipulator with Flexible Links and Joints. Robotics and Autonomous System, 41, 257-270.

Tian, Q., Zhang, Y.Q., Chen, L.P., & Yang, J. 2009. Two-Link Flexible Manipulator Modeling and Tip Trajectory Tracking Based on The Absolute Nodal Coordinat Method. International Journal of Robotics and Automation, 24, 103114.

Tokhi, M.O., Mohamed, Z., & Shaheed, M.H. 2001. Dynamic Characterisation of A Flexible Manipulator System. Robotica, 19, 571-580. Usoro, P.B., Nadira, R., & Mahil, S.S. 1986. A Finite Element/Lagrangian Approach to Modelling Light Weight Flexible Manipulators. ASME Journal of Dynamic Systems, Measurement, and Control, 108, 198-205.

Yang, Z., & Sadler, J.P. 1990. LargeDisplacement Finite Element Analysis of Flexible Linkage. ASME Journal of Mechanical Design, 112, 175-182.