In this study,a simple position synchronization control algorithm based on an integral sliding mode is developed for dual-arm robotic manipulator systems.A first-order sliding surface is designed using cross-coupling error in order to ensure position synchron-ization of dual-arm manipulators.The design objective of the proposed controller is to ensure stability as well as to synchronize the movement of both arms while maintaining the trajectory as desired.The integral sliding mode eliminates the reaching phase and guaran-tees robustness throughout the whole operating period.Additionally,a low pass filter is used to smoothen the discontinuous element and minimize unwanted chattering.Lyapunov stability theory is utilized to prove the asymptotic stability of the controlled system.Simula-tion studies are performed to validate the proposed controller's effectiveness.Also,to investigate the possibility of realizing the proposed dynamic control method in practical applications,experiments are conducted on a 14DoF coordinated links(COOL)dual-arm robotic manipulator system.Experimental evidence indicates adequate efficiency in trajectory tracking and guarantees robustness in the pres-ence of parametric uncertainty and external disturbance.