In this paper, a novel approach for two-loop Control of the DC-DC Cuk converter in discontinuous conduction Mode is presented using a sliding Mode Controller. The proposed Controller can regulate the output of the converter in a wide range of input voltage and load resistance. Controller parameters are selected using PSO algorithms. In order to verify the accuracy and efficiency of the developed sliding Mode Controller, the proposed method is simulated in MATLAB/Simulink. It is shown that the developed Controller has, the faster dynamic response compared with standard integrated circuit (MIC38C42-5) based regulators.

Application of atomic force microscope as a manipulator for pushing-based positioning of nano-particles has been of considerable interest during recent years. However a detailed Modelling of the interaction forces and Control on the AFM tip is important for prosperous manipulation Control, a reliable Control of the AFM tip position during the AFM-based manipulation process is a main issue. The deflection of the AFM tip caused by manipulation force is the one of nonlinearities and uncertainties which causes difficulties in accurately Controlling the tip position, the tip can jump over the target nano-particle then the process will fail. This study aims todesign a sliding Mode Controller (SMC) as robust chattering-free Control in contact-Mode to Control the AFM tip during nano-manipulation process for accomplishment of a precise and effective nano-manipulation task in order to achieve the full automatic nano-manipulation system without direct intervention of an operator. The nano-probe is used to push the spherical micro/nano-particle. Nano-scale interaction forces, elastic deformation in contact areas, and friction forces in tip/nano-particle/substrate system are considered. The first Control purpose is Controlling and positioning the microcantilever tip at a desired trajectory by the Control input force which can be exerted on the microcantilever in the Ydirection by a piezo actuator located in the base of the microcantilever. The second Control target is PZT-driven positioning stage in AFM-based nanomanipulation in the X, Y in the flat surface. The simulation results show that the designed Controllers have been able to make the desired variable state to track specified trajectory during a nano-scale manipulation.

A novel nonlinear Controller is proposed to track active and reactive power for a Brushless Doubly-Fed Induction Generator (BDFIG) wind turbine. Due to nonlinear dynamics and the presence of parametric uncertainties and perturbations in this system, sliding Mode Control is employed. To generate a smooth Control signal, dynamic sliding Mode method is used. Uncertainties bound is not required in the suggested algorithm, since the adaptive gain in the Controller relation is used in this study. Convergence of the sliding variable to zero and adaptive gain to the uncertainty bound are verified using Lyapunov stability theorem. The proposed Controller is evaluated in a comprehensive simulation on the BDFIG Model. Moreover, output performance of the proposed Control algorithm is compared to the conventional and second-order sliding Mode and proportional-integral-derivative (PID) Controllers.