Your search keyword '"Sanjoy Kumar Paul"' showing total 4 results

1. High-Performance Robust Controller Design of Plug-In Hybrid Electric Vehicle for Frequency Regulation of Smart Grid Using Linear Matrix Inequality Approach

Author

Sajal Kumar Das, Mizanur Rahman, Sanjoy Kumar Paul, Maniza Armin, Priyo Nath Roy, and Norottom Paul

Subjects

Smart grid, frequency control, linear matrix inequality, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper proposes a high-performance and robust linear quadratic regulator-proportional integral derivative (LQR-PID) controller for frequency regulation in a two-area interconnected smart grid with a population of plug-in hybrid electric vehicles. Controller robustness is achieved using a linear matrix inequality approach. The proposed control framework is tested in a simulated two-area interconnected smart grid integrated with plug-in hybrid electric vehicles under load disturbances and wind power fluctuations. The performance of the proposed controller is simulated using Matlab and compared with that of a conventional linear quadratic regulator controller. Simulation results show that the proposed controller provides reliable smart grid frequency control.

Published

2019

2. A Novel Blended State Estimated Adaptive Controller for Voltage and Current Control of Microgrid Against Unknown Noise

Author

Md. Shahin Munsi, Abu Bakar Siddique, Sajal K. Das, Sanjoy Kumar Paul, Md. Rabiul Islam, and Mohammad Ali Moni

Subjects

Microgrid, model reference adaptive control, state estimation, unscented kalman filter, voltage and current control, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In this study, a novel blended state estimated adaptive controller is designed for voltage and current control of microgrid against unknown noise. The core feature of the microgrid (MG) is its ability to integrate more than one distributed energy resource into the main grid. The state of a microgrid may deteriorate due to many reasons, for example malicious cyber-attacks, disturbances, packet losses, etc. Therefore, it is necessary to achieve the true state of the system to enhance the control requirement and automation of the microgrid. To achieve the true state of a microgrid, this study proposes the use of an algorithm based on the unscented kalman filter (UKF). The proposed state estimator technique is developed using an unscented-transformation and sigma-points measurement technique capable of minimizing the mean and covariance of a nonlinear cost function to estimate the true state of a single-phase, three-phase single-source and three-phase multi-source microgrid system. The advantage of the proposed estimator over using extended kalman filter (EKF) is investigated in simulations. The results demonstrate that the use of the UKF estimator produces a superior estimation of the system compared with the use of the EKF. An adaptive PID controller is also developed and used in system conjunction with the estimator to regulate its voltage and current against the number of loads. Deviation in load parameters hamper the function of the MG system. The performance of the developed controller is also evaluated against number of loads. Results indicate the controller provides a more stable and high-tracking performance with the inclusion of the UKF in the system.

Published

2019

3. A Novel Blended State Estimated Adaptive Controller for Voltage and Current Control of Microgrid Against Unknown Noise

Author

Mohammad Ali Moni, Abu Bakar Siddique, Sajal K. Das, Sanjoy Kumar Paul, Md. Shahin Munsi, and Md. Rabiul Islam

Subjects

Microgrid, General Computer Science, Computer science, PID controller, unscented kalman filter, 01 natural sciences, Extended Kalman filter, Control theory, General Materials Science, state estimation, 0101 mathematics, business.industry, voltage and current control, 010102 general mathematics, General Engineering, Estimator, Kalman filter, Nonlinear system, Noise, model reference adaptive control, Distributed generation, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, lcsh:TK1-9971, Voltage

Abstract

In this study, a novel blended state estimated adaptive controller is designed for voltage and current control of microgrid against unknown noise. The core feature of the microgrid (MG) is its ability to integrate more than one distributed energy resource into the main grid. The state of a microgrid may deteriorate due to many reasons, for example malicious cyber-attacks, disturbances, packet losses, etc. Therefore, it is necessary to achieve the true state of the system to enhance the control requirement and automation of the microgrid. To achieve the true state of a microgrid, this study proposes the use of an algorithm based on the unscented kalman filter (UKF). The proposed state estimator technique is developed using an unscented-transformation and sigma-points measurement technique capable of minimizing the mean and covariance of a nonlinear cost function to estimate the true state of a single-phase, three-phase single-source and three-phase multi-source microgrid system. The advantage of the proposed estimator over using extended kalman filter (EKF) is investigated in simulations. The results demonstrate that the use of the UKF estimator produces a superior estimation of the system compared with the use of the EKF. An adaptive PID controller is also developed and used in system conjunction with the estimator to regulate its voltage and current against the number of loads. Deviation in load parameters hamper the function of the MG system. The performance of the developed controller is also evaluated against number of loads. Results indicate the controller provides a more stable and high-tracking performance with the inclusion of the UKF in the system.

Published

2019

4. High-Performance Robust Controller Design of Plug-In Hybrid Electric Vehicle for Frequency Regulation of Smart Grid Using Linear Matrix Inequality Approach

Author

Sanjoy Kumar Paul, N. Paul, Priyo Nath Roy, Mizanur Rahman, Sajal K. Das, and Maniza Armin

Subjects

education.field_of_study, Wind power, General Computer Science, business.industry, Computer science, 020209 energy, 020208 electrical & electronic engineering, Population, Automatic frequency control, General Engineering, Linear matrix inequality, 02 engineering and technology, Linear-quadratic regulator, Smart grid, frequency control, Robustness (computer science), Control theory, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, education, lcsh:TK1-9971, linear matrix inequality

Abstract

This paper proposes a high-performance and robust linear quadratic regulator-proportional integral derivative (LQR-PID) controller for frequency regulation in a two-area interconnected smart grid with a population of plug-in hybrid electric vehicles. Controller robustness is achieved using a linear matrix inequality approach. The proposed control framework is tested in a simulated two-area interconnected smart grid integrated with plug-in hybrid electric vehicles under load disturbances and wind power fluctuations. The performance of the proposed controller is simulated using Matlab and compared with that of a conventional linear quadratic regulator controller. Simulation results show that the proposed controller provides reliable smart grid frequency control.

Published

2019