Optimization-Based Fast-Frequency Estimation and Control of Low-Inertia Microgrids

The lack of inertial response from non-synchronous, inverter-based generation in microgrids makes the power system vulnerable to a large rate of change of frequency (ROCOF) and frequency excursions. Energy storage systems (ESSs) can be utilized to provide fast-frequency support to prevent such large excursions in the system. However, fast-frequency support is a power-intensive application that has a significant impact on the ESS lifetime. In this paper, a framework that allows the ESS operator to provide fast-frequency support as a service is proposed. The framework maintains the desired quality-of-service (limiting the ROCOF and frequency) while taking into account the ESS lifetime and physical limits. The framework utilizes moving horizon estimation (MHE) to estimate the frequency deviation and ROCOF from noisy phase-locked loop (PLL) measurements. These estimates are employed by a model predictive control (MPC) algorithm that computes control actions by solving a finite-horizon, online optimization problem. Additionally, this approach avoids oscillatory behavior induced by delays that are common when using low-pass filters as with traditional derivative-based (virtual inertia) controllers. MATLAB/Simulink simulations on a test system from Cordova, Alaska, show the effectiveness of the MHE-MPC approach to reduce frequency deviations and ROCOF of a low-inertia microgrid.

[1]  Gabriela Hug,et al.  MPC-Based Fast Frequency Control of Voltage Source Converters in Low-Inertia Power Systems , 2020, IEEE Transactions on Power Systems.

[2]  Josep M. Guerrero,et al.  Improvement of Frequency Regulation in VSG-Based AC Microgrid Via Adaptive Virtual Inertia , 2020, IEEE Transactions on Power Electronics.

[3]  Alberto Bemporad,et al.  From linear to nonlinear MPC: bridging the gap via the real-time iteration , 2020, Int. J. Control.

[4]  Marco Liserre,et al.  Microgrid Stability Definitions, Analysis, and Examples , 2020, IEEE Transactions on Power Systems.

[5]  Nilanjan Senroy,et al.  Self-Tuning Neural Predictive Control Scheme for Ultrabattery to Emulate a Virtual Synchronous Machine in Autonomous Power Systems , 2020, IEEE Transactions on Neural Networks and Learning Systems.

[6]  Shafiuzzaman K. Khadem,et al.  Impact of Power Sharing Method on Battery Life Extension in HESS for Grid Ancillary Services , 2019, IEEE Transactions on Energy Conversion.

[7]  Petros Aristidou,et al.  Interval-Based Adaptive Inertia and Damping Control of a Virtual Synchronous Machine , 2019, 2019 IEEE Milan PowerTech.

[8]  Timothy M. Hansen,et al.  Model Predictive Frequency Control of Low Inertia Microgrids , 2019, 2019 IEEE 28th International Symposium on Industrial Electronics (ISIE).

[9]  Yasunori Mitani,et al.  Self-Adaptive Virtual Inertia Control-Based Fuzzy Logic to Improve Frequency Stability of Microgrid With High Renewable Penetration , 2019, IEEE Access.

[10]  Ivan Zelinka,et al.  Synthetic inertia control based on fuzzy adaptive differential evolution , 2019, International Journal of Electrical Power & Energy Systems.

[11]  Naresh Malla,et al.  Comparative Analysis of Current Control Techniques to Support Virtual Inertia Applications , 2018, Applied Sciences.

[12]  Gabriela Hug,et al.  Fast Frequency Control Scheme through Adaptive Virtual Inertia Emulation , 2018, 2018 IEEE Innovative Smart Grid Technologies - Asia (ISGT Asia).

[13]  Wolfgang Gawlik,et al.  On Small Signal Frequency Stability under Virtual Inertia and the Role of PLLs , 2018 .

[14]  Thierry Van Cutsem,et al.  Decentralized model predictive control of voltage source converters for AC frequency containment , 2018, International Journal of Electrical Power & Energy Systems.

[15]  Gabriela Hug,et al.  Foundations and Challenges of Low-Inertia Systems (Invited Paper) , 2018, 2018 Power Systems Computation Conference (PSCC).

[16]  Raymond H. Byrne,et al.  Energy Management and Optimization Methods for Grid Energy Storage Systems , 2018, IEEE Access.

[17]  Timothy M. Hansen,et al.  Virtual Inertia: Current Trends and Future Directions , 2017 .

[18]  Boris Fischer,et al.  Modeling and Design of $df/dt$ -Based Inertia Control for Power Converters , 2017, IEEE Journal of Emerging and Selected Topics in Power Electronics.

[19]  Pedro Rodriguez,et al.  Derivative based inertia emulation of interconnected systems considering phase-locked loop dynamics , 2016, 2016 IEEE Power and Energy Society General Meeting (PESGM).

[20]  Naresh Malla,et al.  Reduction of energy consumption of virtual synchronous machine using supplementary adaptive dynamic programming , 2016, 2016 IEEE International Conference on Electro Information Technology (EIT).

[21]  Ujjwol Tamrakar,et al.  Improving transient stability of photovoltaic-hydro microgrids using virtual synchronous machines , 2015, 2015 IEEE Eindhoven PowerTech.

[22]  Babu Narayanan,et al.  POWER SYSTEM STABILITY AND CONTROL , 2015 .

[23]  Luiz A. C. Lopes,et al.  Self-Tuning Virtual Synchronous Machine: A Control Strategy for Energy Storage Systems to Support Dynamic Frequency Control , 2014, IEEE Transactions on Energy Conversion.

[24]  Ramazan Bayindir,et al.  Microgrid testbeds around the world: State of art , 2014 .

[25]  Manfred Morari,et al.  Stabilization of Large Power Systems Using VSC–HVDC and Model Predictive Control , 2014, IEEE Transactions on Power Delivery.

[26]  Göran Andersson,et al.  Predictive control for real-time frequency regulation and rotational inertia provision in power systems , 2013, 52nd IEEE Conference on Decision and Control.

[27]  Feng Liu,et al.  Incorporating approximate dynamic programming-based parameter tuning into PD-type virtual inertia control of DFIGs , 2013, The 2013 International Joint Conference on Neural Networks (IJCNN).

[28]  Mario Zanon,et al.  Nonlinear Moving Horizon Estimation for combined state and friction coefficient estimation in autonomous driving , 2013, 2013 European Control Conference (ECC).

[29]  Jon Are Suul,et al.  Virtual synchronous machines — Classification of implementations and analysis of equivalence to droop controllers for microgrids , 2013, 2013 IEEE Grenoble Conference.

[30]  Luiz A. C. Lopes,et al.  An optimal virtual inertia controller to support frequency regulation in autonomous diesel power systems with high penetration of renewables , 2011 .

[31]  Moritz Diehl,et al.  ACADO toolkit—An open‐source framework for automatic control and dynamic optimization , 2011 .

[32]  Lingling Fan,et al.  Investigation of Microgrids With Both Inverter Interfaced and Direct AC-Connected Distributed Energy Resources , 2011, IEEE Transactions on Power Delivery.

[33]  Hassan Bevrani,et al.  Robust Power System Frequency Control , 2009 .

[34]  James B. Rawlings,et al.  Particle filtering and moving horizon estimation , 2006, Comput. Chem. Eng..

[35]  Andrew R. Teel,et al.  Model predictive control: for want of a local control Lyapunov function, all is not lost , 2005, IEEE Transactions on Automatic Control.

[36]  M.R. Iravani,et al.  Estimation of frequency and its rate of change for applications in power systems , 2004, IEEE Transactions on Power Delivery.

[37]  Jay H. Lee,et al.  Constrained linear state estimation - a moving horizon approach , 2001, Autom..

[38]  David Q. Mayne,et al.  Constrained model predictive control: Stability and optimality , 2000, Autom..