Research on Control Strategy of Single-phase LCL-Type Grid-Connected Inverter based on Composite Repetitive Control -복합 반복제어에 기반한 단상 LCL-계통연계 인버터의 제어 전략에 관한 연구

Research on Control Strategy of Single-phase LCL-Type Grid-Connected Inverter based on Composite Repetitive Control 

A Dissertation Submitted to the Department of Electronic Engineering and the Graduate School of Cheongju University in partial fulfillment of the requirements for the degree of Doctor of Engineering 

AUTHOR:Fen Liang (양분)

ABSTRACT With the rapid development of new energy generation technologies such as photovoltaic and wind power, the distributed power generation system (DPGS) based on renewable energy has attracted more and more attention all over the world. Grid- connected inverters, as an essential component of DPGS, play an important role in converting DC into AC between photovoltaic, wind power equipment, and the power grid. However, a lot of harmonics are generated by the dead time of the grid-connected inverter, the background harmonics from the grid voltages, nonlinear loads, etc., resulting in poor control performance, high total harmonic distortion (THD), additional power loss, and even system instability. Therefore, improving the quality of current and researching high-quality current control technologies for grid-connected inverters are of great significance. Repetitive control (RC) is widely used in grid-connected inverter control systems due to its excellent harmonic suppression performance. To improve the output current quality of the grid-connected inverter and improve the robustness and control accuracy of the system, this dissertation takes a single-phase grid-connected inverter as an application target, adopts composite repetitive control technology to reduce harmonics content in the output current of the grid-connected inverter. The main works of this dissertation are as follows. (1) A single-phase LCL-type grid-connected inverter model is created, and the parameters of the LCL filter are designed. Furthermore, to eliminate the resonant peaks generated by the LCL filter, various damping strategies are compared and analyzed. (2) By analyzing the principles, stability, harmonic suppression ability of the conventional repetitive control (CRC), and advantages of proportional-integral (PI) control, the composite repetitive controller composed of RC and PI in series or in parallel structures is introduced. Furthermore, taking the proportional integral multi- resonant repetitive control (PIMR-RC) composed of RC and PI in parallel as an example, parameters design, steady-state response, and dynamic performance analysis are conducted in detail. (3) The fundamental frequency of the power grid may fluctuate at ±0.5 Hz in DPGSs, and the ratio N is the sampling frequency to the fundamental frequency of the power grid may be a fraction. However, CRC has excellent control performance only N is an integer, or it will result in a significant decrease in signal tracking and harmonic suppression performance. To ensure that the repetitive controller can accurately track reference current even when the grid frequency fluctuates and to reduce computational load and memory consumption, based on a Farrow-structure filter, a fractional-order delay PIMR-RC (FOD-PIMR-RC) scheme is proposed, which greatly improve the quality of the grid current against frequency fluctuations. Then, the stability analysis and the harmonic suppression performance of the proposed scheme are analyzed. Finally, the simulation results demonstrate the effectiveness of the proposed scheme. (4) To reduce the computational load and memory consumption, multirate repetitive control (MRC) is adopted in the PIMR-RC system for grid-connect inverters. Although MRC provides a flexible and efficient design solution, it usually adopts a downsampling rate approach. CRC with integer-order phase lead compensation cannot exactly compensate for the system phase lag, which may result in an unstable system in the case of low sampling frequency. Therefore, a fractional-order phase lead PIMR-MRC (FOPL-PIMR-MRC) scheme, employing an infinite impulse response (IIR) filter, is presented for grid-connected inverters. The proposed scheme includes the design of a fractional-order phase lead compensation filter, along with stability analysis, parameter design, and comprehensive simulation analysis. The steady-state and dynamic simulation results confirm that the proposed control scheme effectively achieves accurate phase compensation, enhances the stability margin of the system, and reduces hardware consumption. Additionally, it ensures excellent performance in harmonic suppression.

ORIGINAL LINK: 

https://www.riss.kr/search/detail/DetailView.do?p_mat_type=be54d9b8bc7cdb09&control_no=eac0d4320214a784ffe0bdc3ef48d419&keyword=Inverter%20Control%20Strategies%20for%20a%20Grid%20Stabilizing

ALTERNATIVE LINK:

https://www.mediafire.com/file/7k5udulzfe1zti9/Research+on+Control+Strategy+of+Single-phase+LCL-Type+Grid-Connected.pdf/file

APEC 2022, Houston, TX, USA Next-Generation Datacenter MV Interfaces — Will Solid-State Transformers Meet Their Waterloo?

 APEC 2022, Houston, TX, USA

Next-Generation Datacenter MV Interfaces — Will Solid-State Transformers Meet Their Waterloo?

  

Inverter Control Strategies for a Grid Stabilizing Power-to-Gas System = 전력가스화 (P2G) 시스템에서 계통 안정화를 위한 인버터 제어기법 -School of Tech University of Korea

  전력가스화 (P2G) 시스템에서 계통 안정화를 위한 인버터 제어기법 Tech University of Korea

  Ph.D. Dissertation Submitted to the Department of Energy and Electrical Engineering and the Graduate School of Tech University of Korea in partial fulfillment of the requirements for the Philosophy Degree in Engineering June 2024 

 Abstract

Inverter Control Strategies for a Grid Stabilizing Power-to-Gas System 전력가스화 (P2G) 시스템에서 계통 안정화를 위한 인버터 제어기법 The integration of Power-to-Gas (P2G) systems into modern power grids represents a pivotal advancement towards achieving a more sustainable and resilient energy infrastructure. However, this integration introduces both challenges and opportunities, particularly concerning grid stability and the effective incorporation of renewable energy sources. This thesis delves into the intricate dynamics of P2G system integration, with a specific focus on the role of inverter control strategies in ensuring grid stability and facilitating the seamless integration of renewable energy sources. Through an extensive review of existing literature and rigorous analysis, various control strategies tailored for P2G applications are explored, emphasizing their efficacy in addressing grid stability concerns. Key aspects examined include voltage and frequency regulation, active and reactive power control, ancillary services provision, and energy storage management. These factors are crucial for maintaining grid stability amidst the variability inherent in renewable energy generation and the intermittent nature of P2G systems. Additionally, the development and implementation of advanced control algorithms are discussed. These algorithms are designed to account for grid dynamics, renewable energy variability, and compliance with grid codes and regulations. A particular focus is placed on enhancing grid-forming capabilities within inverters, enabling autonomous operation even in weak grid conditions, thereby bolstering grid resilience.

ORIGINAL LINK:  

https://www.riss.kr/search/detail/DetailView.do?p_mat_type=be54d9b8bc7cdb09&control_no=e4eef281c8f67286ffe0bdc3ef48d419&keyword=inverter%20grid%20forming%20system

 ALTERNATIVE LINK:https://www.mediafire.com/file/wx16ob1ycexs50b/Inverter+Control+Strategies+for+a+Grid+Stabilizing+Power-to-Gas+System.pdf/file

 

Performance Comparison of Droop Control and VSG Control for Grid Forming Inverter = 그리드 포밍 인버터를 위한 드룹 제어와 가상 동기 발전기 (VSG) 제어의 성능 비교 by Thapyay Hlaing-Kwangwoon University South Korea

 

Performance Comparison of Droop Control and Virtual Synchronous Generator (VSG) Control for Grid Forming Inverters

 Advisor: Professor Minhan Yoon Submitted for the Master's Degree in Electrical Engineering July 1, 2025 Kwangwoon University Department of Electrical Engineering Thapyay Hlaing

 ] 그리드 포밍 인버터를 위한 드룹 제어와 가상 동기 발전기 (VSG) 제어의 성능 비교 Performance Comparison of Droop Control and VSG Control for Grid Forming Inverter 지도교수 윤민한 이 논문을 전기공학 석사학위논문으로 제출함 2025년 7월 1일 광운대학교 전기공학과 Thapyay Hlaing

 ABSTRACT As the growing integration of renewable energy sources, inverter-based resources (IBRs) becoming new challenges for power system stability. This brings new contests to maintain system stability. The inverter that lacks inertia and making the grid more sensitive to disturbances, especially under weak grid conditions. The thesis offers a detailed performance comparison between droop control and VSG control for grid-forming inverters. The wide-spread simulation-based testing was conducted under various scenarios, including steady state operations, load variations, and fault conditions such as low voltage ride through (LVRT). GFM inverters with droop control effectively regulate power sharing. This provides improved system stability by proportionally adjusting frequency and voltage responses. VSG control further improves dynamic behavior by mimicking the inertia and damping characteristics of synchronous generators, resulting in smoother transitions and stronger fault response. Each control strategy was evaluated for its ability to handle power deviations, share load among multiple inverters and maintain system stability under both normal and fault conditions. Therefore, the careful selection and tuning of inverter control methods are critical to ensure balanced grid support, reliable power sharing, and fault ride- through performance. Advanced GFM control strategies such as droop and VSG will play a central role in enabling stable and resilient grid operation.

View full Thesis: ORIGINAL LINK

 https://www.riss.kr/search/detail/DetailView.do?p_mat_type=be54d9b8bc7cdb09&control_no=071c02e876d833bcffe0bdc3ef48d419&keyword=inverter%20grid%20forming%20system

 ALTERNATIVE LINK : https://www.mediafire.com/file/ectvrvhzxyirakk/Performance+Comparison+of+Droop+Control+and+VSG+Control+for+Grid+Forming+Inverter.pdf/file

Fundamental of Power Electronics-24-1 High-Frequency Dynamics Controlled by Current Mode- Dr.Wang Haoyu-School of Information Science and Technology, ShanghaiTech University

 

Modeling and Control of Power Electronic Converters.

ShanghaiTech University Online English Course: Power Electronic Converter Modeling and Control Instructor:Professor Wang Haoyu 

{Haoyu Wang} (Senior Member, IEEE) received the bachelor's degree with distinguished honor in electrical engineering from Zhejiang University, Hangzhou, China, in 2009, and the Ph.D. degree in electrical engineering from the University of Maryland, College Park, MD, USA, in 2014. In September 2014, he joined the School of Information Science and Technology, ShanghaiTech University, where he is currently a Full Professor with tenure. In 2023, he was a visiting academic fellow at the University of Cambridge, UK. His research interests include power electronics, electric vehicles, renewable energy systems, and power management integrated circuits. Dr. Wang is an IET Fellow. He serves as an Associate Editor for IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, IEEE TRANSACTIONS ON TRANSPORTATION ELECTRIFICATION, and CPSS Transactions on Power Electronics and Applications. He was a Guest Editor for IEEE JOURNAL OF EMERGING AND SELECTED TOPICS IN POWER ELECTRONICS, and a Guest Associate Editor for IEEE TRANSACTIONS ON POWER ELECTRONICS.