Design of Filter based Wide Area Damping Controllers in Power System
-
Mahendra Bhadu
and
Nilanjan Senroy
Abstract
In this paper, the concept of analog filter circuit is used for designing of wide area damping controller (WADC) in power system. The designed continuous mode filter based WADC is robust enough to deal with the problem of imperfect communication medium, which include process noise, measurement noise and signal latency in wide area remote signal. Residue method is used for the selection of wide area control signal and controller location. Modelling of imperfect communication network is done using Pade approximation and by inserting Gaussian random noise. The effectiveness of filter based WADC as a power system stability agent is assessed in the frequency domain using two typical test power systems and via appropriate time domain simulations based upon the non-linear model on MATLAB/Simulink software platform.
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Articles in the same Issue
- Microgrid Architecture Evaluation for Small and Medium Size Industries
- Application of V2G and G2V Coordination of Aggregated Electric Vehicle Resource in Load Levelling
- Design of Filter based Wide Area Damping Controllers in Power System
- A Study of Efficient MPPT Techniques for Photovoltaic System Using Boost Converter
- Estimation of Battery Soc for Hybrid Electric Vehicle using Coulomb Counting Method
- Combined Frequency Equivalent Model for Power Transmission Network Dynamic Behavior Analysis
- Generator Coherency Using Zolotarev Polynomial Based Filter Bank and Principal Component Analysis
- Techniques for the Identification of Critical Nodes Leading to Voltage Collapse in a Power System
- Computational Studies of Voltage Regulation Provided by Wind Farms Through Reactive Power Control
- Energy Scheduling of Smart Appliances at Home under the Effect of Dynamic Pricing Schemes and Small Renewable Energy Source
- High Rate Pulse Discharge of Lithium Battery in Electromagnetic Launch System
- A Balanced Operation of Static VAR Compensator for Voltage Stability Improvement and Harmonic Minimization
