Qiuhua Huang scite author profile

Qiuhua Huang

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50Publications

555Citation Statements Received

392Citation Statements Given

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Affiliations

Pacific Northwest National Laboratory, Arizona State University

Publications

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Adaptive Power System Emergency Control Using Deep Reinforcement Learning

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et al. 2020

IEEE Trans. Smart Grid

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Power system emergency control is generally regarded as the last safety net for grid security and resiliency. Existing emergency control schemes are usually designed off-line based on either the conceived "worst" case scenario or a few typical operation scenarios. These schemes are facing significant adaptiveness and robustness issues as increasing uncertainties and variations occur in modern electrical grids. To address these challenges, this paper developed novel adaptive emergency control schemes using deep reinforcement learning (DRL) by leveraging the high-dimensional feature extraction and non-linear generalization capabilities of DRL for complex power systems.Furthermore, an open-source platform named Reinforcement Learning for Grid Control (RLGC) has been designed for the first time to assist the development and benchmarking of DRL algorithms for power system control. Details of the platform and DRL-based emergency control schemes for generator dynamic braking and under-voltage load shedding are presented. Robustness of the developed DRL method to different simulation scenarios, model parameter uncertainty and noise in the observations is investigated. Extensive case studies performed in both the two-area, four-machine system and the IEEE 39-bus system have demonstrated excellent performance and robustness of the proposed schemes.

Integrated Transmission and Distribution System Power Flow and Dynamic Simulation Using Mixed Three-Sequence/Three-Phase Modeling

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2017

IEEE Trans. Power Syst.

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Application of Electromagnetic Transient-Transient Stability Hybrid Simulation to FIDVR Study

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2016

IEEE Trans. Power Syst.

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A Learning-Based Power Management Method for Networked Microgrids Under Incomplete Information

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et al. 2020

IEEE Trans. Smart Grid

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This paper presents an approximate Reinforcement Learning (RL) methodology for bi-level power management of networked Microgrids (MG) in electric distribution systems. In practice, the cooperative agent can have limited or no knowledge of the MG asset behavior and detailed models behind the Point of Common Coupling (PCC). This makes the distribution systems unobservable and impedes conventional optimization solutions for the constrained MG power management problem. To tackle this challenge, we have proposed a bi-level RL framework in a price-based environment. At the higher level, a cooperative agent performs function approximation to predict the behavior of entities under incomplete information of MG parametric models; while at the lower level, each MG provides powerflow-constrained optimal response to price signals. The function approximation scheme is then used within an adaptive RL framework to optimize the price signal as the system load and solar generation change over time. Numerical experiments have verified that, compared to previous works in the literature, the proposed privacy-preserving learning model has better adaptability and enhanced computational speed.

Accelerated Derivative-Free Deep Reinforcement Learning for Large-Scale Grid Emergency Voltage Control

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et al. 2022

IEEE Trans. Power Syst.

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HVDC macrogrid modeling for power-flow and transient stability studies in north american continental-level interconnections

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et al. 2017

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Advanced EMT and Phasor-Domain Hybrid Simulation With Simulation Mode Switching Capability for Transmission and Distribution Systems

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2018

IEEE Trans. Power Syst.

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Integrated Transmission and Distribution System Power Flow and Dynamic Simulation Using Mixed Three-Sequence/ Three-Phase Modeling

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2018

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