Mingjian Cui scite author profile

With the growing wind penetration into the power system worldwide, improving wind power forecasting accuracy is becoming increasingly important to ensure continued economic and reliable power system operations. In this paper, a data-driven multi-model wind forecasting methodology is developed with a two-layer ensemble machine learning technique. The first layer is composed of multiple machine learning models that generate individual forecasts. A deep feature selection framework is developed to determine the most suitable inputs to the first layer machine learning models. Then, a blending algorithm is applied in the second layer to create an ensemble of the forecasts produced by first layer models and generate both deterministic and probabilistic forecasts. This two-layer model seeks to utilize the statistically different characteristics of each machine learning algorithm. A number of machine learning algorithms are selected and compared in both layers. This developed multi-model wind forecasting methodology is compared to several benchmarks. The effectiveness of the proposed methodology is evaluated to provide 1-hour-ahead wind speed forecasting at seven locations of the Surface Radiation network. Numerical results show that comparing to the single-algorithm models, the developed multi-model framework with deep feature selection procedure has improved the forecasting accuracy by up to 30%.

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Wind Power Ramp Event Forecasting Using a Stochastic Scenario Generation Method

Cui

Sun

et al. 2015

IEEE Trans. Sustain. Energy

144

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Model-Free Emergency Frequency Control Based on Reinforcement Learning

Chen

Cui

et al. 2021

IEEE Trans. Ind. Inf.

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Machine Learning-Based Anomaly Detection for Load Forecasting Under Cyberattacks

Cui

Wang

Yue

2019

IEEE Trans. Smart Grid

121

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Ramp forecasting performance from improved short-term wind power forecasting over multiple spatial and temporal scales

Zhang

Cui

Hodge

et al. 2017

Energy

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The large variability and uncertainty in wind power generation present a concern to power system operators, especially given the increasing amounts of wind power being integrated into the electric power system. Large ramps, one of the biggest concerns, can significantly influence system economics and reliability. The Wind Forecast Improvement Project (WFIP) was to improve the accuracy of forecasts and to evaluate the economic benefits of these improvements to grid operators. This paper evaluates the ramp forecasting accuracy gained by improving the performance of short-term wind power forecasting. This study focuses on the WFIP southern study region, which encompasses most of the Electric Reliability Council of Texas (ERCOT) territory, to compare the experimental WFIP forecasts to the existing short-term wind power forecasts (used at ERCOT) at multiple spatial and temporal scales. The study employs four significant wind power ramps definitions according to the power change magnitude, direction, and duration. The optimized swinging door algorithm is adopted to extract ramp events from actual and forecasted wind power time series. The results show that the experimental WFIP forecasts improve the accuracy of the wind power ramp forecasting. This improvement can result in substantial costs savings and power system reliability enhancements.

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An Optimized Swinging Door Algorithm for Identifying Wind Ramping Events

Cui

Zhang

Florita

et al. 2016

IEEE Trans. Sustain. Energy

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Wind-Friendly Flexible Ramping Product Design in Multi-Timescale Power System Operations

Cui

Zhang

et al. 2017

IEEE Trans. Sustain. Energy

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A Novel Event Detection Method Using PMU Data With High Precision

Cui

Wang

Tan

et al. 2019

IEEE Trans. Power Syst.

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Mingjian Cui

A data-driven multi-model methodology with deep feature selection for short-term wind forecasting

Wind Power Ramp Event Forecasting Using a Stochastic Scenario Generation Method

Model-Free Emergency Frequency Control Based on Reinforcement Learning

Machine Learning-Based Anomaly Detection for Load Forecasting Under Cyberattacks

Ramp forecasting performance from improved short-term wind power forecasting over multiple spatial and temporal scales

An Optimized Swinging Door Algorithm for Identifying Wind Ramping Events

Wind-Friendly Flexible Ramping Product Design in Multi-Timescale Power System Operations

A Novel Event Detection Method Using PMU Data With High Precision

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