Short-term wind forecasting via surface pressure measurements: stochastic modeling and sensor placement

TL;DR

This paper introduces a real-time wind forecasting method using surface pressure and nacelle measurements, combining stochastic models and Kalman filters, with optimized sensor placement for improved accuracy and speed.

Contribution

It develops a novel framework integrating stochastic modeling, sensor placement optimization, and Kalman filtering for enhanced short-term wind prediction at turbine hub height.

Findings

Kalman filtering improves wind prediction accuracy.

Sensor placement optimization reduces measurement requirements.

Synchronizing estimates with nacelle velocity enhances temporal tracking.

Abstract

We propose a short-term wind forecasting framework for predicting real-time variations in atmospheric turbulence based on nacelle-mounted anemometer and ground-level air-pressure measurements. Our approach combines linear stochastic estimation and Kalman filtering algorithms to assimilate and process real-time field measurements with the predictions of a stochastic reduced-order model that is confined to a two-dimensional plane at the hub height of turbines. We bridge the vertical gap between the computational plane of the model at hub height and the measurement plane on the ground using a projection technique that allows us to infer the pressure in one plane from the other. Depending on the quality of this inference, we show that customized variants of the extended and ensemble Kalman filters can be tuned to balance estimation quality and computational speed 1-1.5 diameters ahead and behind leading turbines. In particular, we show how synchronizing the sign of estimates with that of velocity fluctuations recorded at the nacelle can significantly improve the ability to follow temporal variations upwind of the leading turbine. We also propose a convex optimization-based framework for selecting a subset of pressure sensors that achieve a desired level of accuracy relative to the optimal Kalman filter that uses all sensing capabilities.