Abstract
Remote sensing devices (e.g., lidars) are quickly becoming a cost-effective and reliable alternative to meteorological towers for wind energy applications. Although lidars can measure mean wind speeds accurately, these devices measure different values of turbulence intensity (TI) than an instrument on a tower. In response to these issues, a lidar TI error reduction model was recently developed for commercially available lidars. The TI error model first applies physics-based corrections to the lidar measurements, then uses machine-learning techniques to further reduce errors in lidar TI estimates. The model was tested at two sites in the Southern Plains where vertically profiling lidars were collocated with meteorological towers. Results indicate that the model works well under stable conditions but cannot fully mitigate the effects of variance contamination under unstable conditions. To understand how variance contamination affects lidar TI estimates, a new set of equations was derived in previous work to characterize the actual variance measured by a lidar. Terms in these equations were quantified using a lidar simulator and modeled wind field, and the new equations were then implemented into the TI error model.
Highlights
Procedures such as wind resource assessment and turbine site suitability require measurements of the mean wind speed and turbulence intensity (TI) at the turbine hub height
Initial results shown here indicate that Lidar Turbulence Error Reduction Algorithm (L-TERRA) generally reduces TI errors under all stability conditions but does not fully capture TI errors under unstable conditions, likely as a result of variance contamination
There is no simple method to quantify the effects of variance contamination on lidar TI estimates
Summary
Procedures such as wind resource assessment and turbine site suitability require measurements of the mean wind speed and turbulence intensity (TI) at the turbine hub height. These measurements have been collected by cup anemometers on tall meteorological (met) towers. Lidars only provide an estimate of the line-of-sight velocity and must point the lidar beam toward different azimuth angles around a scanning circle to derive the full three-dimensional wind field This scanning circle, which has a diameter of approximately 100 m for a commercial lidar at a measurement height of 100 m, introduces a phenomenon known as variance contamination [1]. A lidar simulator is used to improve the variance contamination corrections in L-TERRA and future applications of the lidar simulator in improving lidar turbulence estimates are discussed
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