An error reduction algorithm to improve lidar turbulence estimates for wind energy

Newman, Jennifer F.; Clifton, Andrew

doi:10.5194/wes-2-77-2017

Cited by 21 publications

(15 citation statements)

References 55 publications

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“…A machine-learning approach to produce unfiltered wind speed variances from pulsed lidar signals was used in Newman and Clifton (2017). Besides a model for the spatial averaging the algorithm also includes automatic noise removal.…”

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confidence: 99%

Comparison of Methods to Derive Radial Wind Speed from a Continuous-Wave Coherent Lidar Doppler Spectrum

Held¹,

Mann²

2018

Preprint

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Abstract. Continuous-wave lidar systems offer the possibility to remotely sense wind speed but are also affected by inherent differences in their measurement process compared to more traditional anemometry like cup or sonic anemometers. Their large measurement volume leads to an attenuation of turbulence. In this paper we study how different methods to derive the radial wind speed from a lidar Doppler spectrum can mitigate turbulence attenuation. The centroid, median and maximum methods are compared by estimating transfer functions and calculating root mean squared errors (RMSE) between a lidar and a sonic 5 anemometer. Numerical simulations and experimental results both indicate that the maximum method, even though using the least amount of information from the Doppler spectrum, performs best at mitigating the volume averaging effect. However, this benefit is paid by increased signal noise due to the discretisation of the maximum method. The median method shows slight improvements over the centroid method in terms of volume averaging reduction and also resulted in the overall lowest RMSE.Thus, when the aim is to obtain point-like wind speed time series with high temporal resolution, the median method is superior 10 to the centroid and maximum method. When comparing 10 minute averages there is no difference between the methods.

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confidence: 99%

Comparison of Methods to Derive Radial Wind Speed from a Continuous-Wave Coherent Lidar Doppler Spectrum

Held¹,

Mann²

2018

Preprint

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“…43 In order to derive meaningful TI values from lidar data though, several approaches have been proposed. 44,45 A check of their application to FLS data and their combination with the existing motion correction algorithms has yet to be performed.…”

Section: Turbulence Intensity Data From Flsmentioning

confidence: 99%

Floating lidar as an advanced offshore wind speed measurement technique: current technology status and gap analysis in regard to full maturity

Gottschall

Gribben²,

Stein

et al. 2017

WIREs Energy & Environment

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Floating lidar was introduced in 2009 as an offshore wind measurement technology focusing on the specific needs of the wind industry with regard to wind resource assessment applications. Floating lidar systems (FLS) are meant to replace an offshore met mast, being significantly cheaper and saving an essential part of project upfront investment costs. But at the same time, they need to overcome particular challenges—these are (1) the movement of the sea imparting motion on the buoy and the lidar, and the subsequent challenge of maintaining wind speed and direction accuracy, and (2) the remoteness of the deployed system in an extremely challenging environment necessitating robust, autonomous and reliable operation of measurement, power supply, data logging, and communication systems. The issue of motion influences was investigated in a number of studies and is to be checked and monitored in offshore trials of individual FLS realizations. In trials to date, such influences have been demonstrated to be negligibly or manageably small with the application of motion reduction or compensation strategies. Thereby, it is possible to achieve accurate wind measurement data from FLS. The second kind of challenge is tackled by implementing a sufficiently robust and reliable FLS design. Recommended practices collected by a working group within the International Energy Agency (IEA) Wind Task 32 and within the UK offshore wind accelerator program offer guidance for FLS design and configuration, and furthermore set requirements for trialing the system types and individual devices in representative offshore conditions. WIREs Energy Environ 2017, 6:e250. doi: 10.1002/wene.250 This article is categorized under: Wind Power > Science and Materials Wind Power > Climate and Environment

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“…The lidar methods and results of the lidar studies of the ABL, the height of the turbulent mixing layer at different temperature stratifications, and the different types of underlying surfaces are discussed in the literature [11][12][13][14][15]. The capabilities of the lidar methods in the studies of wind turbulence and the results of their testing in atmospheric experiments are discussed in the literature [16][17][18][19][20][21][22][23][24][25][26][27].…”

Section: Introductionmentioning

confidence: 99%

“…Fewer theoretical works are devoted to study of the structure of a stable ABL. Despite the obtained theoretical results and a large number of works devoted to experimental lidar studies of the atmospheric boundary layer [16][17][18][19][20][21][22][23][24][25][26][27], it remains unclear whether the stable boundary layer of the atmosphere has a layered structure such as that of the upper atmosphere.…”

Section: Introductionmentioning

confidence: 99%

“…For that, in the measurements, we employed coherent Doppler wind lidar concurrently with a microwave temperature profiler. As a result, we succeeded in not only obtaining data on the wind processes but also, in contrast to the lidar experiments on ABLs [16][17][18][19][20][21][22][23][24][25][26][27], relating them with the temperature regime in the ABL.…”

Section: Introductionmentioning

confidence: 99%

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Wind–Temperature Regime and Wind Turbulence in a Stable Boundary Layer of the Atmosphere: Case Study

2020

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The paper presents the results of probing the stable atmospheric boundary layer in the coastal zone of Lake Baikal with a coherent Doppler wind lidar and a microwave temperature profiler. Two-dimensional height–temporal distributions of the wind velocity vector components, temperature, and parameters characterizing atmospheric stability and wind turbulence were obtained. The parameters of the low-level jets and the atmospheric waves arising in the stable boundary layer were determined. It was shown that the stable atmospheric boundary layer has an inhomogeneous fine scale layered structure characterized by strong variations of the Richardson number Ri. Layers with large Richardson numbers alternate with layers where Ri is less than the critical value of the Richardson number Ricr = 0.25. The channels of decreased stability, where the conditions are close to neutral stratification 0 < Ri < 0.25, arise in the zone of the low-level jets. The wind turbulence in the central part of the observed jets, where Ri > Ricr, is weak, increases considerably to the periphery of jets, at heights where Ri < Ricr. The turbulence may intensify at the appearance of internal atmospheric waves.

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An error reduction algorithm to improve lidar turbulence estimates for wind energy

Cited by 21 publications

References 55 publications

Comparison of Methods to Derive Radial Wind Speed from a Continuous-Wave Coherent Lidar Doppler Spectrum

Comparison of Methods to Derive Radial Wind Speed from a Continuous-Wave Coherent Lidar Doppler Spectrum

Floating lidar as an advanced offshore wind speed measurement technique: current technology status and gap analysis in regard to full maturity

Wind–Temperature Regime and Wind Turbulence in a Stable Boundary Layer of the Atmosphere: Case Study

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