Analysis of Factors Influencing the Measurement Error of Ground-based LiDAR

Dong-Bum Kang; Jong-Chul Huh; Kyung-Nam Ko

doi:10.7836/kses.2017.37.6.025

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2017 Vol.37, Issue 6 Preview Page Next Page

Analysis of Factors Influencing the Measurement Error of Ground-based LiDAR 지상기반 라이다의 측정 오차에 영향을 미치는 요인 분석

30 December 2017. pp. 25-37

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Abstract

A study on factors influencing measurement error of Ground-based LiDAR(Light Detection And Ranging) system was conducted in Kimnyeong wind turbine test site on Jeju Island. Three properties of wind including inclined angle, turbulence intensity and power law exponent were taken into account as factors influencing the measurement error of Ground-based LiDAR. In order to calculate LiDAR measurements error, 2.5-month wind speed data collected from LiDAR (WindCube v2) were compared with concurrent data from the anemometer on a nearby 120m-high meteorological mast. In addition, data filtering was performed and its filtering criteria was based on the findings at previous researches. As a result, at 100m above ground level, absolute LiDAR error rate with absolute inclined angle showed 4.58~13.40% and 0.77 of the coefficients of determination, R². That with turbulence intensity showed 3.58~23.94% and 0.93 of R² while that with power law exponent showed 4.71~9.53% and 0.41 of R². Therefore, it was confirmed that the LiDAR measurement error was highly affected by inclined angle and turbulence intensity, while that did not much depend on power law exponent.

Keywords

Wind energy

Wind data

Light detection and ranging (LiDAR) system

Inclined angle

Turbulence intensity

Wind shear

키워드

풍력에너지

바람데이터

라이다 시스템

유동경사각

난류강도

풍속전단

References

World Wind Energy Association (WWEA). Wind Energy International 2014/2015, WWEC, pp. 9-24, 2013.

Joint Research Centre (JRC). 2014 JRC wind status report, JRC, pp. 16-17, 2015.

Brower M. C., Wind Resource Assessment, John Wiley & Sons, Inc, pp. 105-114, 2012.

Kim, H. G., Chyng, C. W., An, H. J., and Ji, Y. M., Comparative Validation of WindCube LIDAR and Remtech SODAR for Wind Resource Assessment - Remote Sensing Campaign at Pohang Accelerator Laboratory, Journal of the Korean Solar Energy Society, Vol. 31, No. 2, pp. 63-71, 2011.

Kim, H. G. and Choi, J. H., Uncertainty Analysis on Wind Speed Profile Measurements of LIDAR by Applying SODAR Measurements as a Virtual True Value, Journal of the Korean Solar Energy Society, Vol. 30, No. 4, pp. 79-85, 2010.

Deutsche WindGuard Consulting GmbH, Evaluation of ZephIR(Project No: VC 05250, Report No: PWG 06005), Deutsche WindGuard Consulting GmbH, 2006.

Renewable Energy Research Laboratory, MTC Final Progress Report-LIDAR, University of Massachusetts, 2007.

Kindler, D., Courtney, M., and Oldroyd, A., 2009, Testing and calibration of various lidar remote sensing devices for a 2 year offshore wind measurement campaign, EWEC, pp. 141-143.

Kim, D., Kim, T., Oh, G., Huh, J., and Ko, K., A Comparison of Ground-based LiDAR and Met Mast Wind Measurements for Wind Resource Assessment Over Various Terrain Conditions, Journal of Wind Engineering and Industrial Aerodynamics, Vol. 158, pp. 109-121, 2016.

Hyundai Heavy Industries, Business - Green Energy, https://english.hhi.co.kr.

Hyosung Power & Industrial systems, Products & Solutions - Green Energy, https://www.hyosungpni.co.kr.

Leosphere, WindCube v2 LiDAR Remote Sensor User Manual version 06, Leosphere, pp.18-19.

Thies Clima, The product information, https://www.thiesclima.com.

B. Cañadillas, A. Westerhellweg, T. Neumann, Testing the Performance of a Ground-based Wind LiDAR System, DEWI Magazine, No. 38, pp. 58-64, 2011.

Measnet, Evaluation of Site-specific Wind Conditions, Version 1, pp. 14-18, 2009.

A., González-Jorge, H., Lagüela, S., Díaz-Vilariño, L., and Arias, P., Quantifying the influence of rain in LiDAR performance, Measurement, Vol. 95, pp. 143-148, 2017.

17.International Electrotechnical Commission (IEC), IEC 61400-12-1, Wind Turbines - Power performance measurements of electricity producing wind turbines, 1st ed., IEC, pp. 15, 33-35, 2005.

18.Kang, D., Hyeon, J., Yang, K., Huh, J., and Ko, K., Analysis and Verification of Wind Data from Ground-based LiDAR, International Journal of Renewable Energy Research, Vol. 7, No. 2, 2017.

International Electrotechnical Commission (IEC), IEC 61400-1, Wind Turbines - Design requirements, 3rd ed., IEC, pp. 21-23, 2005.

Windographer 3.3.11 User Manual, https://www.windographer.com.

International Electrotechnical Commission (IEC), IEC 61400-12-1, Wind Turbines - power performance measurements of electricity producing wind turbines, Draft FDIS, IEC, pp. 31, 2016.

Boquet, M., Ribstein, B., Parmentier, R., Sauvage, L., and Cariou, J., Analysis and Optimisation of Pulsed Doppler Lidar Wind Profile Measurement Process in Complex Terrain, 15th Coherent Laser Radar Conference Proceedings, pp. 69-72, 2008.

Kim, H. and Meissner, C., 2017, Correction of LiDAR Measurement Error in Complex Terrain by CFD: Case Study of the Yangyang Pumped Storage Plant, Wind Engineering, Vol. 41, No. 4, pp. 226-234.

Jain Pramod, Wind Energy Engineering, Mc GrawHill Companies, Inc., pp. 101-104, 2011.

Manwell J. F., McGowan J. G., and Rogers A. L., Wind Energy Explained: Theory, Design and Application, 2nd ed., Wiley, pp. 39-48, 2009.

Information

Publisher :Korean Solar Energy Society
Publisher(Ko) :한국태양에너지학회
Journal Title :Journal of the Korean Solar Energy Society
Journal Title(Ko) :한국태양에너지학회 논문집
Volume : 37
No :6
Pages :25-37
Received Date : 2017-06-12
Revised Date : 2017-11-03
Accepted Date : 2017-12-12
DOI :https://doi.org/10.7836/kses.2017.37.6.025

Journal of the Korean Solar Energy Society ISSN:1598-6411(Print) 2508-3562(Online) 한국태양에너지학회 논문집

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