Comparative analysis of estimators for wind direction standard deviation

P. S. Farrugia; A. Micallef

doi:10.1017/S1350482705001982

Abstract

Wind direction is a circular variable. This makes the algorithms used to find its standard deviation different from that of the linear variables. In particular, the requirement for storing all the data points before the standard deviation can be computed limits the storage capacity and puts great strain on remote data acquisition systems. Various algorithms have therefore been developed to estimate the standard deviation in order to reduce the number of terms stored. The following work consists of a comparative analysis of such estimators together with the parameters used. It emerges that some of the assumptions adopted to produce the equations being analysed do not hold in practice, even though this does not affect significantly the performance of the estimators that depend on them. On the other hand, the parameter that has the best trend with the algorithm adopted is the magnitude of the vector to the centre of gravity of the system. However, such a result gives rise to some concerns since it does not account for the ‘vectorial’ nature of the angle being treated.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Pulvirenti, Luca Pierdicca, Nazzareno and Marzano, Frank 2008. Coupling a Neural Network-Based forward Model and a Bayesian Inversion Approach to Retrieve Wind Field from Spaceborne Polarimetric Radiometers. Sensors, Vol. 8, Issue. 12, p. 7850.

Pérez, Isidro A. Luisa Sánchez, M. Ángeles García, M. and de Torre, Beatriz 2008. Description and distribution fitting of transformed sodar wind observations. Journal of Atmospheric and Solar-Terrestrial Physics, Vol. 70, Issue. 1, p. 89.

Farrugia, Pierre S. Borg, James L. and Micallef, Alfred 2009. On the Algorithms Used to Compute the Standard Deviation of Wind Direction. Journal of Applied Meteorology and Climatology, Vol. 48, Issue. 10, p. 2144.

Stegall, Steve T. and Zhang, Jing 2012. Wind Field Climatology, Changes, and Extremes in the Chukchi–Beaufort Seas and Alaska North Slope during 1979–2009. Journal of Climate, Vol. 25, Issue. 23, p. 8075.

Hájek, Petr and Olej, Vladimír 2013. Engineering Applications of Neural Networks. Vol. 383, Issue. , p. 302.

Gioli, Beniamino Carfora, Maria F. Magliulo, Vincenzo Metallo, Maria C. Poli, Attilio A. Toscano, Piero and Miglietta, Franco 2014. Aircraft mass budgeting to measure CO2 emissions of Rome, Italy. Environmental Monitoring and Assessment, Vol. 186, Issue. 4, p. 2053.

Lin, Wenming Portabella, Marcos Stoffelen, Ad Vogelzang, Jur and Verhoef, Anton 2015. ASCAT wind quality under high subcell wind variability conditions. Journal of Geophysical Research: Oceans, Vol. 120, Issue. 8, p. 5804.

Silva, Adaiana Francisca Gomes da Zaparoli, Edson Luiz and Fisch, Gilberto 2016. Uma Análise da Aplicação de Três Métodos Estatísticos para o Cálculo do Desvio Padrão da Direção do Vento na Região Tropical. Revista Brasileira de Meteorologia, Vol. 31, Issue. 1, p. 45.

Hernández-Ceballos, M.A. Sorribas, M. San Miguel, E.G. Cinelli, G. Adame, J.A. and Bolívar, J.P. 2016. Impact of sea-land breezes on 210Pb in southern Iberian Peninsula – Feasibility study on using submicron-sized aerosol particles to analyze 210Pb hourly patterns. Atmospheric Pollution Research, Vol. 7, Issue. 1, p. 1.

Farrugia, Pierre S. and Micallef, Alfred 2017. Vectorial statistics for the standard deviation of wind direction. Meteorology and Atmospheric Physics, Vol. 129, Issue. 5, p. 495.

Wilks, Daniel S. 2019. Statistical Methods in the Atmospheric Sciences. p. 23.

2019. Statistical Methods in the Atmospheric Sciences. p. 771.

Aslam, Muhammad and Al-Marshadi, Ali Hussein 2022. A New Test for Ridge Wind Directional Data Under Neutrosophic Statistics. Frontiers in Energy Research, Vol. 10, Issue. ,

Sheridan, Peter Xu, Anlun Li, Jian and Furtado, Kalli 2023. Use of Targeted Orographic Smoothing in Very High Resolution Simulations of a Downslope Windstorm and Rotor in a Sub-tropical Highland Location. Advances in Atmospheric Sciences, Vol. 40, Issue. 11, p. 2043.

Kanwal, Ammara Tahir, Zia ul Rehman Asim, Muhammad Hayat, Nasir Farooq, Muhammad Abdullah, Muhammad and Azhar, Muhammad 2023. Evaluation of Reanalysis and Analysis Datasets against Measured Wind Data for Wind Resource Assessment. Energy & Environment, Vol. 34, Issue. 5, p. 1258.

Liponhay, Marissa P. Valerio, Alyssa V. and Monterola, Christopher P. 2024. Time-delayed causal network analysis of meteorological variables and air pollutants in Baguio city. Atmospheric Pollution Research, Vol. 15, Issue. 6, p. 102095.

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Comparative analysis of estimators for wind direction standard deviation

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Comparative analysis of estimators for wind direction standard deviation

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