Using Machine Learning to Predict Wind Flow in Urban Areas

被引：17

作者：

BenMoshe, Nir ^{[1
]}

Fattal, Eyal ^{[1
]}

Leitl, Bernd ^{[2
]}

Arav, Yehuda ^{[1
]}

机构：

[1] Israel Inst Biol Res, Dept Appl Math, POB 19, IL-7410001 Ness Ziona, Israel

[2] Univ Hamburg, Meteorol Inst Informat & Nat Sci, Dept Math, Bundesstr 55, D-20146 Hamburg, Germany

来源：

ATMOSPHERE | 2023年 / 14卷 / 06期

关键词：

wind; urban; machine learning; CFD; openFOAM; AIR-QUALITY; DISPERSION; TUNNEL; MODEL; SIMULATIONS; VALIDATION; BUILDINGS; COMFORT; RANS;

D O I：

10.3390/atmos14060990

中图分类号：

X [环境科学、安全科学];

学科分类号：

08 ; 0830 ;

摘要：

Solving the hydrodynamical equations in urban canopies often requires substantial computational resources. This is especially the case when tackling urban wind comfort issues. In this article, a novel and efficient technique for predicting wind velocity is discussed. Reynolds-averaged Navier-Stokes (RANS) simulations of the Michaelstadt wind tunnel experiment and the Tel Aviv center are used to supervise a machine learning function. Using the machine learning function it is possible to observe wind flow patterns in the form of eddies and spirals emerging from street canyons. The flow patterns observed in urban canopies tend to be predominantly localized, as the machine learning algorithms utilized for flow prediction are based on local morphological features.

引用

页数：17

共 37 条

[1] AN INTRODUCTION TO KERNEL AND NEAREST-NEIGHBOR NONPARAMETRIC REGRESSION [J].

ALTMAN, NS .

AMERICAN STATISTICIAN, 1992, 46 (03) :175-185

[2]

[Anonymous], 1987, PUBLIC STREETS PUBLI

[3] Urban wind conditions and small wind turbines in the built environment: A review [J].

Anup, K. C. ;

Whale, Jonathan ;

Urmee, Tania .

RENEWABLE ENERGY, 2019, 131 :268-283

[4]

Baumann-Stanzer K., 2015, COST ES1006 Model Evaluation Case Studies: Approach and Results.

[5] Pedestrian-level wind conditions around buildings: Review of wind-tunnel and CFD techniques and their accuracy for wind comfort assessment [J].

Blocken, B. ;

Stathopoulos, T. ;

van Beeck, J. P. A. J. .

BUILDING AND ENVIRONMENT, 2016, 100 :50-81

[6] Pedestrian wind comfort around a large football stadium in an urban environment: CFD simulation, validation and application of the new Dutch wind nuisance standard [J].

Blocken, B. ;

Persoon, J. .

JOURNAL OF WIND ENGINEERING AND INDUSTRIAL AERODYNAMICS, 2009, 97 (5-6) :255-270

[7]

Caretto L.S., 1972, Problems of Fluid Mechanics, V19, P60, DOI [10.1007/BFb0112677, DOI 10.1007/BFB0112677, 10.1007/BFb0112677ofLectureNotesinPhysics]

[8] Validation of a Lagrangian particle dispersion model with wind tunnel and field experiments in urban environment [J].

Castelli, S. Trini ;

Armand, P. ;

Tinarelli, G. ;

Duchenne, C. ;

Nibart, M. .

ATMOSPHERIC ENVIRONMENT, 2018, 193 :273-289

[9] Air quality model performance evaluation [J].

Chang, JC ;

Hanna, SR .

METEOROLOGY AND ATMOSPHERIC PHYSICS, 2004, 87 (1-3) :167-196

[10] Scaling of Flows Over Realistic Urban Geometries: A Large-Eddy Simulation Study [J].

Cheng, Wai-Chi ;

Yang, Ying .

BOUNDARY-LAYER METEOROLOGY, 2023, 186 (01) :125-144

← 1 2 3 4 →