Pedestrian Wind Factor Estimation in Complex Urban Environments

Urban planners and policy makers face the challenge of creating livable and enjoyable cities for larger populations in much denser urban conditions. While the urban microclimate holds a key role in defining the quality of urban spaces today and in the future, the integration of wind microclimate assessment in early urban design and planning processes remains a challenge due to the complexity and high computational expense of computational fluid dynamics (CFD) simulations. This work develops a data-driven workflow for real-time pedestrian wind comfort estimation in complex urban environments which may enable designers, policy makers and city residents to make informed decisions about mobility, health, and energy choices. We use a conditional generative adversarial network (cGAN) architecture to reduce the computational computation while maintaining high confidence levels and interpretability, adequate representation of urban complexity, and suitability for pedestrian comfort estimation. We demonstrate high quality wind field approximations while reducing computation time from days to seconds.

[1]  Thomas Brox,et al.  FlowNet 2.0: Evolution of Optical Flow Estimation with Deep Networks , 2016, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[2]  Rob Fergus,et al.  Stochastic Video Generation with a Learned Prior , 2018, ICML.

[3]  V. Dorer,et al.  Urban Physics: Effect of the micro-climate on comfort, health and energy demand , 2012 .

[4]  Alexei A. Efros,et al.  Image-to-Image Translation with Conditional Adversarial Networks , 2016, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[5]  J. Nathan Kutz,et al.  Deep learning in fluid dynamics , 2017, Journal of Fluid Mechanics.

[6]  Meisam Babanezhad,et al.  Simulation of liquid flow with a combination artificial intelligence flow field and Adams–Bashforth method , 2020, Scientific reports.

[7]  Amir Barati Farimani,et al.  Deep Learning the Physics of Transport Phenomena , 2017, ArXiv.

[9]  Léon Bottou,et al.  Wasserstein Generative Adversarial Networks , 2017, ICML.

[10]  Athanasios Vitsas,et al.  Towards Sustainable Architecture: 3D Convolutional Neural Networks for Computational Fluid Dynamics Simulation and Reverse DesignWorkflow , 2019, ArXiv.

[11]  Wei Li,et al.  Convolutional Neural Networks for Steady Flow Approximation , 2016, KDD.

[12]  Simon Osindero,et al.  Conditional Generative Adversarial Nets , 2014, ArXiv.

[13]  Sean Hanna,et al.  Beyond simulation: designing for uncertainty and robust solutions , 2010, SpringSim.

[14]  Ling Zhang,et al.  RBF neural networks for the prediction of building interference effects , 2004 .

[15]  Antonio Torralba,et al.  Generating Videos with Scene Dynamics , 2016, NIPS.

[16]  Fergus R. Fricke,et al.  The interference index and its prediction using a neural network analysis of wind-tunnel data , 1999 .

[17]  Petros Koumoutsakos,et al.  Machine Learning for Fluid Mechanics , 2019, Annual Review of Fluid Mechanics.

[18]  Wangda Zuo,et al.  Simulating Natural Ventilation in and Around Buildings by Fast Fluid Dynamics , 2013 .

[19]  D. Grawe,et al.  BEST PRACTICE GUIDELINE FOR THE CFD SIMULATION OF FLOWS IN THE URBAN ENVIRONMENT , 2007 .

[20]  Qingming Zhan,et al.  A surrogate-assisted optimization framework for microclimate-sensitive urban design practice , 2021 .

[21]  Jonathan Lindström,et al.  A life between the buildings , 2014 .

[22]  Jakob Uszkoreit,et al.  Scaling Autoregressive Video Models , 2019, ICLR.

[23]  Alex Kendall,et al.  What Uncertainties Do We Need in Bayesian Deep Learning for Computer Vision? , 2017, NIPS.

[24]  J. Jacobs The Death and Life of Great American Cities , 1962 .

[25]  Sanja Fidler,et al.  DriveGAN: Towards a Controllable High-Quality Neural Simulation , 2021, 2021 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR).

[26]  Shunta Saito,et al.  Temporal Generative Adversarial Nets with Singular Value Clipping , 2016, 2017 IEEE International Conference on Computer Vision (ICCV).

[27]  Karthik Duraisamy,et al.  Turbulence Modeling in the Age of Data , 2018, Annual Review of Fluid Mechanics.

[28]  Yike Guo,et al.  A reduced order model for turbulent flows in the urban environment using machine learning , 2019, Building and Environment.

[29]  Timo Aila,et al.  A Style-Based Generator Architecture for Generative Adversarial Networks , 2018, 2019 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR).