Fast and Accurate Urban Atmospheric Models

快速准确的城市大气模型

• 批准号: RGPIN-2017-04018
• 负责人: Aliabadi, AmirAbbas
• 金额: $ 1.53万
• 依托单位: University of Guelph
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=678091
• 关键词: Fast; Accurate; Urban; Atmospheric; Models

Cities occupy approximately 2% of the earth's surface and accommodate more than 50% of the world's population. Understanding and mitigating the growing environmental impact of cities require design and prediction tools, such as the Urban Atmospheric Models (UAMs). UAMs predict the urban climate (air temperature, wind, precipitation, and humidity) and pollution dispersion (distribution of air pollutants in the urban environment). UAMs help understand, develop, and regulate more sustainable cities toward the control of the urban air temperature, moisture, and winds and the improvement of air quality within urban spaces.******The proposed interdisciplinary research program attempts to develop novel, fast, and accurate operational UAMs based on reduced-order and Artificial Intelligence (AI) approaches to account for the realistic urban environment. The realistic urban environment is currently not well represented in operational models or is otherwise too computationally expensive to model. The UAMs will account for 1) complexity of the urban morphology such as variety of geometries and length scales in buildings, landscapes, roads, and other urban components, 2) thermal effects such as differential heating on urban surfaces or the influence of stable/unstable boundary layers, and 3) pollution dispersion from realistic anthropogenic emissions by vehicles and buildings.******The scientific approach includes development of experimental and numerical databases to formulate and validate the UAMs. Experimental databases will be developed from a novel blimp (balloon) platform (first one of its kind in Canada), wind tunnel, water channel, field, and remote sensing measurements. Numerical databases will be developed from high spatiotemporal resolution models for parametric study of realistic urban environments using computational fluid dynamics, energy balance, dispersion, and atmospheric models. These databases will be used to develop the new UAMs based on a 1D vertical diffusion (reduced-order) and Artificial Neural Network (AI) models.******This research program contributes to knowledge of complex physics influencing the urban atmosphere and the ability to develop models to predict it. It results in UAMs that can be commercialized as stand-alone design and prediction tools for use by various architectural firms, engineering consulting firms, and urban planners. It will train HQP with data science by collection, generation, processing, and analysis of big data, and by building and validating simple or complex models for the urban atmosphere. It provides environmental benefits by improving operational forecast and air quality models, both in Canada or internationally, with computational speed and accuracy. It provides social benefits toward more sustainable urban development for the future generations by reducing their energy consumption and improving their environmental conditions.

城市约占地球表面的2%，容纳了世界人口的50%以上。了解和减轻城市日益增长的环境影响需要设计和预测工具，如城市大气模型（UAMs）。UAM预测城市气候（空气温度，风，降水和湿度）和污染扩散（城市环境中空气污染物的分布）。UAMs有助于了解，发展和调节更可持续的城市，以控制城市空气温度，湿度和风，并改善城市空间内的空气质量。拟议的跨学科研究计划试图开发基于降阶和人工智能（AI）方法的新颖，快速，准确的操作UAM，以应对现实的城市环境。现实的城市环境目前没有很好地表示在业务模型或否则是太昂贵的计算模型。UAM将考虑1）城市形态的复杂性，例如建筑物、景观、道路和其他城市组成部分的几何形状和长度尺度的多样性，2）热效应，例如城市表面的差异加热或稳定/不稳定边界层的影响，以及3）车辆和建筑物的实际人为排放的污染扩散。科学方法包括开发实验和数值数据库，以制定和验证无人机模型。实验数据库将从一个新的飞艇（气球）平台（在加拿大的第一个），风洞，水道，现场和遥感测量。将利用计算流体动力学、能量平衡、扩散和大气模型，从高时空分辨率模型中开发数值数据库，用于对现实城市环境进行参数研究。这些数据库将用于开发基于一维垂直扩散（降阶）和人工神经网络（AI）模型的新UAM。该研究计划有助于了解影响城市大气的复杂物理学知识，并开发模型来预测它。它导致UAM可以作为独立的设计和预测工具商业化，供各种建筑公司，工程咨询公司和城市规划师使用。它将通过收集、生成、处理和分析大数据，以及通过构建和验证城市大气的简单或复杂模型，来培训HQP。它通过改进加拿大或国际上的业务预报和空气质量模型，以计算速度和准确性提供环境效益。它通过减少能源消耗和改善环境条件，为子孙后代实现更可持续的城市发展提供社会效益。