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Materials and Thermodynamics

Living and Economic Systems

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Mechanics of Aeronautical Composite Materials

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Finite Physical Dimensions Optimal Thermodynamics 1


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Co-design in Living Labs for Healthcare and Independent Living

Concepts, Methods and Tools

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Metaheuristics for Intelligent Electrical Networks

Metaheuristics Set – Volume 10

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RCS Synthesis for Chipless RFID

Theory and Design

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Fundamentals of Electronics 1

Electronic Components and Elementary Functions

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Swift Ion Beam Analysis in Nanosciences

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Inside Anthropotechnology

User and Culture Centered Experience

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Ethics in Social Networking and Business 1

Theory, Practice and Current Recommendations

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Solar Energy at Urban Scale

Edited by Benoit Beckers, Compiègne University of Technology, France

ISBN: 9781848213562

Publication Date: May 2012   Hardback   384 pp.

165.00 USD

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Increasing urbanization throughout the world, the depletion of fossil fuels and concerns about global warming have transformed the city into a physical problem of prime importance. This book proposes a multi-disciplinary and systematic approach concerning specialities as different as meteorology, geography, architecture and urban engineering systems, all surrounding the essential problem of solar radiation. It collects the points of view of 18 specialists from around the world on the interaction between solar energy and constructions, combining territorial, urban and architectural scales to better regulate energetic efficiency and light comfort for the sustainable city. The main subjects covered are: measures and models of solar irradiance (satellite observations, territorial and urban ground measurements, sky models, satellite data and urban mock-up), radiative contribution to the urban climate (local heat balance, radiative-aerodynamics coupling, evapotranspiration, Urban Heat Island), light and heat modeling (climate-based daylight modeling, geometrical models of the city, solar radiation modeling for urban environments, thermal simulation methods and algorithms) and urban planning, with special considerations for solar potential, solar impact and daylight rights in the temperate, northern and tropical climates, and the requirement of urban solar regulation.


1. The Odyssey of Remote Sensing from Space: Half a Century of Satellites for Earth Observations, Théo Pirard.
2. Territorial and Urban Measurements, Marius Paulescu and Viorel Badescu.
3. Sky Luminance Models, Matej Kobav and Grega Bizjak.
4. Satellite Images Applied to Surface Solar Radiation Estimation, Bella Espinar and Philippe Blanc.
5. Worldwide Aspects of Solar Radiation Impact, Benoit Beckers.
6. Local Energy Balance, Pierre Kastendeuch.
7. Evapotranspiration, Marjorie Musy.
8. Multiscale Daylight Modeling for Urban Environments, John Mardaljevic and George Janes.
9. Geometrical Models of the City, Daniel G. Aliaga.
10. Radiative Simulation Methods, Pierre Beckers and Benoit Beckers.
11. Radiation Modeling Using the Finite Element Method, Tom van Eekelen.
12. Dense Cities in the Tropical Zone, Edward Ng.
13. Dense Cities in Temperate Climates: Solar and Daylight Rights, Guedi Capeluto.
14. Solar Potential and Solar Impact, Frédéric Monette and Benoit Beckers.
Appendix 1. Table of Europe’s Platforms (Micro- and Minisatellites) for Earth Observations, Théo Pirard.
Appendix 2. Commercial Operators of Earth Observation (EO) Satellites (as of January 1, 2012), Théo Pirard.
Appendix 3. Earth’s Annual Global Mean Energy Budget, Benoit Beckers.

About the Authors

Benoit Beckers has been Associate Professor in the Department of Urban Systems Engineering, Compiègne University of Technology, France, since 2008. He specializes in radiation modeling for architectural and urban projects (sound, light and heat), geometric methods and perception.


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