Tensegrity systems
Bel Hadj Ali ,N. &. Smith, I.F.C. Dynamic behavior and vibration control of a tensegrity structure. Applied Computing and Mechanics laboratory Ecole Polytechnique Federale de Lausanne (EPFL)
Buckminster, F. & Applewhite, E.J., 1975. Synergetics: explorations in the geometry of thinking. New York: Macmillan. Also available in http://www.rwgrayprojects.com/synergetics/synergetics.html
Burrows, J., 1989. Catalogue Introduction, In The New York Academy of Sciences (ed.), Kenneth Snelson Exhibition: The Nature of Structure. New York (USA), January - April 1989.
Chandana, P., Hod, L. & Valero Cuevas F. Evolutionary Form-Finding of Tensegrity Structures. Mechanical and Aerospace Engineering Cornell University
Josep, M., Mirats T. & Sergi H.J. 1991. Tensegrity frameworks: Dynamic analysis review and open problems
Motro R., 2002. Tensegrity: The State of the Art, In Space Structures 5, 97-106, London: Thomas Telford.
Motro, R., 2003. Tensegrity: structural systems for the future. London: Kogan Page Science
Parsons, J. & Marcer, N., 2005. Osteopathy. Models for Diagnosis, Treatment and Practice. Oxford: Elsevier
Tristan d’Estrée Sterk, Shape control in responsive architectural structures- current reasons & challenges. The School Of Interactive Arts & Technology, Simon Fraser University, Canada
Tristan d’Estrée Sterk, Using Actuated Tensegrity Strucutres to produce a responsive architecture. The school of the Art Institute of Chicago, USA
Sushant V., Pradeep D., 2011-2013. Adaptive Skins. AA_Em.Tech. http://adaptiveskins.com/
Wind Movement and Computational Fluid Dynamics
Blocken, B. & Carmeliet, J., 2004, Pedestrian Wind Environment around Buildings: Literature Review and Practical Examples. Journal of Thermal Envelope and Building Science, 28(2): 107-159.
Blocken, B., Carmeliet, J. & Stathopoulos, T., 2007. CFD Evaluation of wind speed conditions in passages between parallel buildings- effect of wall- function roughness modifications for the atmospheric boundary layer flow. Journa of wind engineering and industrial aerodynamics, 95 (9-11): 941-962
Blocken B, Janssen WD, van Hooff T. 2012. CFD simulation for pedestrian wind comfort and wind safety in urban areas: General decision framework and case study for the Eindhoven University campus. Environmental Modelling & Software 30: 15-34.
Bottema, M., 2000. A method for optimization of wind discomfort criteria. Building and Environment, 35(1): 1-18.
Bottema, M., 1993. Wind climate and urban geometry. Ph.D. thesis, Eindhoven University of Technology
Capeluto, I. G., Yezioro, A. & Shaviv, E. 2003. Climatic aspects in urban design: a case study, In Building ad Environment, 38(6): 827-835
Chronis, A., Turner, A. & Tsigkari, M. 2011. Generative Fluid Dynamics: Integration of Fast Fluid Dynamics and Genetic Algorithms for wind loading optimization of a free form surface. Proceedings of the Symposium on Simulation for Architecture and Urban Design, 2011, Boston, USA, 79-86.
Karagkouni, C. 2012. Façade’s apertures optimization. Integrating cross ventilation in Fluid Dynamics analysis in early design stages.
Chung, D. H. J. & L. C. Malone Lee (2010), ‘Computational Fluid Dynamics for Urban Design’, In Proceedings of the 15th International Conference on Computer Aided Architectural Design Research in Asia CAADRIA, April 2010, Hong Kong, China, 357–366.
Foster, N. & Metaxas, D. 1996. Realistic animation of liquids. Graphical models and image processing, 58(5): 471-483
Givoni B et al., 2003. Outdoor comfort research issues, Energy and Buildings, vol. 35, pp. 77-86.
Oke, T.R., 1987. Boundary Layer Climates, Second Edition. Routledge
Lawson, T.V & Penwarden, A.D. 1975. The effects of wind on people in vicinity of buildings. Proceedings of the Fourth International Conference on Wind Effects on Buildings and Structures (London, England), Cambridge University Press, Cambridge, UK, 605-622
Murakami, S., Uehara, K. & Deguchi, K. 1979. Wind effect on pedestrians: new criterisbased on outdoor observation of over 2000 persons, Wind Engineering. In: J.E Cermak (ed.), Wind Engineering, 277-288
Neema, S. 2011. Pedestrian wind comfort criteria. Incorporation of Agent Based model with Fast fluid dynamics to study pedestrian wind comfort using pedestrian behavior.
Reiter, S., 2010. Assessing wind comfort in urban planning. Environment and Planning B: Planning and Design, 857-873
Stam, J. 1999. Stable fluids. Proceedings of the 26th annual conference on computer graphics and interactive techniques, August 1999, Los Angeles, USA, 121-128
Stam, J. 2003. Real time fluid dynamics for games. Proceedings of the Game Developer Conference
Zuo, W. & Chen, Q. 2007. Validation of fast fuid dynamics for room airflow. Proceedings of the 10th International IBPSA Conference – Building simulation, Beijing, China
Windbreak
Caborn, J.M., 1957. Shelterbelts and microclimate. Edinburgh University, Bulletin, 29, Forestry commission, 136 p.
DeWalle, D.R., Heisler, G.M. 1983. Windbreak effects on air infiltration and space heating in a mobile home. Energy and Buildings. 5: 279-288.
Heisler, G.M., Dewalle, D.R., 1988. Effects of windbreak structure on wind flow. Agric. Eco-systems Environ., 22/23: 41-69
Johnson, S.R, 1997. Farmstead Windbreaks: Planning. Iowa State University.
Katarzyna K., The influence of windscreen on wind flow, (2007), CESB 07 Prague Conference, Session T3B: Internal Environment
Pescaru, R.A., Akileh, H.A.A. & Radu A., 2011. Laboratory measurements of wind velocity field behind windbreak screens, Gheorghe Asachi Technical University of Iasi, Faculty of Civil Engineering and Building Services
Plate, E.J., 1971. The aerodynamics of shelterbelts. Agric. Meteorol. 8, 203.
Vigiak O., Sterk G., Warren A, Hagen L. G., (2003), Spatial modeling of wind speed around windbreaks, available at www.elsevier.com/locate/catena
Stredova H., Podhrazska J., Litschmann T., Streda T., Roznovsky J., (2012), Aerodynamic parameters of windbreak based on its optical porosity, Contributions to Geophysics and Geodesy, Vol. 42/3, 213–22
Wang, H. & Takle, E.S. 1995. A numerical simulation of boundary layer flows near shelter- belts. Boundary-Layer Meteorol, 75: 141–173
Wang, H. & Takle, E.S. 1996. On three-dimensionality of shelterbelt structure and its influences on shelter effects. Boundary-Layer Meteorol ,79: 83–105
Wei L., Wang F. & Bell S., (2003), Windbreak sheltering effects on outdoor open spaces, Eighth International IBPSA Conference
Pedestrian wind comfort criteria
Ghosh, E., Mittal A.K. 2012. A review on pedestrian wind comfort around tall buildings. VI National Conference on Wind Engineering p.491-506
Lawson,T.V.andPenwarden,A.D.(1975).The effects of wind on people in the vicinity of buildings, Proceedings 4th International Conference on Wind Effects on Buildings and Structures, Heathrow, Cambridge University Press, pp. 605-622.
Blocken B, Janssen WD, van Hooff T. 2012. CFD simulation for pedestrian wind comfort and wind safety in urban areas: General decision framework and case study for the Eindhoven University campus. Environmental Modelling & Software 30: 15-34
Bel Hadj Ali ,N. &. Smith, I.F.C. Dynamic behavior and vibration control of a tensegrity structure. Applied Computing and Mechanics laboratory Ecole Polytechnique Federale de Lausanne (EPFL)
Buckminster, F. & Applewhite, E.J., 1975. Synergetics: explorations in the geometry of thinking. New York: Macmillan. Also available in http://www.rwgrayprojects.com/synergetics/synergetics.html
Burrows, J., 1989. Catalogue Introduction, In The New York Academy of Sciences (ed.), Kenneth Snelson Exhibition: The Nature of Structure. New York (USA), January - April 1989.
Chandana, P., Hod, L. & Valero Cuevas F. Evolutionary Form-Finding of Tensegrity Structures. Mechanical and Aerospace Engineering Cornell University
Josep, M., Mirats T. & Sergi H.J. 1991. Tensegrity frameworks: Dynamic analysis review and open problems
Motro R., 2002. Tensegrity: The State of the Art, In Space Structures 5, 97-106, London: Thomas Telford.
Motro, R., 2003. Tensegrity: structural systems for the future. London: Kogan Page Science
Parsons, J. & Marcer, N., 2005. Osteopathy. Models for Diagnosis, Treatment and Practice. Oxford: Elsevier
Tristan d’Estrée Sterk, Shape control in responsive architectural structures- current reasons & challenges. The School Of Interactive Arts & Technology, Simon Fraser University, Canada
Tristan d’Estrée Sterk, Using Actuated Tensegrity Strucutres to produce a responsive architecture. The school of the Art Institute of Chicago, USA
Sushant V., Pradeep D., 2011-2013. Adaptive Skins. AA_Em.Tech. http://adaptiveskins.com/
Wind Movement and Computational Fluid Dynamics
Blocken, B. & Carmeliet, J., 2004, Pedestrian Wind Environment around Buildings: Literature Review and Practical Examples. Journal of Thermal Envelope and Building Science, 28(2): 107-159.
Blocken, B., Carmeliet, J. & Stathopoulos, T., 2007. CFD Evaluation of wind speed conditions in passages between parallel buildings- effect of wall- function roughness modifications for the atmospheric boundary layer flow. Journa of wind engineering and industrial aerodynamics, 95 (9-11): 941-962
Blocken B, Janssen WD, van Hooff T. 2012. CFD simulation for pedestrian wind comfort and wind safety in urban areas: General decision framework and case study for the Eindhoven University campus. Environmental Modelling & Software 30: 15-34.
Bottema, M., 2000. A method for optimization of wind discomfort criteria. Building and Environment, 35(1): 1-18.
Bottema, M., 1993. Wind climate and urban geometry. Ph.D. thesis, Eindhoven University of Technology
Capeluto, I. G., Yezioro, A. & Shaviv, E. 2003. Climatic aspects in urban design: a case study, In Building ad Environment, 38(6): 827-835
Chronis, A., Turner, A. & Tsigkari, M. 2011. Generative Fluid Dynamics: Integration of Fast Fluid Dynamics and Genetic Algorithms for wind loading optimization of a free form surface. Proceedings of the Symposium on Simulation for Architecture and Urban Design, 2011, Boston, USA, 79-86.
Karagkouni, C. 2012. Façade’s apertures optimization. Integrating cross ventilation in Fluid Dynamics analysis in early design stages.
Chung, D. H. J. & L. C. Malone Lee (2010), ‘Computational Fluid Dynamics for Urban Design’, In Proceedings of the 15th International Conference on Computer Aided Architectural Design Research in Asia CAADRIA, April 2010, Hong Kong, China, 357–366.
Foster, N. & Metaxas, D. 1996. Realistic animation of liquids. Graphical models and image processing, 58(5): 471-483
Givoni B et al., 2003. Outdoor comfort research issues, Energy and Buildings, vol. 35, pp. 77-86.
Oke, T.R., 1987. Boundary Layer Climates, Second Edition. Routledge
Lawson, T.V & Penwarden, A.D. 1975. The effects of wind on people in vicinity of buildings. Proceedings of the Fourth International Conference on Wind Effects on Buildings and Structures (London, England), Cambridge University Press, Cambridge, UK, 605-622
Murakami, S., Uehara, K. & Deguchi, K. 1979. Wind effect on pedestrians: new criterisbased on outdoor observation of over 2000 persons, Wind Engineering. In: J.E Cermak (ed.), Wind Engineering, 277-288
Neema, S. 2011. Pedestrian wind comfort criteria. Incorporation of Agent Based model with Fast fluid dynamics to study pedestrian wind comfort using pedestrian behavior.
Reiter, S., 2010. Assessing wind comfort in urban planning. Environment and Planning B: Planning and Design, 857-873
Stam, J. 1999. Stable fluids. Proceedings of the 26th annual conference on computer graphics and interactive techniques, August 1999, Los Angeles, USA, 121-128
Stam, J. 2003. Real time fluid dynamics for games. Proceedings of the Game Developer Conference
Zuo, W. & Chen, Q. 2007. Validation of fast fuid dynamics for room airflow. Proceedings of the 10th International IBPSA Conference – Building simulation, Beijing, China
Windbreak
Caborn, J.M., 1957. Shelterbelts and microclimate. Edinburgh University, Bulletin, 29, Forestry commission, 136 p.
DeWalle, D.R., Heisler, G.M. 1983. Windbreak effects on air infiltration and space heating in a mobile home. Energy and Buildings. 5: 279-288.
Heisler, G.M., Dewalle, D.R., 1988. Effects of windbreak structure on wind flow. Agric. Eco-systems Environ., 22/23: 41-69
Johnson, S.R, 1997. Farmstead Windbreaks: Planning. Iowa State University.
Katarzyna K., The influence of windscreen on wind flow, (2007), CESB 07 Prague Conference, Session T3B: Internal Environment
Pescaru, R.A., Akileh, H.A.A. & Radu A., 2011. Laboratory measurements of wind velocity field behind windbreak screens, Gheorghe Asachi Technical University of Iasi, Faculty of Civil Engineering and Building Services
Plate, E.J., 1971. The aerodynamics of shelterbelts. Agric. Meteorol. 8, 203.
Vigiak O., Sterk G., Warren A, Hagen L. G., (2003), Spatial modeling of wind speed around windbreaks, available at www.elsevier.com/locate/catena
Stredova H., Podhrazska J., Litschmann T., Streda T., Roznovsky J., (2012), Aerodynamic parameters of windbreak based on its optical porosity, Contributions to Geophysics and Geodesy, Vol. 42/3, 213–22
Wang, H. & Takle, E.S. 1995. A numerical simulation of boundary layer flows near shelter- belts. Boundary-Layer Meteorol, 75: 141–173
Wang, H. & Takle, E.S. 1996. On three-dimensionality of shelterbelt structure and its influences on shelter effects. Boundary-Layer Meteorol ,79: 83–105
Wei L., Wang F. & Bell S., (2003), Windbreak sheltering effects on outdoor open spaces, Eighth International IBPSA Conference
Pedestrian wind comfort criteria
Ghosh, E., Mittal A.K. 2012. A review on pedestrian wind comfort around tall buildings. VI National Conference on Wind Engineering p.491-506
Lawson,T.V.andPenwarden,A.D.(1975).The effects of wind on people in the vicinity of buildings, Proceedings 4th International Conference on Wind Effects on Buildings and Structures, Heathrow, Cambridge University Press, pp. 605-622.
Blocken B, Janssen WD, van Hooff T. 2012. CFD simulation for pedestrian wind comfort and wind safety in urban areas: General decision framework and case study for the Eindhoven University campus. Environmental Modelling & Software 30: 15-34