Athienitis, A. K., Bambara, J., O'Neill, B. & Faille, J., 2010. A prototype photovoltaic/thermal system integrated with transpired collector. Solar Energy, 85(1), pp. 139-153.

Augustus Leon, M. & Kumar, S., 2007. Mathematical modeling and thermal performance analysis of unglazed transpired solar collectors. Solar Energy, 81(1), pp. 62-75.

Bambara, J., 2012. Experimental Study of a Façade-integrated Photovoltaic/thermal System, M.A.Sc thesis: Concordia University, Montreal, Canada.

Blocken, B., Defraeye, T., Derome, D. & Carmeliet, J., 2009. High-resolution CFD simulations for forced convection heat transfer coefficients at the facade of a low-rise building. 
Building and Environment, 44(12), pp. 2396-2412.

CIBS, 1979. Chartered Institute of Building Services Guide Book A, Section A3. London: Cited in : Sharples, S., 1984. Full-scale measurements of convective energy losses from exterior building surfaces. Building and Environment, 19(1), pp. 31-39.

CIBSE, 2006. Chartered Institute of Building Services Engineers Guide Book A, Section A3. 7 ed. London: CIBSE.

Conserval Engineering Inc., n.d. Company Info. [Online] 
Available at: http://solarwall.com
[Accessed 8 May 2012].

Cordeau, S. & Barrington, S., 2011. Performance of unglazed solar ventilation air pre-heaters for broiler barns. Solar Energy, 85(7), pp. 1418-1429.

Davenport, A. G., 1967. The dependence of wind loads on meteorological parameters. Ottawa, Proceedings of the International Conference on Wind Effects on Buildings and Structures: University of Toronto Press, pp. 19-82.

Defraeye, T., Blocken, B. & Carmeliet, J., 2010. CFD analysis of convective heat transfer at the surfaces of a cube immersed in a turbulent boundary layer. International Journal of Heat and Mass Transfer, 53(1-3), pp. 297-308.

Defraeye, T., Blocken, B. & Carmeliet, J., 2011. Convective heat transfer coefficients for exterior building surfaces: Existing correlations and CFD modelling. Energy Conservation and Management, 52(1), pp. 512-522.

Defraeye, T. & Carmeliet, J., 2010. A methodology to assess the influence of local wind conditions and building orientation on the convective heat transfer at building surfaces. Environmental Modelling & Software, 25(12), pp. 1813-1824.

Delisle, V., 2008. Analytical and experimental study of a PV/thermal transpired solar collector, PhD Thesis: University of Waterloo, Waterloo, Ontario.

Djunaedy, E., Hensen, J. L. M. & Loomans, M. G. L. C., 2004. Comparing internal and external run-time coupling of CFD and building energy simulation software. Coimbra, Portugal, Proceedings of the 9th ROOMVENT International Conference on Air Distribution in Rooms, 5-8 September 2004, University of Coimbra, pp. 393-396.

Dymond, C. & Kutscher, C., 1997. Development of a flow distribution and design model for transpired solar collectors. Solar Energy, 60(5), pp. 291-300.

Environment Canada, 2012. National Climate Data and Information Archive. [Online] 
Available at: http://climate.weatheroffice.gc.ca/climateData/canada_e.html
[Accessed October 2012].

Fleck, B. A., Meier, R. M. & Matovic, M. D., 2002. A field study of the wind effects on the performance of an unglazed transpired solar collector. Solar Energy, 73(3), pp. 209-216.

Gawlik, K. M. & Kutscher, C. F., 2002. Wind heat loss from corrugated, transpired solar collectors. Journal of Solar Energy Engineering, 124(3), pp. 256-261.

Gunnewiek, L. H., Hollands, K. G. T. & Brundrett, E., 2002. Effect of wind on flow distribution in unglazed transpired-plate collectors. Solar Energy, 72(4), pp. 317-325.

Heinrich, M., 2007. Transpired Solar Collectors - Results of a Field Trial, Juddgeford, New Zealand: BRANZ Ltd.

Holmes, J. D., 2007. Wind loading of structures. In: New York, USA: Taylor & Francis, pp. 55-60.

Ito, N., Kimura, K. & Oka, J., 1972. A field experiment study on the convective heat transfer coefficient on exterior surface of a building. ASHRAE Transactions, 79(1), pp. 184-191.

Jürges , W., 1924. Der Wärmeübergang an einer ebenen Wand. Beihefte zum Gesundheits-Ingenieur, 1(19), pp. 1227-1249. Cited in : Sharples, S., 1984. Full-scale measurements of convective energy losses from exterior building surfaces. Building and Environment, 19(1), pp. 31-39.

Kutscher, C. F., 1992. An investigation of heat transfer for air flow through low porosity perforated plates, PhD Thesis: University of Colorado, Colorado, USA.

Kutscher, C. F., 1994. Heat exchange effectiveness and pressure drop for air flow through perforated plates with and without crosswind. Journal of Heat Transfer, 116(2), pp. 391-399.

Kutscher, C. F., Christensen, C. B. & Barker, G. M., 1993. Unglazed transpired solar collectors: heat loss theory. Journal of Solar Energy Engineering, 115(3), pp. 182-188.

Liu, Y. & Harris, D. J., 2007. Full-scale measurements of convective coefficient on external surface of a low-rise building in sheltered conditions. Building and Environment, 42(7), pp. 2718-2736.

Loveday, D. L. & Taki, A. H., 1996. Convective heat transfer coefficients at a plane surface on a full-scale building facade. International Journal of Heat and Mass Transfer, 39(8), pp. 1729-1742.

Mirsadeghi, M., Blocken, B. & Hensen, J. L. M., 2008. Validation of external BES-CFD coupling by inter-model comparison. Kyoto, Japan. In Murakami, S (Ed.), 29th AIVC Conference, 14-16 October 2008, pp. 193-198.

Moore, R., 2005. Solar air heating and cooling, Camberwell, Australia: ISS Institute Inc..

Morse, E. S., 1881. Warming and ventilating apartments by the sun's rays. Massachusetts, U.S.A, Patent No. 246626.

NRCan, 2010. Solar Thermal. [Online] 
Available at: http://canmetenergy.nrcan.gc.ca
[Accessed 15 November 2012].

NREL, 1998. Transpired Collectors (Solar Preheaters for Outdoor Ventilation Air), Golden, Colorado: U.S. Department of Energy.

O'Neill, B., Chen, Y. & Koziol, A., 2011. Description of the JMSB BIPV/T solar system, monitoring and database, Solar Buildings Research Network: Concordia University, Montreal.

REN21, 2012. Renewables 2012 Global Status Report, Paris: REN21 Secretariate.

R. M. Young Company, n.d. Wind Monitor. [Online] 
Available at: http://www.youngusa.com/products/7/8.html
[Accessed 20 December 2012].

Shao, J. et al., 2010. Field measurement of the convective heat transfer coefficient on vertical external building surface using naphthalene sublimation method. Journal of Building Physics, 33(4), pp. 307-326.

Sharples, S., 1984. Full-scale measurements of convective energy losses from exterior building surfaces. Building and Environment, 19(1), pp. 31-39.

Simiu, E., 1981. Modern developments in wind engineering : Part 1. Engineering Structures, 3(4), pp. 233-241.

Stathopoulos, T., 1984. Design and fabrication of a wind tunnel for building aerodynamics. Journal of Wind Engineering and Industrial Aerodynamics, 16(2-3), pp. 361-376.

Stathopoulos, T., 2007. In: T. Stathopoulos & C. C. Baniotopoulos, eds. Wind effects on buildings and design of wind-sensitive structures. International Center for Mechanical Sciences, Udine, Italy: Springer Wien New York, pp. 1-15.

Test, F. L., Lessmann, R. C. & Johary, A., 1981. Heat transfer during wind flow over rectangular bodies in the natural environment. Journal of Heat Transfer, 103(2), pp. 262-267.

Van Decker, G. W. E., Hollands, K. G. T. & Brunger, A. P., 2001. Heat-exchange relations for unglazed transpired solar collectors with circular holes on a square or triangular pitch. Solar Energy, 71(1), pp. 33-45.

Vasan, N. & Stathopoulos, T., 2012. Wind Tunnel Assessment of the Wind Velocity Distribution on. Halifax, Canada, Proceedings of eSim 2012: The Canadian Conference on Building Simulation, 1-4 May, pp. 61-74.