참고문헌
- Auckland City (1997), "Proposed district plan", published by Auckland City.
- Eaddy, M.J. (1999), "Pedestrian level wind measurement using computer image processing", ME Thesis, University of Auckland, New Zealand.
- Eaddy, M.J. and Flay, R.G.J. (1999), "Automatic pedestrian wind category assignment using a computer image processing system", Proc. of 10th Int. Conf. on Wind Eng., Copenhagen, Denmark, 2, 753-758.
- Flay, R.G.J. (1989), "Wind environment measurements and acceptance criteria developed at the University of Auckland", Proc. of the 10th Australasian Fluid Mech. Conf., Melbourne, Australia.
- Flay, R.G.J. (1991), "Pedestrian-level wind investigations using Cork Grain Erosion Techniques", Department of Mechanical Engineering Report, ME G91-02, The University of Auckland, New Zealand.
- Isyumov, N. and Davenport, A.G. (1976), "The ground level wind environment in built up areas", Proc. of 4th Int. Conf. on Wind Effects on Buildings and Structures, Tokyo, 403-422.
- Livesey, F., Inculet, D., Isyumov, N. and Davenport, A.G., (1989), "A scour technique for the evaluation of pedestrian winds", Proc. of the 6th U.S. Nat. Conf. on Wind Engineering, Houston, U.S.A.
- Mallinson, G.D. (1993), SeeFD User Guide, Department of Mechanical Engineering, The University of Auckland, New Zealand.
- Melbourne, W.H. (1978), "Criteria for environmental wind conditions", J. Industrial Aerodynamics., 3, 241-249. https://doi.org/10.1016/0167-6105(78)90013-2
- Penwarden, A.D. and Wise A.F.E. (1975), "Wind environment around buildings", Building Research Establishment Report, H.M.S.O.
-
Richards, P.J. And Hoxey, R.P. (1993), "Appropriate boundary conditions for computational wind engineering models using the
${\kappa}-{\varepsilon}$ turbulence model", J. Wind Eng. Ind. Aerod., 46 & 47, 145-153. - Richards, P.J. and Mallinson, G.D. (1998), "Computational modelling and flow visualisation of wind flow over Downtown Auckland", 13th Australasian Fluid Mech. Conf., Melbourne, Australia, December 1998.
- Richards, P.J. and Mallinson, G.D. (1999), "Simulation and visualisation of wind around Downtown Auckland", The PHOENICS Journal, 12(2), 224-239.
- Standards New Zealand (1992), "Code of practice for general structural design and design loadings for buildings", NZS 4203.
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