Description:
Fundamentals for the course
This course is offered to all students with no previous knowledge of design projection
and means of graphic expression, who want to learn about tropical design.
General objective
Learn about architecture in the tropics, and develop the skill to analyze a particular
situation and be able to offer adequate design solutions that will guarantee a good
quality environment.
Instructive objective
Exercise the analysis capacity in order to draw conclusions and create design solutions
that will respond to specific conditions such as climate. To broaden the experience of
learning and challenge the creative process through exposure, investigation,
observation, experimentation, group analysis and general discussions.
Specific Objectives:
-To understand the need for adequate climatic design.
-To enjoy the form and shape of architecture as a response to climate.
-To study the interesting diversity that we find in the world due to the fact that
every place, as each person, presents different characteristics and destinies.
- Find the balance between globalization and local identity.
- To learn from the richest treasure of the poor: their ingenuity. Restricted
resources, knowledge of land and climate as well as a rural tradition where
domestic construction is passed on from one generation to another, resulted in
vernacular architecture that has a lot of useful application and meaning.
-Familiarize the student with the various contemporary climate-related design
currents around the world.
Tropical Architecture: Themes and Contents
I. Tropical Climate
A. Climatic Zones
B. The geographic belt between the Tropic of Cancer and the Tropic of
Capricorn
1. Diversity of People
2. Similarities in conditions
C. Vernacular response to climate
D. Design with climate
II. Climatic Conditions
A. Climatic Elements
B. Climatic Factors
C. Classification of Tropical and warm climates
D. Local Climate
E. Bioclimatic Design
III. Concept of Comfort zone
A. Comfort Factors
B. How to meet the comfort zone
C. Design criteria to improve local conditions
1. Materials and their properties
2. Thermal design and control
3. Ventilation improvement
4. Natural and artificial lighting
IV. Design with Climate
A. Site Analysis and Local Climate
B. Topography and Vegetation
C. Orientation and Shape
D. Technology
V. Environmental Design
A. Landscape Architecture
B. Vernacular Architecture
C. Energy Saving Design
D. Earth-sheltered architecture
VI. Architecture for Tropical climates
A. Tropical Dry Climate
1. Climatic characteristics
2. Design recommendations and examples
B. Tropical Humid Climate
1. Climatic conditions
2. Design approach and examples
C. Equatorial Climate
1. Climatic characteristics
2. Design criteria, examples
D. Tropical Climate of Altitude
1. Climatic conditions
2. Adequate design and examples
E. Desert Climate
1. Climatic characteristics
2. Design proposals, examples
CRONOGRAM and CONTENTS
Week 1
Class 1:
- Global climatic factors: Earth rotation, axis inclination, thermal equilibrium of the
globe, winds.
- Classification of climatic zones. Classification of tropical and warm climates.
Class 2:
- Geographic belt between the Tropic of Cancer and the Tropic of Capricorn.
- The land: geography, topographical influence, forestry, presence of water.
- The climatic conditions: general and local climates, differences and similarities.
- The people: social and racial background, cultural behavior, tradition and identity.
Class 3:
- Climatic conditions. Elements of Climate: Temperature, relative humidity,
precipitation, wind speed and direction, sky conditions: presence of clouds and
solar radiation.
- Climatic factors and how they affect design.
Class 4:
- Design with climate. How to read and produce charts. The use of various design
tools.
- Charts assignment.
Week 2
Class 5: Bioclimatic diagram. Bioclimatic design. Checking of charts.
Class 6:
- Concept of Comfort Zone. Comfort factors. Heat production and loss in the
human body.
- Thermal factors, heat-fatigue index and long exposure. Air movement.
Temperature effectiveness and regulators. How to meet the comfort zone.
Comfort scale and design. Class exercise: comfort zone chart.
Class 7:
- Design criteria to improve local climatic conditions. Shape and orientation of group and
individual buildings. Class exercises on specific design solutions.
Class 8
- Microclimate. Thermal design and control. Heat exchange in buildings. Ventilation
improvement. Mechanic and structural controls. Special conditions. Urban climate.
Week 3
Class 9:
- Natural and artificial lighting. Nature of light. Daylight and climate. Shade.
Munsell principle.
- Acoustics. Sound principles. Noise control in the tropics.
Class 10:
- Application of climatic analysis. Site analysis and microclimate. Topography and
vegetation.
- Underground water. Building orientation and shape. Views.
Class 11: Class exercises: general use of charts and applied analysis.
Class 12: Theory exam
Week 4
Class 13:
- Environmental Design. Landscape architecture. Learning from vernacular
experience.
- Regionalist approach to design. Contemporary technology for climate control.
Low budget construction in the tropics. Examples of “gardens in the air” in highrise
buildings.
- Ecological architecture. Relationship between Nature and built form. Out-doors
spaces.
Class 14:
- Energy saving. Low-energy design. Solar energy. Hot water. Principles of
thermal design.
- Passive solar energy housing. Eolic energy, other sources and options. Earthsheltered
architecture and the underground space. Architecture on trees.
Design with water.
Class 15:
- Architecture for tropical and warm climates. Contemporary Architecture in the
tropics and Desert climate. Subtropical regions. Examples of climatic design in
various tropical countries.
- Tropical climate of altitude.
Class 16: Field trip to a volcano. On-site analysis of tropical mountain climate.
Observation of gradual change in vegetation and climatic conditions along the route.
Design tips.
Week 5
Class 17:
- Equatorial climate. Compound climates. Mild or moderate humid climate.
Insular climates.
- Revision of first design or theoretical project.
Class 18:
- Tropical dry climate. Climatic characteristics and physiological needs.
Traditional protection.
- Design recommendations and examples. Revision of projects and theoretical
investigations.
Class 19:
- Tropical humid climate. Climatic conditions and analysis. External and internal
spaces.
- Design treatment of construction elements. Exercise in class.
Class 20:
- Field trip to the hot-humid tropical area of the Caribbean. Climate analysis
through observation.
- Study of vernacular influence and local architecture as response to climatic
conditions.
- Conclusions. Final results.
METHODOLOGY
Theory presented with plenty of visual images and examples.
Practice based on active participation of students in class discussions and various
exercises.
Individual and group presentation of theoretical analysis or a short design project.
Two field trips: volcano site and Caribbean beach site.
EVALUATION SYSTEM
Class assistance, participation, individual and group class work…………………... 25%
Field trips………………………………………………………………………………….. 10%
Theory exam…………………………………………………………………………….... 10%
Design assignments:
Design project #1: mountain restaurant or theoretical
proposal (tropical climate of altitude) 15%
Design project #2: sea-front house or theoretical proposal
(tropical dry climate) 15%
Design project #3: small beach hotel or theoretical proposal
(tropical humid climate) 25%
BIBLIOGRAPHY
Aronin, J. E., Climate and Achitecture New York: Reinhold, 1953
Barreneche, R. A. Tropical Modern Thames and Hudson, London 2003
Cain, A., Asfar, F., y Norton, J. Indigenous Building and the third world,
Architectural Design Vol 45, #4 April, 1975 Pag. 207-224
Cornoldi, A. Hábitat y energía Tecnología y Arquitectura, Editorial Gustavo Gili, S.A.
Bacelona 1982
Centro de Espacio Subterráneo de la Universidad de Minnesota. Tierra y Cobijo
Editorial Gustavo Gili, Barcelona, 1980
Danz, E., Architecture and the Sun: an international survey of sun protection
methods, London: Thames and Hudson, 1967.
Design of Low Cost Housing and Community Facilities, vol. 1: Climate and house
design. New York: United Nations, 1971
Faihurst, C., y Bligh, T., Earth Sheltered Housing Design. Minneapolis, Minn: The
Underground Space Center, University of Minnesota, 1978.
Faithy, H., Architecture for the poor: An Experiment in Rural Egypt. Chicago:
University of Chicago Press, 1973
Fitch, J. M., y Branch, D.P. Primitive Architecture and Climate. Scientific American,
vol 203, #6,dic.1960
Fry, M. and Drew, J., Tropical Architecture in the Dry and Humid Zones. Londres:
Bstford, 1964
Gardi, R. Indigeneous African Architecture. New York: Van Nostand Reinhold, 1973
Giovoni, B. Ma, Climate and Architecture, 2nd edition. Barkingg, Essex: Applied
Science, 1976
Koenisberger, O. H., Manual of Tropical Housing and Building. Part 1: Climatic
Design.
Lee, K., Encyclopedia of Energy-efficient Building Design. Boston: Environmental
Design and Research Center, 1977
Lippsmeier, G., Building en the Tropics, Munich: Callwey, 1969
Mather, J.R., Climatology: Fundamentals and Applications. New York: McGraw-Hill,
1974
MacDonald, K. y Segura, C.H. Arquitectura Climática. Habitar: Revista del Colegio de
Arquitectos de Costa Rica. #20, Agosto 1986
MacDonald, K. Y Segura, C.H. Arquitectura y Clima. Acta Académica: Revista Bianual
Universidad Autónoma de Centro América. Febrero 1987
MacDonald, K. Casa Campestre: ¿Cómo enfrentar el Clima? Estilos y Casas:
Especial de Casas de Playa y Campo año 4 #6
Olyay, V., and Olgyay, A., Solar Control and Shading Devices. Princeton, NJ:
Princeton University Press, 1957
Oliver, J. E., Climate and Man’s Environment. New York: Wiley, 1973
Oliver, P. editor, Shelter in Africa. London: Narie and Jenkins, 1971
Pond, A. W., The Desert World. New York: Wiley, 1973
Rapaport, A., House form and Culture, Engelwood Cliffs, NJ: Prentice-Hall, 1969
Rudofsky, B., Architecture Without Architects. New York: The Museum of Modern
Art, 1965
Van Straaten, J. F., Thermal Performance of Buildings. Amsterdam: Elsevier, 1967
Wright, D., Natural Solar Architecture: a passive primer. Florencia, KY: Van Nostand
Reinhold, 1978
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