Upgrade to Pro — share decks privately, control downloads, hide ads and more …

KTH Urban Studio - Sustainable Urban Design Int...

Avatar for John Manoochehri John Manoochehri
January 21, 2014
210

KTH Urban Studio - Sustainable Urban Design Intro I

Avatar for John Manoochehri

John Manoochehri

January 21, 2014
Tweet

Transcript

  1. J M

  2. E N V I R O N M E N

    T S U S T A I N A B I L I T Y J M
  3. 1234 E N V I R O N M E

    N T S U S T A I N A B I L I T Y J M
  4. 1234 PRINCIPLES E N V I R O N M

    E N T S U S T A I N A B I L I T Y J M
  5. 1234 PRINCIPLES BUILT DESIGN E N V I R O

    N M E N T S U S T A I N A B I L I T Y J M
  6. 1234 PRINCIPLES FRAMEWORK BUILT DESIGN E N V I R

    O N M E N T S U S T A I N A B I L I T Y J M
  7. 1234 PRINCIPLES FRAMEWORK BUILT DESIGN E N V I R

    O N M E N T REVIEW / SUMMARY S U S T A I N A B I L I T Y J M
  8. JM

  9. JM

  10. OXFORD > UN SCOE CO-OP 2001 RV CONSULT RESEARCH 2003

    SCIENCE P&C POLICY STRATEGY RV DESIGN 2006 RTA (KTH, SURREY) GENERAL A + UD CONSULT DESIGN COLLABORATION LIFESTYLE DESIGN UPD SDUS WRITING JM
  11. E N V I R O N M E N

    T T O O L S
  12. E N V I R O N M E N

    T T O O L S ACTION?
  13. Pre-Enlightenment Ancients Lao Tzu, Plato, Asoka: c.500 BCE Industrial Revolution

    Romantics Muir, Ruskin, Thoreau: late 19th C Early Scientists Pinchot, Leopold, Geddes: 19th-20th 20th C Disasters Minamata Bay, Torrey Canyon, Chernobyl: 60s-80s Scientists Carson, Meadows, Commoner, Ehrlich: 60s, 70s Green Ideologues Kelly, Bahro, Porritt: 80s HISTORY
  14. Pre-Enlightenment Ancients Lao Tzu, Plato, Asoka: c.500 BCE Industrial Revolution

    Romantics Muir, Ruskin, Thoreau: late 19th C Early Scientists Pinchot, Leopold, Geddes: 19th-20th 20th C Disasters Minamata Bay, Torrey Canyon, Chernobyl: 60s-80s Scientists Carson, Meadows, Commoner, Ehrlich: 60s, 70s Green Ideologues Kelly, Bahro, Porritt: 80s HISTORY
  15. Pre-Enlightenment Ancients Lao Tzu, Plato, Asoka: c.500 BCE Industrial Revolution

    Romantics Muir, Ruskin, Thoreau: late 19th C Early Scientists Pinchot, Leopold, Geddes: 19th-20th 20th C Disasters Minamata Bay, Torrey Canyon, Chernobyl: 60s-80s Scientists Carson, Meadows, Commoner, Ehrlich: 60s, 70s Green Ideologues Kelly, Bahro, Porritt: 80s HISTORY
  16. Pre-Enlightenment Ancients Lao Tzu, Plato, Asoka: c.500 BCE Industrial Revolution

    Romantics Muir, Ruskin, Thoreau: late 19th C Early Scientists Pinchot, Leopold, Geddes: 19th-20th 20th C Disasters Minamata Bay, Torrey Canyon, Chernobyl: 60s-80s Scientists Carson, Meadows, Commoner, Ehrlich: 60s, 70s Green Ideologues Kelly, Bahro, Porritt: 80s HISTORY
  17. Pre-Enlightenment Ancients Lao Tzu, Plato, Asoka: c.500 BCE Industrial Revolution

    Romantics Muir, Ruskin, Thoreau: late 19th C Early Scientists Pinchot, Leopold, Geddes: 19th-20th 20th C Disasters Minamata Bay, Torrey Canyon, Chernobyl: 60s-80s Scientists Carson, Meadows, Commoner, Ehrlich: 60s, 70s Green Ideologues Kelly, Bahro, Porritt: 80s HISTORY
  18. Pre-Enlightenment Ancients Lao Tzu, Plato, Asoka: c.500 BCE Industrial Revolution

    Romantics Muir, Ruskin, Thoreau: late 19th C Early Scientists Pinchot, Leopold, Geddes: 19th-20th 20th C Disasters Minamata Bay, Torrey Canyon, Chernobyl: 60s-80s Scientists Carson, Meadows, Commoner, Ehrlich: 60s, 70s Green Ideologues Kelly, Bahro, Porritt: 80s HISTORY
  19. Pre-Enlightenment Ancients Lao Tzu, Plato, Asoka: c.500 BCE Industrial Revolution

    Romantics Muir, Ruskin, Thoreau: late 19th C Early Scientists Pinchot, Leopold, Geddes: 19th-20th 20th C Disasters Minamata Bay, Torrey Canyon, Chernobyl: 60s-80s Scientists Carson, Meadows, Commoner, Ehrlich: 60s, 70s Green Ideologues Kelly, Bahro, Porritt: 80s HISTORY
  20. Lack of Harmony Separation from Nature Pollution Humankind spoiling its

    own living environment Wise-use Lack of strategy in exploiting resources Industrial Ugliness Machinery harming Nature, humankind brutalising/being brutalised Enlightenment Inverted Separation from natural systems, lack of immediate feedbacks, lack of contextual limits Hypertechnology, Systems Complexity Super-pollution, Mega-catastrophe Politico-economic ‘anthropocentrism’ (c.f. ‘geocentrism’) Defective theories of economic development IDEAS
  21. 19th C National parks (Yellowstone, 1872), game reserves, scientific conservation

    Post-war Some intl interest (UNSCCUR ‘49) 50s-70s Anti-pollution legislation, toxics legislation, government ministries 80s Green parties, consumer action 90s Rio (UNCED ‘92) decade, international meetings POLICY
  22. 19th C National parks (Yellowstone, 1872), game reserves, scientific conservation

    Post-war Some intl interest (UNSCCUR ‘49) 50s-70s Anti-pollution legislation, toxics legislation, government ministries 80s Green parties, consumer action 90s Rio (UNCED ‘92) decade, international meetings POLICY
  23. 19th C National parks (Yellowstone, 1872), game reserves, scientific conservation

    Post-war Some intl interest (UNSCCUR ‘49) 50s-70s Anti-pollution legislation, toxics legislation, government ministries 80s Green parties, consumer action 90s Rio (UNCED ‘92) decade, international meetings POLICY
  24. 19th C National parks (Yellowstone, 1872), game reserves, scientific conservation

    Post-war Some intl interest (UNSCCUR ‘49) 50s-70s Anti-pollution legislation, toxics legislation, government ministries 80s Green parties, consumer action 90s Rio (UNCED ‘92) decade, international meetings POLICY
  25. Yield Resources/Media Forests (productivity, area) Fisheries (productivity, species) Minerals/Fossils (availability)

    Rangelands (cattle health/ productivity, feed sustainability, toxification) Pastures (soil depth, soil fertility, productivity, toxification): Land (urbanisation, toxification) Air (pollution) Water (freshwater stocks, pollution) Non-yield Resources Ecosystem resilience Carbon/Nitrogen/Water Cycles Climate stability Drainage Nature Species Ecosystems Biomes Aggregate Impact Eco-Footprint Environmental Space Ecosystem Health CO2e Concentration SCIENCE
  26. Yield Resources/Media Forests (productivity, area) Fisheries (productivity, species) Minerals/Fossils (availability)

    Rangelands (cattle health/ productivity, feed sustainability, toxification) Pastures (soil depth, soil fertility, productivity, toxification): Land (urbanisation, toxification) Air (pollution) Water (freshwater stocks, pollution) Non-yield Resources Ecosystem resilience Carbon/Nitrogen/Water Cycles Climate stability Drainage Nature Species Ecosystems Biomes Aggregate Impact Eco-Footprint Environmental Space Ecosystem Health CO2e Concentration SCIENCE
  27. Yield Resources/Media Forests (productivity, area) Fisheries (productivity, species) Minerals/Fossils (availability)

    Rangelands (cattle health/ productivity, feed sustainability, toxification) Pastures (soil depth, soil fertility, productivity, toxification): Land (urbanisation, toxification) Air (pollution) Water (freshwater stocks, pollution) Non-yield Resources Ecosystem resilience Carbon/Nitrogen/Water Cycles Climate stability Drainage Nature Species Ecosystems Biomes Aggregate Impact Eco-Footprint Environmental Space Ecosystem Health CO2e Concentration SCIENCE
  28. Yield Resources/Media Forests (productivity, area) Fisheries (productivity, species) Minerals/Fossils (availability)

    Rangelands (cattle health/ productivity, feed sustainability, toxification) Pastures (soil depth, soil fertility, productivity, toxification): Land (urbanisation, toxification) Air (pollution) Water (freshwater stocks, pollution) Non-yield Resources Ecosystem resilience Carbon/Nitrogen/Water Cycles Climate stability Drainage Nature Species Ecosystems Biomes Aggregate Impact Eco-Footprint Environmental Space Ecosystem Health CO2e Concentration SCIENCE
  29. Yield Resources/Media Forests (productivity, area) Fisheries (productivity, species) Minerals/Fossils (availability)

    Rangelands (cattle health/ productivity, feed sustainability, toxification) Pastures (soil depth, soil fertility, productivity, toxification): Land (urbanisation, toxification) Air (pollution) Water (freshwater stocks, pollution) Non-yield Resources Ecosystem resilience Carbon/Nitrogen/Water Cycles Climate stability Drainage Nature Species Ecosystems Biomes Aggregate Impact Eco-Footprint Environmental Space Ecosystem Health CO2e Concentration SCIENCE
  30. Yield Resources/Media Forests (productivity, area) Fisheries (productivity, species) Minerals/Fossils (availability)

    Rangelands (cattle health/ productivity, feed sustainability, toxification) Pastures (soil depth, soil fertility, productivity, toxification): Land (urbanisation, toxification) Air (pollution) Water (freshwater stocks, pollution) Non-yield Resources Ecosystem resilience Carbon/Nitrogen/Water Cycles Climate stability Drainage Nature Species Ecosystems Biomes Aggregate Impact Eco-Footprint Environmental Space Ecosystem Health CO2e Concentration SCIENCE
  31. Mandates Policy frameworks (Agenda 21), Changed mandates (GATT) Institutional development

    Government Agencies and Ministries Policies Regulatory: Preservation, Anti-pollution Fiscal: Resource-use taxes, Behaviour taxes, Funding for research Informational: consumer education/information Concepts Sustainable development
  32. Mandates Policy frameworks (Agenda 21), Changed mandates (GATT) Institutional development

    Government Agencies and Ministries Policies Regulatory: Preservation, Anti-pollution Fiscal: Resource-use taxes, Behaviour taxes, Funding for research Informational: consumer education/information Concepts Sustainable development POLICY ACTION
  33. Clean by Technology Biotech, Bioremeditation, Nuclear, Pollution Capture, Mega-engineering Efficiency

    by Design Full-system design, Advanced composites, Intelligent Controls, Passive Systems Better-organised by Systems Public systems, Product-Service-Systems, Changed business models Sufficiency by Simplicity Upshift, Locality, Quality
  34. Clean by Technology Biotech, Bioremeditation, Nuclear, Pollution Capture, Mega-engineering Efficiency

    by Design Full-system design, Advanced composites, Intelligent Controls, Passive Systems Better-organised by Systems Public systems, Product-Service-Systems, Changed business models Sufficiency by Simplicity Upshift, Locality, Quality VISIONS
  35. Clean by Technology Biotech, Bioremeditation, Nuclear, Pollution Capture, Mega-engineering Efficiency

    by Design Full-system design, Advanced composites, Intelligent Controls, Passive Systems Better-organised by Systems Public systems, Product-Service-Systems, Changed business models Sufficiency by Simplicity Upshift, Locality, Quality VISIONS
  36. Clean by Technology Biotech, Bioremeditation, Nuclear, Pollution Capture, Mega-engineering Efficiency

    by Design Full-system design, Advanced composites, Intelligent Controls, Passive Systems Better-organised by Systems Public systems, Product-Service-Systems, Changed business models Sufficiency by Simplicity Upshift, Locality, Quality VISIONS
  37. Clean by Technology Biotech, Bioremeditation, Nuclear, Pollution Capture, Mega-engineering Efficiency

    by Design Full-system design, Advanced composites, Intelligent Controls, Passive Systems Better-organised by Systems Public systems, Product-Service-Systems, Changed business models Sufficiency by Simplicity Upshift, Locality, Quality VISIONS
  38. Clean by Technology Biotech, Bioremeditation, Nuclear, Pollution Capture, Mega-engineering Efficiency

    by Design Full-system design, Advanced composites, Intelligent Controls, Passive Systems Better-organised by Systems Public systems, Product-Service-Systems, Changed business models Sufficiency by Simplicity Upshift, Locality, Quality VISIONS
  39. Sustainable sites (14 points) Construction Activity Pollution Prevention Plan (required)

    Site selection (1 pt) Development density and community connectivity (1 pt) Brownfield redevelopment (1 pt) Alternative transportation availability (3 pts) Public transportation access (1 pt) Bicycle storage and changing rooms (1 pt) Parking capacity and carpooling (1 pt) Reduced site disturbance (2 pt) Protect or restore open space (1 pt) Development footprint Stormwater management (2 pts) Rate and quantity (1 pt) Treatment (1 pt) Reduce heat islands (2 pts) Roof (1 pt) Non-roof (1 pt) Light pollution reduction (1 pt) Water efficiency (5 points) Water efficient landscaping (2 pt) Reduce by 50% (1 pt) No potable use or no irrigation (1 pt) Innovative wastewater technologies (1 pt) Water use reduction (2 pt) Energy and atmosphere (17 points) Fundamental commissioning (required) Minimum (code) energy performance (required) Fundamental Refrigerant Management (required) Optimize energy performance by 14% (new) or 7% (existing) buildings (2 pts, required as of June 26, 2007) Energy optimization (8 pts in addition to the 2 required above) On-site renewable energy (3 pts) Ozone depletion (1 pt) Measurement and verification (1 pt) Green power (1 pt) Materials and resources (13 points) Storage and collection of recyclables (required) Building reuse (3 pts): 75% reuse of building structure and shell excluding windows (1 pt) 100% reuse of building structure and 50% of walls, floors, ceilings (1 pt) Construction waste reuse or recycling (by weight or volume) (2 pts): 50% diversion (1 pt) 75% diversion (1 pt) Reuse of existing materials (by cost) (2 pts) 5% salvaged or refurbished materials (1 pt) 10% salvaged or refurbished materials (1 pt) Recycled content (2 pts) Criteria vary in recent versions of LEED, but depend on value of pre- and post-consumer recycled content (2 pt) Use of local materials (2 pts) Fabrication shop within 500 miles (800 km) of building site and raw materials source within 500 miles (800 km) of building site, 10% (1 pt) or 20% (+1 pt). Rapidly renewable materials (1 pt) Certified Wood (1 pt) Indoor environmental quality (15 points) Minimum indoor air quality (required) Environmental tobacco smoke control (required) Outdoor air delivery monitoring (1 pt) Increased ventilation (1 pt) Construction indoor air quality management (2 pt) Indoor chemical and pollutant source control (1 pt) Controllability of systems (2 pt) Thermal comfort (2 pt) Daylight and views (2 pt) Innovation and design process (5 points) Examples for up to four design points using steel construction include structure as finish, structure as plumbing, lightweight materials, recyclability, and potential for disassembly.
  40. Sustainable sites (14 points) Construction Activity Pollution Prevention Plan (required)

    Site selection (1 pt) Development density and community connectivity (1 pt) Brownfield redevelopment (1 pt) Alternative transportation availability (3 pts) Public transportation access (1 pt) Bicycle storage and changing rooms (1 pt) Parking capacity and carpooling (1 pt) Reduced site disturbance (2 pt) Protect or restore open space (1 pt) Development footprint Stormwater management (2 pts) Rate and quantity (1 pt) Treatment (1 pt) Reduce heat islands (2 pts) Roof (1 pt) Non-roof (1 pt) Light pollution reduction (1 pt) Water efficiency (5 points) Water efficient landscaping (2 pt) Reduce by 50% (1 pt) No potable use or no irrigation (1 pt) Innovative wastewater technologies (1 pt) Water use reduction (2 pt) Energy and atmosphere (17 points) Fundamental commissioning (required) Minimum (code) energy performance (required) Fundamental Refrigerant Management (required) Optimize energy performance by 14% (new) or 7% (existing) buildings (2 pts, required as of June 26, 2007) Energy optimization (8 pts in addition to the 2 required above) On-site renewable energy (3 pts) Ozone depletion (1 pt) Measurement and verification (1 pt) Green power (1 pt) Materials and resources (13 points) Storage and collection of recyclables (required) Building reuse (3 pts): 75% reuse of building structure and shell excluding windows (1 pt) 100% reuse of building structure and 50% of walls, floors, ceilings (1 pt) Construction waste reuse or recycling (by weight or volume) (2 pts): 50% diversion (1 pt) 75% diversion (1 pt) Reuse of existing materials (by cost) (2 pts) 5% salvaged or refurbished materials (1 pt) 10% salvaged or refurbished materials (1 pt) Recycled content (2 pts) Criteria vary in recent versions of LEED, but depend on value of pre- and post-consumer recycled content (2 pt) Use of local materials (2 pts) Fabrication shop within 500 miles (800 km) of building site and raw materials source within 500 miles (800 km) of building site, 10% (1 pt) or 20% (+1 pt). Rapidly renewable materials (1 pt) Certified Wood (1 pt) Indoor environmental quality (15 points) Minimum indoor air quality (required) Environmental tobacco smoke control (required) Outdoor air delivery monitoring (1 pt) Increased ventilation (1 pt) Construction indoor air quality management (2 pt) Indoor chemical and pollutant source control (1 pt) Controllability of systems (2 pt) Thermal comfort (2 pt) Daylight and views (2 pt) Innovation and design process (5 points) Examples for up to four design points using steel construction include structure as finish, structure as plumbing, lightweight materials, recyclability, and potential for disassembly. LEED
  41. 9. EQU inves 10. HEA prom NET LIVING 6 7

    8 9 10 2 3 4 5 s based ples of anet n which ead within e Earth’s One Pl courtes an initia engage specify The init represe
  42. OPL 9. EQU inves 10. HEA prom NET LIVING 6

    7 8 9 10 2 3 4 5 s based ples of anet n which ead within e Earth’s One Pl courtes an initia engage specify The init represe
  43. EVA

  44. CONTEXT We all share the need to recognize ourselves in

    the context in which we live. Kjellgren Kaminsky collects inspiration from the unique history and soul of each new environment. These two ingredients create together with people’s specifi c needs, the context that fi nally is formed into a fi nished building.
  45. CONTEXT We all share the need to recognize ourselves in

    the context in which we live. Kjellgren Kaminsky collects inspiration from the unique history and soul of each new environment. These two ingredients create together with people’s specifi c needs, the context that fi nally is formed into a fi nished building. OTHER / K&K
  46. E N V I R O N M E N

    T T O O L S
  47. E N V I R O N M E N

    T T O O L S ACTION?
  48. 1 2 3 4 P R I N C I

    P L E S B U I L T D E S I G N
  49. 1 2 3 4 P R I N C I

    P L E S F R A M E W O R K B U I L T D E S I G N
  50. BINARY DEBATE TECHNOLOGY OF SUPPLY? FORCING MASS SOCIAL CHANGE? ENVIRONMENTAL

    VS SUSTAINABLE TOTAL MATERIALISATION? CONDITIONED MATERIALISATION? DESIGN VS ENGINEERING DESIGN? CREATIVITY? HUMAN DEVELOPMENT CREATIVITY FREEDOM OBSCURITY? COHERENT STRUCTURE? MASKING OF POLITICS? SOCIAL ISSUES? APPROPRIATE RELATIONSHIP? SERIOUS TREATMENT? COST? FEASIBLE? COST EFFECTIVE? 0 CRITIQUE
  51. FOSSILS MINERALS BIOTA LIFESYSTEMS SUN WATER SOIL LAND SPACE FOOD

    POWER GOODS MOBILITY BUILDINGS INFRASTRUCTURE ACTIVITY VALUE EXPERIENCE WELFARE RESOURCES MEDIA APPLICATIONS FUNCTION 1 MATERIAL CRISIS
  52. A BIOPHYSICAL RESOURCE LIMITS ABSORPTION (pollution, waste) STOCKS (freshwater, oil,

    minerals) SERVICES (climate, nutrient cycling, resilience) INPUTS (solar, tidal) B NATURE VULNERABILITY SPECIES ECOSYSTEMS LANDSCAPES 2 PROBLEM
  53. A SUPPLY POLLUTION REDUCTION STOCK CONSERVATION NATURE PRESERVATION B APPLICATIONS

    BETTER APPLICATION OF RESOURCES C BEHAVIOUR ME/US ETHICS THEM ETHICS 3 SOLUTIONS
  54. A INFORMATION B PRICES C LAWS 4 ENABLERS D QUALITY

    DESIGN, INNOVATION, NARRATIVE, VALUE
  55. N

  56. SUPPLY APPLICATIONS BEHAVIOUR MANAGED DESIGNED INFORMED ! ? ! NO

    MONEY MORE LIMITS ! POLITICS ⊖ ⊗ ⊗
  57. H N p c METABOLISM R E S I L

    I E N C E RECYCLING
  58. H N p c METABOLISM R E S I L

    I E N C E RECYCLING
  59. H N p c METABOLISM SYMBIOSIS R E S I

    L I E N C E RECYCLING
  60. H N p c METABOLISM SYMBIOSIS R E S I

    L I E N C E RECYCLING
  61. H N p c METABOLISM SYMBIOSIS R E S I

    L I E N C E BIOCYCLING RECYCLING
  62. H N p c METABOLISM SYMBIOSIS R E S I

    L I E N C E BIOCYCLING RECYCLING
  63. H N p c METABOLISM SYMBIOSIS R E S I

    L I E N C E BIOCYCLING SERVICE-USE RECYCLING
  64. H N p c METABOLISM SYMBIOSIS R E S I

    L I E N C E BIOCYCLING SERVICE-USE RECYCLING
  65. H N p c METABOLISM SYMBIOSIS R E S I

    L I E N C E SOCIETY LIFESTYLES INFRASTRUCTURE BUILT ENVIRONMENT CITIES BIOCYCLING SERVICE-USE RECYCLING
  66. SUSTAINABILITY SUPPLY APPLICATIONS BEHAVIOUR CONCEPTS MATERIAL CLEAN ABUNDANT CONTROLLED EFFICIENT

    DESIGNED NETWORKED SKILLED MEDIA Soil Space Land Water RESOURCES Fossils Life-systems Minerals Biota Sunlight APPLICATIONS Power Housing Mobility Food Goods Infrastructure MY NEEDS THEIR NEEDS TECHNIQUES Pollution Capture Technolgy Waste Management Recapture Technology Remediation Technology Toxics Reduction Scientific 

Management Source Substitution Park Management Preservation Research Remediation & Restoration Material choices Personal reductions Process 

Efficiency Product 

Efficieny Recycled Materials Recycling Durability Localisation Simultaneous Functionality Sequential Functionality Synchronic Usage Sequential Usage User-adapting Tech User Skills Service Agents Pollution Reduction Stock Conservation Nature Protection Resource 

Efficiency Functional 

Efficiency Use 

Efficiency Welfare 

Efficiency Sufficiency-­Limits Respect-Limits
  67. SUSTAINABILITY SUPPLY APPLICATIONS BEHAVIOUR CONCEPTS MATERIAL CLEAN ABUNDANT CONTROLLED EFFICIENT

    DESIGNED NETWORKED SKILLED MEDIA Soil Space Land Water RESOURCES Fossils Life-systems Minerals Biota Sunlight APPLICATIONS Power Housing Mobility Food Goods Infrastructure MY NEEDS THEIR NEEDS TECHNIQUES Pollution Capture Technolgy Waste Management Recapture Technology Remediation Technology Toxics Reduction Scientific 

Management Source Substitution Park Management Preservation Research Remediation & Restoration Material choices Personal reductions Process 

Efficiency Product 

Efficieny Recycled Materials Recycling Durability Localisation Simultaneous Functionality Sequential Functionality Synchronic Usage Sequential Usage User-adapting Tech User Skills Service Agents Pollution Reduction Stock Conservation Nature Protection Resource 

Efficiency Functional 

Efficiency Use 

Efficiency Welfare 

Efficiency Sufficiency-­Limits Respect-Limits
  68. 1 2 3 4 P R I N C I

    P L E S B U I L T D E S I G N
  69. 1 2 3 4 P R I N C I

    P L E S F R A M E W O R K B U I L T D E S I G N
  70. J M

  71. E N V I R O N M E N

    T S U S T A I N A B I L I T Y J M
  72. 1234 E N V I R O N M E

    N T S U S T A I N A B I L I T Y J M
  73. 1234 PRINCIPLES E N V I R O N M

    E N T S U S T A I N A B I L I T Y J M
  74. 1234 PRINCIPLES BUILT DESIGN E N V I R O

    N M E N T S U S T A I N A B I L I T Y J M
  75. 1234 PRINCIPLES FRAMEWORK BUILT DESIGN E N V I R

    O N M E N T S U S T A I N A B I L I T Y J M
  76. 1234 PRINCIPLES FRAMEWORK BUILT DESIGN E N V I R

    O N M E N T REVIEW / SUMMARY S U S T A I N A B I L I T Y J M
  77. R E C A P / D I S C

    U S S T E C H N I Q U E S
  78. R E C A P / D I S C

    U S S T E C H N I Q U E S M E T H O D S
  79. R E C A P / D I S C

    U S S T E C H N I Q U E S C A S E S M E T H O D S
  80. R E C A P / D I S C

    U S S T E C H N I Q U E S C A S E S M E T H O D S C R I T I Q U E
  81. K E Y C O N C E P T

    S S Y S T E M
  82. K E Y C O N C E P T

    S S Y S T E M D E M O G R A P H I C S
  83. K E Y C O N C E P T

    S S Y S T E M L I F E S T Y L E D E M O G R A P H I C S
  84. K E Y C O N C E P T

    S S Y S T E M L I F E S T Y L E D E M O G R A P H I C S A R C H I T E C T U R E