BIG_ABCDEF.pdf

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1. BIG SMALL GIG | JM/RV | 190309 A B C

   D E F

2. BIG SMALL GIG | JM/RV | 190309 SUSTAINABLE A B

   C D E F

3. BIG SMALL GIG | JM/RV | 190309 SUSTAINABLE MATERIAL A

   B C D E F

4. BIG SMALL GIG | JM/RV | 190309 SUSTAINABLE MATERIAL DESIGN

   A B C D E F

5. A

6. None

7. AGENDA 21 AL GORE ALEX STEFFEN AMORY LOVINS AVAAZ BASEL

   CONVENTION BEDZED BIG HYDRO BILL MCDONOUGH BIOMASS ENERGY BO01 BREEAM BUSINESS SCHOOLS CARBON NEUTRAL CARDIFF PROCESS CAROLINE LUCAS CBD CDM CFSD CITES CLEAN COAL CLIMATE ALLIANCE CLIMATE CARE COMMUNITY GROUPS CSD DARYL HANNAH DISCOURSE THEORY DONGTAN DOWNSHIFTING E PSYCHOLOGY E SOCIOLOGY ECO-PHILOSOPHY ECO-VILLAGES ECODESIGN ECOLABELS ECOLOGICAL ECONOMICS ED BEGLEY JR EDEN PROJECT ELECTRIC CARS EMISSIONS TRADING EU SDS EVA FOOTPRINTING FORUM FOR THE FUTURE FRIENDS OF THE EARTH FSC WOOD FUTERRA GEORGE MONBIOT GMOS GRAHAM HILL GREEN ARCHITECTURE GREEN PARTIES GREEN REVOLUTION GREENPEACE HAMMARBY SJÖSTAD HYBRID CARS I = P.A.T INDUSTRIAL ECOLOGY JIM HANSEN JOHN ELKINGTON JOHN MANOOCHEHRI JOINT IMPLEMENTATION JONATHAN ROBINSON JONATHON PORRITT KYOTO PROTOCOL LCA/MFA/PIOT/MIOT LEED LEONARDO DICAPRIO LESTER BROWN LISBON STRATEGY LOCAL AGENDA 21 MARK LYNAS MASDAR MATA DE SESIMBRA MATERIALS SUBSTITUTION MEDIA MICHAEL BRAUNGART MILLENNIUM DEVELOPMENT MSC FISH NATIONAL PARKS NATURE RESERVES NEW DREAM NEW ECONOMICS NICHOLAS STERN NRDC NUCLEAR ORGANIC FOOD OTHER PARTIES PAUL EHRLICH PHOTOVOLTAICS PIC-POPS CONVENTIONS PLANET IN PERIL POLITECNICO DI TORINO POLITICAL ECOLOGY POLLUTION REMEDIATION RECYCLED PRODUCTS RECYCLING RELIGIOUS GROUPS RESOURCE VISION ROCKY MOUNTAIN INSTITUTE SCHOOLS SD COMMISSION SERI SID SLOW FOOD SMALL HYDRO SOLITAIRE TOWNSEND STERN REVIEW SUSTAINBLE DEVELOPMENT SYSTEMS ECOLOGY TALLBERG FORUM TED THE HUB TIDAL POWER TIM JACKSON TIM SMIT TRANSITION TOWNS TREE-HUGGER UN SUMMITS UNEP UNEP CHEMICALS UNFCC CLIMATE TALKS UNIVERSITIES USGBC VANDANA SHIVA VOLUNTARY OFFSET WANGARI MAATHAI WAVE POWER WB ENVIRONMENT WEF WIND POWER WISER EARTH WOLFGANG SACHS WOMEN’S GROUPS WORLDWATCH WTO ENVIRONMENT WUPPERTAL YOUTH GROUPS ZERI ZIPCAR
8. None

9. BEHAVIOUR SOLUTIONS SOCIAL SCIENCE PSYCHOLOGY POLICY/INFORMATION SYSTEM SOLUTIONS POLITICS GOVERNANCE

   ECONOMICS MASS MOVEMENTS RESOURCE SOLUTIONS POLLUTION MANAGEMENT NATURE PRESERVATION SUBSTITUTION/EFFICIENCY

10. FAIL

11. None
12. None

13. PROBLEM? SOLUTION? SCALE?

14. MATERI CULTUR PROBLEM? SOLUTION? SCALE?

15. 90% RESOURCE REDUCTION BY 2050

16. 90% RESOURCE REDUCTION BY 2050 10BN

17. None

18. BIG

19. BIG DEAL

20. A

21. ATTACK

22. A FAIL TTACK

23. A FAIL M CULTURE TTACK

24. A FAIL M CULTURE BIG DEAL TTACK

25. B

26. None

27. OIL

28. OIL IEA WEO (2008) INDICATES PEAK OIL AROUND 2020

29. None

30. SUN

31. SUN SOLAR ENERGY REACHING EARTH EXCEEDS HUMAN ENERGY CONSUMPTION X

    20,000
32. None

33. SOLAR ENVELOPE

34. SOLAR ENVELOPE 2050 : 2-3 PLANETS 2008 : 1.5 PLANETS

    CONSUMED BIOCAPACITY
35. None

36. CONSUMPTION

37. CONSUMPTION PROVISIONING SYSTEMS ! TOTAL MATERIALISATION ! DESIGN ?

38. None

39. N

40. NATURAL RESOURCES N

41. NATURAL RESOURCES N H

42. NATURAL RESOURCES PRODUCT CONSUMPTION N H

43. NATURAL RESOURCES PRODUCT CONSUMPTION N H

44. NATURAL RESOURCES PRODUCT CONSUMPTION N H

45. S CONSUMPTION NATURAL RESOURCES PRODUCT CONSUMPTION N H

46. ⊖R S CONSUMPTION NATURAL RESOURCES PRODUCT CONSUMPTION N H

47. ⊖R S CONSUMPTION NATURAL RESOURCES PRODUCT CONSUMPTION N H

48. ⊖R S CONSUMPTION NATURAL RESOURCES PRODUCT CONSUMPTION ⊗R N H

49. ⊖R S CONSUMPTION NATURAL RESOURCES PRODUCT CONSUMPTION ⊗R N H

50. ⊖R S CONSUMPTION NATURAL RESOURCES ⊗C PRODUCT CONSUMPTION ⊗R N

    H

51. ⊖R S CONSUMPTION NATURAL RESOURCES PRODUCT CONSUMPTION ⊖U ? ⊗R

    N H
52. None

53. NOT MAXIMISATION

54. NOT MAXIMISATION NOT MINIMISATION

55. NOT MAXIMISATION NOT MINIMISATION ⊗R/⊖U

56. INTERFACE NOT MAXIMISATION NOT MINIMISATION ⊗R/⊖U

57. None

58. PHOTOSYNTHESIS

59. PHOTOSYNTHESIS FRACTAL FORM 100% MATERIAL EFFICIENCY

60. climax

61. climax ECOSYSTEM

62. B I O M A S S TIME climax ECOSYSTEM

63. B I O M A S S TIME pioneer climax

    ECOSYSTEM

64. B I O M A S S TIME pioneer climax

    ECOSYSTEM

65. B I O M A S S TIME pioneer climax

    ECOSYSTEM
66. None

67. JM

68. JM OXFORD > UN

69. JM OXFORD > UN SCOE CO-OP 2001

70. JM OXFORD > UN SCOE CO-OP 2001 RV CONSULT RESEARCH

    2003 SCIENCE P&C POLICY STRATEGY

71. JM 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

72. JM 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 ⊗R/ ⊖U

73. B

74. BACKGROUND

75. SOLAR BACKGROUND

76. SOLAR CONSUMPTION BACKGROUND

77. SOLAR CONSUMPTION INTERFACE BACKGROUND

78. C

79. None

80. 1234

81. 1234 1 MATERIAL CULTURE 2 PROBLEMS 3 SOLUTIONS 4 ENABLERS

82. None

83. RESOURCES MEDIA APPLICATIONS FUNCTION

84. FOSSILS MINERALS BIOTA LIFESYSTEMS SUN ++ WATER SOIL LAND SPACE

    FOOD POWER GOODS MOBILITY BUILDINGS INFRASTRUCTURE ACTIVITY VALUE EXPERIENCE WELFARE RESOURCES MEDIA APPLICATIONS FUNCTION

85. FOSSILS MINERALS BIOTA LIFESYSTEMS SUN ++ WATER SOIL LAND SPACE

    FOOD POWER GOODS MOBILITY BUILDINGS INFRASTRUCTURE ACTIVITY VALUE EXPERIENCE WELFARE RESOURCES MEDIA APPLICATIONS FUNCTION 1 M CULTURE

86. A. BIOPHYSICAL RESOURCE LIMITS ABSORPTION (pollution, waste) STOCKS (freshwater, oil,

    minerals) SERVICES (climate, nutrient cycling, INPUTS (solar, tidal) B. NATURE VULNERABILITY SPECIES ECOSYSTEMS LANDSCAPES

87. A. BIOPHYSICAL RESOURCE LIMITS ABSORPTION (pollution, waste) STOCKS (freshwater, oil,

    minerals) SERVICES (climate, nutrient cycling, INPUTS (solar, tidal) B. NATURE VULNERABILITY SPECIES ECOSYSTEMS LANDSCAPES 2 PROBLEMS

88. A. SUPPLY POLLUTION REDUCTION STOCK CONSERVATION NATURE PRESERVATION B. USE

    BETTER USE OF RESOURCE C. ETHICS ME/US ETHICS THEM ETHICS

89. A. SUPPLY POLLUTION REDUCTION STOCK CONSERVATION NATURE PRESERVATION B. USE

    BETTER USE OF RESOURCE C. ETHICS ME/US ETHICS THEM ETHICS 3 SOLUTIONS
90. None

91. A INFORMATION B PRICES C LAWS D OTHER STUFF

92. A INFORMATION B PRICES C LAWS D OTHER STUFF 4

    ENABLERS
93. None

94. 3 SOLUTIONS

95. 3 SOLUTIONS PRINCIPLES STORIES DESIGN ROLE TECHNIQUES

96. PRINCIPLES

97. SUPPLY DEMAND ETHICS POLLUTION R CONSERVATION PRESERVATION BETTER APPLICATION ME/US

    THEM ⊖N ⊗C ⊗R

98. SUPPLY DEMAND ETHICS MANAGED DESIGNED INFORMED ⊖ ⊗ ⊗

99. SUPPLY DEMAND ETHICS MANAGED DESIGNED INFORMED SAFE EFFICIENT APPRECIATIVE ⊖

    ⊗ ⊗

100. STORIES

101. SUPPLY DEMAND ETHICS MANAGED DESIGNED INFORMED SAFE EFFICIENT APRECIATIVE PRODUCTIVE

     ELEGANT CREATIVE ⊖ ⊖ ⊖ ⊖

102. SUPPLY DEMAND ETHICS PRODUCTIVE ELEGANT CREATIVE POLLUTION R CONSERVATION PRESERVATION

     BETTER APPLICATION ME/US THEM

103. SUPPLY DEMAND ETHICS PRODUCTIVE ELEGANT CREATIVE POLLUTION R CONSERVATION PRESERVATION

     BETTER APPLICATION ME/US THEM CULTIVATION

104. DESIGN ROLE

105. SUPPLY MANAGEMENT DEMAND MANAGEMENT ETHICAL TRANSFORM SAFETY EFFICIENCY ETHICS TECHS?

     METHODS? TECHS? METHODS? TECHS? METHODS? ⊖ ⊗ ⊗

106. SUPPLY MANAGEMENT DEMAND MANAGEMENT ETHICAL TRANSFORM SAFETY EFFICIENCY ETHICS !

     ? ! DESIGN? ! DESIGN? ⊖ ⊗ ⊗

107. SUPPLY MANAGEMENT DEMAND MANAGEMENT ETHICAL TRANSFORM SAFETY EFFICIENCY ETHICS !

     ? ! NO MONEY MORE LIMITS ! POLITICS ⊖ ⊗ ⊗

108. TECHNIQUES

109. SUPPLY MANAGEMENT SUPPLY MANAGEMENT SUPPLY MANAGEMENT MANAGED > SAFE >

     PRODUCTIVE MANAGED > SAFE > PRODUCTIVE MANAGED > SAFE > PRODUCTIVE POLLUTION R CONSERVATION PRESERVATION SUPPLY

110. ETHICAL TRANSFORMATION ETHICAL TRANSFORMATION INFORMED > APPRECIATIVE > CREATIVE INFORMED

     > APPRECIATIVE > CREATIVE SUFFICIENCY RESPECT ETHICS

111. DEMAND MANAGEMENT DEMAND MANAGEMENT DEMAND MANAGEMENT DEMAND MANAGEMENT DESIGNED >

     EFFICIENT > ELEGANT DESIGNED > EFFICIENT > ELEGANT DESIGNED > EFFICIENT > ELEGANT DESIGNED > EFFICIENT > ELEGANT OBJECT FUNCTION USE WELFARE DEMAND

112. [NATURE’S DEFINITION OF EFFICIENCY, A PRODUCT OF EVOLUTIONARY PRESSURE, IS

     FRACTAL FORMS WHICH OPTIMISE THE RATIO BETWEEN PHOTOSYNTHETIC SURFACE AREA AND BIOMASS VOLUME]

113. [NATURE’S DEFINITION OF EFFICIENCY, A PRODUCT OF EVOLUTIONARY PRESSURE, IS

     FRACTAL FORMS WHICH OPTIMISE THE RATIO BETWEEN PHOTOSYNTHETIC SURFACE AREA AND BIOMASS VOLUME] OPTIMISATION

114. OBJECT OBJECT OBJECT OBJECT RESOURCE EFFICIENCY RESOURCE EFFICIENCY RESOURCE EFFICIENCY

     RESOURCE EFFICIENCY PROCESS & PRODUCT LOCAL- ISATION CYCLING SYSTEMS DURABILITY D

115. FUNCTION FUNCTION FUNCTION FUNCTIONAL EFFICIENCY FUNCTIONAL EFFICIENCY FUNCTIONAL EFFICIENCY SPATIAL

     OBJECT NEGATIVE D

116. USE USE USE USE EFFICIENCY USE EFFICIENCY USE EFFICIENCY SEQUENTL

     USE SIMULTN USE LIFESTYLE SYSTEMS D

117. WELFARE WELFARE WELFARE EFFICIENCY WELFARE EFFICIENCY SKILLS SERVICES D

118. SUSTAINABILITY SUPPLY DEMAND ETHICS PRINCIPLES MATERIAL CLEAN ABUNDANT CONTROLLED EFFICIENT

     DESIGNED NETWORKED SKILLED MEDIA Soil Space Land Water RESOURCES Fossils Life-systems Minerals Biota 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

119. SUSTAINABILITY SUPPLY DEMAND ETHICS PRINCIPLES MATERIAL CLEAN ABUNDANT CONTROLLED EFFICIENT

     DESIGNED NETWORKED SKILLED MEDIA Soil Space Land Water RESOURCES Fossils Life-systems Minerals Biota 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
120. None

121. H N p c

122. H N p c

123. H N p c METABOLISM

124. H N p c METABOLISM

125. H N p c METABOLISM RECYCLING

126. H N p c METABOLISM RECYCLING

127. H N p c METABOLISM R E S I L

     I E N C E RECYCLING

128. H N p c METABOLISM R E S I L

     I E N C E RECYCLING

129. H N p c METABOLISM SYMBIOSIS R E S I

     L I E N C E RECYCLING

130. H N p c METABOLISM SYMBIOSIS R E S I

     L I E N C E RECYCLING

131. H N p c METABOLISM SYMBIOSIS R E S I

     L I E N C E BIOCYCLING RECYCLING

132. H N p c METABOLISM SYMBIOSIS R E S I

     L I E N C E BIOCYCLING RECYCLING

133. H N p c METABOLISM SYMBIOSIS R E S I

     L I E N C E BIOCYCLING SERVICE-USE RECYCLING

134. H N p c METABOLISM SYMBIOSIS R E S I

     L I E N C E BIOCYCLING SERVICE-USE RECYCLING

135. 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

136. C

137. CONCEPTS

138. C 1234 ONCEPTS

139. C 1234 CULTIVATION ONCEPTS

140. C 1234 CULTIVATION OPTIMISATION ONCEPTS

141. D

142. Programme/Brief Meta Programme Economic/Political Agenda Hard Programme Buildings, Infrastructure Soft

     Programme Aesthetics, Mood, Culture Pollution Reduction Stock Conservation Nature Preservation Sufficiency 

 

 Compassion MATERIAL SPATIAL SOCIAL PERSONAL OBJECTS STRUCTURES Resource 

Efficiency Product 

Efficiency Cycling 

Systems

143. Social Discourse Programme/Brief Functional Decomposition vehicle > property > food

     > growth > mobility > space > nutrition > wealth > access accommodation health wellbeing Meta Programme Social Discourse Components Hard Programme Buildings, Infrastructure Soft Programme Aesthetics, Mood, Culture Politics Identity Inclusion Crime Environment Nature Ethics Risk Cost Pollution Reduction Stock Conservation Nature Preservation Sufficiency 

 

 Compassion S E MATERIAL SPATIAL SOCIAL PERSONAL OBJECTS ACTIONS STRUCTURES Resource 

Efficiency Functional 

Efficiency Use 

Efficiency Welfare 

Efficiency User Skills Development End-use services U Simultaneous / Sequential Spatial F Simultaneous / Sequential Object F Elimination of Negative F Process 

Efficiency Product 

Efficiency Localisation Cycling Systems Durability Simultaneous / Sequential UC Social Discourse

144. Social Discourse Programme/Brief Functional Decomposition vehicle > property > food

     > growth > mobility > space > nutrition > wealth > access accommodation health wellbeing Meta Programme Social Discourse Components Hard Programme Buildings, Infrastructure Soft Programme Aesthetics, Mood, Culture Politics Identity Inclusion Crime Environment Nature Ethics Risk Cost Pollution Reduction Stock Conservation Nature Preservation Sufficiency 

 

 Compassion S E MATERIAL SPATIAL SOCIAL PERSONAL OBJECTS ACTIONS STRUCTURES Resource 

Efficiency Functional 

Efficiency Use 

Efficiency Welfare 

Efficiency User Skills Development End-use services U Simultaneous / Sequential Spatial F Simultaneous / Sequential Object F Elimination of Negative F Process 

Efficiency Product 

Efficiency Localisation Cycling Systems Durability Simultaneous / Sequential UC Social Discourse METHOD
145. None
146. None
147. None
148. None
149. None

150. FUNCTIONAL SURFACE

151. FUNCTIONAL SURFACE

152. FUNCTIONAL SURFACE

153. FUNCTIONAL SURFACE

154. FUNCTIONAL SURFACE

155. None
156. None
157. None
158. None

159. INEFFICIENT USE

160. INEFFICIENT USE

161. INEFFICIENT USE

162. INEFFICIENT USE

163. INEFFICIENT USE EFFICIENT USE

164. INEFFICIENT USE EFFICIENT USE

165. INEFFICIENT USE EFFICIENT USE

166. INEFFICIENT USE EFFICIENT USE

167. INEFFICIENT USE EFFICIENT USE EXPERIENCE

168. None
169. None

170. SHARING

171. SHARING

172. SHARING

173. SHARING ACCESS

174. SHARING ACCESS CONSUMPTION SYSTEM

175. SHARING ACCESS CONSUMPTION SYSTEM

176. SHARING ACCESS CONSUMPTION SYSTEM FUNCTION

177. D

178. DESIGN

179. D METHOD ESIGN

180. D METHOD EXPERIENCE ESIGN

181. D METHOD EXPERIENCE FUNCTION ESIGN

182. E

183. None
184. None
185. None
186. None
187. None

188. ??!

189. None

190. ??!

191. None
192. None
193. None

194. !

195. E

196. EXCELLENCE

197. E ? XCELLENCE

198. E ? ??! XCELLENCE

199. E ? ??! ! XCELLENCE

200. F

201. None

202. 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.

203. 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. FAD

204. 10. HE pro 6 7 8 9 10 2 3

     4 5 based es of et which d thin arth’s One P court an ini engag speci The in repre Group
205. None

206. 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.
207. None

208. Social Discourse Programme/Brief Functional Decomposition vehicle > property > food

     > growth > mobility > space > nutrition > wealth > access accommodation health wellbeing Meta Programme Social Discourse Components Hard Programme Buildings, Infrastructure Soft Programme Aesthetics, Mood, Culture Politics Identity Inclusion Crime Environment Nature Ethics Risk Cost Pollution Reduction Stock Conservation Nature Preservation Sufficiency 

 

 Compassion S E MATERIAL SPATIAL SOCIAL PERSONAL OBJECTS ACTIONS STRUCTURES Resource 

Efficiency Functional 

Efficiency Use 

Efficiency Welfare 

Efficiency User Skills Development End-use services U Simultaneous / Sequential Spatial F Simultaneous / Sequential Object F Elimination of Negative F Process 

Efficiency Product 

Efficiency Localisation Cycling Systems Durability Simultaneous / Sequential UC Social Discourse

209. Social Discourse Programme/Brief Functional Decomposition vehicle > property > food

     > growth > mobility > space > nutrition > wealth > access accommodation health wellbeing Meta Programme Social Discourse Components Hard Programme Buildings, Infrastructure Soft Programme Aesthetics, Mood, Culture Politics Identity Inclusion Crime Environment Nature Ethics Risk Cost Pollution Reduction Stock Conservation Nature Preservation Sufficiency 

 

 Compassion S E MATERIAL SPATIAL SOCIAL PERSONAL OBJECTS ACTIONS STRUCTURES Resource 

Efficiency Functional 

Efficiency Use 

Efficiency Welfare 

Efficiency User Skills Development End-use services U Simultaneous / Sequential Spatial F Simultaneous / Sequential Object F Elimination of Negative F Process 

Efficiency Product 

Efficiency Localisation Cycling Systems Durability Simultaneous / Sequential UC Social Discourse ‘FAD’
210. None

211. BIG IT UP

212. A PROJECT REVIEW B DESIGN POLICY C STAFF TRAINING E

     UNI-PROJECTS F DESIGN METHOD BIG IT UP

213. F

214. FUTURE

215. F FAD? UTURE

216. F FAD? FAD! UTURE

217. F FAD? FAD! UNI-PROJECTS UTURE

218. A B C D E F

219. BIG SMALL GIG | JM/RV | 190309 A B C

     D E F

220. BIG SMALL GIG | JM/RV | 190309 A B C

     D E F SUSTAINABLE MATERIAL DESIGN

221. BIG SMALL GIG | JM/RV | 190309 A B C

     D E F TTACK ACKGROUND ONCEPTS ESIGN XCELLENCE UTURE

222. FAIL SOLAR 1234 METHOD ? FAD BIG SMALL GIG |

     JM/RV | 190309 A B C D E F

223. BIG SMALL GIG | JM/RV | 190309 A B C

     D E F M CULTURE CONSUMPTION CULTIVATION EXPERIENCE ??! FAD!

224. BIG SMALL GIG | JM/RV | 190309 BIG INTERFACE OPTIMISATION

     FUNCTION ! UNI-PROJECTS A B C D E F

225. BIG SMALL GIG | JM/RV | 190309 A B C

     D E F SUSTAINABLE MATERIAL DESIGN