Beyond the EU: DORA and NIS 2 Directive's Global Impact
BTES at ACSA March 2015
1. @
Architecture and Building Technology in a
Post-Critical Age
Toronto 2015
2.
Par%cipants
Terri
Boake
Erin
Carraher
James
Doerfler
Jonathan
Massey
Patricia
Kucker
Moderator
Franca
Trubiano
Architecture and Building Technology in a
Post-Critical Age
Toronto 2015
3.
4.
5.
6.
7. TAD
TAD
TECHNOLOGY
ARCHITECTURE
+
DESIGN
Journal
of
Editorial
Board
Marci
Uihlein
Smith
University
of
Illinois
Andrzej
Zarzycki
New
Jersey
InsQtute
of
Technology
Terri
Boake
University
of
Waterloo
Franca
Trubiano
University
of
Pennsylvania
8. Journal
Mission:
TECHNOLOGY
|
ARCHITECTURE
+
DESIGN
is
a
peer-‐reviewed
internaQonal
journal
dedicated
to
the
advancement
of
scholarship
in
building
technologies
and
their
impact,
integraQon
and
translaQon
within
architecture
and
design.
TAD
encourages,
captures,
and
shares
new
knowledge
in
how
we
think,
make
and
use
technology
in
the
building
arts.
ArQcles
are
sought
that
feature
primary
research
in
emerging
materials,
construcQon
techniques,
design
integraQon,
structures,
building
systems,
energy,
environmental
design,
informaQon
technology,
digital
fabricaQon,
sustainability
and
resiliency,
history
and
theory
of
technology,
and
building
technology
educaQon.
Aimed
at
researchers,
educators,
and
pracQQoners,
the
journal
seeks
to
advance
and
transform
the
current
discourse
on
technology
in
order
to
reimagine
its
role
within
the
fields
of
architecture
and
design.
9. Panel
Discussion
1/2
BTES
represents
an
internaQonal
group
of
academics
who
teach
in
schools
of
architecture
and
who
are
commi^ed
to
advancing
the
value
of
technology
in
the
educaQon
of
the
architect.
Structural
design,
new
materials,
construcQon
techniques,
environmental
design,
and
digital
fabricaQon
are
some
of
the
subjects
of
interest
to
its
nearly
100
strong
membership,
be
it
manifest
via
teaching,
research,
or
scholarship.
In
this
light,
the
following
panel
discussion
seeks
to
idenQfy
contemporary
issues
of
criQcal
importance
to
architectural
educaQon
as
it
seeks
to
address
the
role
which
technology
plays
in
shaping
the
pracQce
of
design.
• Architecture,
both
within
and
beyond
the
academy,
has
recently
turned
to
all
things
technological;
doing
so,
in
an
evermore
globalized
and
networked
set
of
pracQces
predicated
on
vast
quanQQes
of
data
exchange,
the
promoQon
of
highly
mechanized
forms
of
fabricaQon,
diminishing
access
to
natural
resources
and
extensive
transnaQonal
displacements
of
human
labor.
Much
that
condiQons
the
architect’s
pracQce
is
now
predicated
on
the
limits
and
extents
of
ever
more
technological
imperaQves,
ocen
at
the
exclusion
of
all
things
criQcal
or
discursive.
10. Panel
Discussion
2/2
• Moreover,
the
extent
to
which
important
advances
in
building
technology
and
construcQon
have
been
moQvated
by
quesQons
of
theory,
ethics,
and
jusQce,
is
negligible,
if
nonexistent.
The
cultural
dimension
of
building
has
rarely
been
influenQal
in
the
development
and
deployment
of
building
based
technologies.
Instead,
market
imperaQves
and
global
procurement
pracQces
have
been
far
more
significant
in
condiQoning
what
actually
gets
built.
Acer
all,
architects
are
marginally
implicated
in
the
material
transformaQon
of
their
pracQces.
The
reasons
for
which
are
many.
Hence,
no
Qmelier
a
moment
is
there
to
reevaluate
the
criQcal
dimension
of
architectural
design,
parQcularly
in
what
concerns
its
relaQonship
to
the
material
and
environmental
technologies
that
subtend
its
pracQce
.
This
panel
discussion
seeks
to
address
the
present
lacuna
in
the
theoreQcal
foundaQons
of
the
architectural
design
by
asking
how
building
technology
might
be
addressed
in
our
post
criQcal
age.
11. Erin
Carraher
University
of
Utah
ARCHITECTURE
AND
BUILDING
DIGITAL
TECHNOLOGY
IN
a
Post-‐Cri%cal
Age
Past
the
analog
versus
digital
divide
in
architectural
educaQon,
the
quesQon
now
becomes
what
are
the
digital
technologies
fundamental
to
an
architect’s
educaQon,
and
how/when/where
do
we
introduce
them?
Faculty
must
also
consider
whether
or
not
digital
technologies
–
especially
BIM
and
parametric
modeling
–
can
and
should
be
used
as
design
tools
and
whether
or
not
the
uQlizaQon
of
digital
tools
to
incorporate
data-‐rich
content
concerning
building
performance,
structural
opQmizaQon,
and
digital
fabricaQon
output
are
enriching
the
pracQce
of
architecture
or
are
too
complex
for
students
to
digest
while
in
school.
In
a
post-‐criQcal
context,
what
then
are
pedagogical
tools
and
curricular
frameworks
that
allow
for
the
introducQon
of
criQcal
digital
technologies
as
integrated
and
integral
components
of
architectural
educaQon?
12.
13.
14.
15.
16.
17.
18.
19.
20. Terri
Boake
University
of
Waterloo
PRACTICE
BASED
EDUCATION
Technology
is
being
reposiQoned
in
the
pracQce
and
appreciaQon
of
architecture.
This
is
evidenced
by
an
increasing
focus
on
sustainable
design
as
well
as
in
the
recent
announcement
by
NCARB
regarding
licensure
upon
accreditaQon.
Studies
by
Design
Intelligence
seem
to
note
that
schools
are
divided
into
two
primary
groups:
those
with
a
focus
on
history/theory
and
those
that
value
technology/sustainable
design
and
a
future
in
pracQce.
In
light
of
this
informaQon,
how
might
the
content
and
format
of
educaQon
change
and
be
changed?
How
can
the
experQse
of
BTES
be
involved
in
this
potenQal
shic
towards
this
pracQce
based
educaQon
focus?
21. 1. Licensure
upon
graduaQon
proposal
by
NCARB
2. Current
pass
rates
for
licensing
exams
3. Design
Intelligence
Survey
regarding
schools
with
technical
strengths
Terri
Meyer
Boake,
University
of
Waterloo
School
of
Architecture
28. In
the
survey
of
students,
the
responses
by
those
a^ending
Harvard
and
Columbia
(the
only
Ivy
League
schools
with
published
student
survey
results)
showed
a
body
of
students
which
tended
to
be
ambivalent
to
architecture’s
professional
insQtuQons,
and
the
profession
as
a
whole.
Asked
if
they
plan
to
become
a
licensed
architect
in
the
future,
only
73%
of
Harvard
and
61%
of
Columbia
said
yes,
compared
to
a
naQonal
average
of
83.4%.
NaQonally,
63%
of
students
either
already
are,
or
plan
to
become
LEED
accredited.
At
Columbia,
this
drops
to
44%,
and
at
Harvard
just
37%
–
and
this
in
a
profession
which,
as
the
report
demonstrates,
values
sustainability
very
highly.
Finally,
this
ambivalence
towards
the
profession
of
architecture
manifests
in
fewer
graduates
being
happy
to
work
for
others:
asked
what
they
plan
to
do
acer
graduaQon,
only
1.8%
of
students
naQonally
predicted
self-‐employment.
At
Columbia,
this
rises
to
5%,
and
at
Harvard
to
a
colossal
12%.
Let
me
reiterate
that:
Harvard
graduates,
despite
being
hugely
coveted
by
architecture
firms,
are
almost
seven
Qmes
as
likely
as
other
students
to
go
it
alone.
29.
30.
31.
32. James
Doerfler
Philadelphia
University
INDUSTRY
SPONSORED
PROJECTS
Taking
advantage
of
our
academic
abiliQes
to
uncover
projects
combined
with
our
students
virtuous
perspecQve
allows
industry
sponsored
projects
to
flourish
in
the
right
environment.
It
is
possible
to
provide
soluQons
that
are
ocen
not
limited
by
constraints
and
ocen
have
outcomes
that
surpass
expectaQons.
Can
the
way
we
teach
and
support
project-‐based
research
in
the
academy
and
create
a
value-‐added
environment
for
sponsorship
of
projects?
What
environment
enhances
project-‐based
research
outcomes?
What
role
does
technological
educaQon
play
in
project-‐based
research?
33. 103rd
ACSA
Annual
MeeQng
–
Toronto
2015
Architecture and Building Technology in a
Post-Critical Age:
Industry Sponsored Research
34. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
What
lures
industry
sponsored
research?
35. Cal Poly - Fourth Year Architectural Design Studio – Kaohsuing
Cruiseship Terminal Competition
Eight students worked together as the design team for RNT Architects
and Buro Happold Los Angeles for this professional competition in
Taiwan.
DIAGRAMS
URBAN RESPONSE
LANDSCAPE
BUILDING
ENVIRONMENTAL SYSTEMS
PLANS
ELEVATIONS
SECTIONS
SKIN
2
3
4
6
8
14
16
18
20
26
17SECTIONS
CROSS SECTION 02 SCALE: 1:400
Departing Passengers Arriving Passengers Office Workers General Public
1. Concourse 2. International Terminal 3. Domestic Terminal 4. Offices 5. Underground Parking 6. Generator 7. Atrium
12
3
4
5
7
6
BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
36. Cal Poly - Fourth Year Architectural Design Studio – Gensler Design/
Build
Gensler Los Angeles requested Cal Poly to work with them on a
design for a large table in the lobby of their new offices in downtown
Los Angeles. Three students over two quarters developed a design for
the table and provided digital files for the fabrication. Installed January
2012.
Exploded Rib Assembly Exploded Waffle Assembly Exploded Fiberglass Assembly
Vertical ribs friction fit into horizontal
Opposing sides joined together
Fiberglass fabricated in three main panels
and joined on rib structure
2)
rage:
8'0"
4'0"
BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
37. Cal Poly - Fourth Year Architectural Design Studio – Gensler Design/
Build
BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
38. Cal Poly – Graduate Research Studio
Architecture!
Graduate Research Studio – Feasibility for Faculty Retreat Center and
Marina for Diamond Valley Lake. This project and report is fulfilling a
research grant provided by the Metropolitan Water District of Southern
California for a off-the grid and water independent 100 unit facility. All
services were researched and sized and a budget was provided. The
team was made up of seven graduate students from different
disciplines.
Le#$column$from$top:$Small,$
Medium$and$Large$prefabricated$
housing$units$with$ar;culated$
second$skin$for$shading.$Extra$
Large$building$is$recep;on$and$
Conference$Center.$Right$column$
from$top:$Masterplan$and$
Rendering$of$buildings$on$site.$
$
The$students$were$asked$to$
provide$all$design$work,$present$
their$work$to$the$client$and$
consul;ng$engineers,$contribute$
during$discussions$and$provide$all$
final$renderings$and$drawings$and$
compose$the$feasibility$report$
(2012).$
$
$
$
Student$team:$H.$Anderson,$B.$
Anton,$B.$Dwyer,$K.$JueQe,$C.$
Kossack,$J.$Schmiidt,$T.$Shorey$
$
Faculty:$J.$Doerfler$
$
$
$
$
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
SMALLUNITDESIGNFORTHEDIAMONDVALLEYLAKERETREATCENTERANDMARINA
017
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
MEDIUMUNITDESIGNFORTHEDIAMONDVALLEYLAKERETREATCENTERANDMARINA
021
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
LARGEUNITDESIGNFORTHEDIAMONDVALLEYLAKERETREATCENTERANDMARINA
025
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
030
CONFERENCECENTERDESIGNFORTHEDIAMONDVALLEYLAKERETREATCENTER
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marin
Cal Poly Architecture
Grad Research Studio
BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
39. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
04
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
04
PROJECTSUMMARYOFDIAMONDVALLEYLAKERETREATCENTERANDMARINA
BUILDING AT A GLANCE
PROJECT SUMMARY OF DIAMOND VALLEY LAKE RETREAT CENTER AND MARINA
Location: Diamond Valley Lake
Hemet, CA
Principal Use: Residential and commercial
Gross Area: Units (varies):
25@ 336 sq. ft. 8,400 sq. ft.
45@ 420 sq. ft. 18,900 sq. ft.
32@ 504 sq. ft. 16,128 sq. ft.
Total: 43,428 sq. ft.
Conference Center: 9,287 sq. ft.
Marina:
Administration Building 3,528 sq. ft.
Commercial Building 4,032 sq. ft.
Toilets 1,008 sq. ft.
Total: 8,568 sq. ft.
Energy & water plant: 1,000 sq. ft.
Gazebo 420 sq. ft.
Total: 62,703 sq. ft.
ENERGY SYSTEMS AT A GLANCE
Microgrid for interconnection buildings
Source: Photovoltaic array 230 kW
Diesel generator 30 kW
Battery bank 3.1 million ah
Demand: kWh per year 380,000 kWh/year
WATER CYCLE AT A GLANCE
Micro utility grid to interconnect buildings
Water supplied from Diamond Valley Lake
All surplus treated wastewater to be pumped off-site for irrigation
Source: Water purificiation Pre-filtration with reverse
osmosis and sterilization
Wastewater treatment: Living System
Greywater treatment: Living System
To be used for toilet flushing, then
sent to education center for irrigation
Rainwater: Controlled runoff
Demand: Per day 10,000 gallons
CLIMATE CONTROL SYSTEMS AT A GLANCE
Cooling Source: 3,000 cfm evaporative coolers in each unit
Btu’s of cooling per gallon of water 7,830 btu
Heating Source: Solar hot water
Radiant heating
Ventilation: Natural Ventilation
Fan-assisted
PASSIVE SYSTEMS AT A GLANCE
Orientation Solar and wind
Shade Layered building envelope
Building management system to close up the units
Perforated shed roof to shade unit
Natural Daylight Windows and 80 sq. ft. glass accordion door
Building Envelope Roof and floor R-25
Wall R-20
Window Dual glazed low-E U 0.29 blocks 95% of UV rays
Thermal Mass 3.5”exposed concrete floor slab
Phase change BIOpcm M51 on all walls, floor, and ceiling 51 btu/sf
KEY SUSTAINABILITY FEATURES
Water Conservation Low-flow fixtures
Greywater recycling
Recycled/Certified Materials 90% recycled steel and FSC certified lumber used throughout
Construction Waste Pre-fab construction reduces construction waste by 80%
Lighting LED lighting only
Indoor Air Quality LEED Platinum requirements for VOC’s
Solar Hot Water Individual Rheem Solar Hot Water for each unit
Building Management System Active motorized shading screens to regulate direct sun exposure and
to fire protect and secure units
Cal Poly – Graduate Research Studio – Faculty Retreat Center and
Marina for Diamond Valley Lake. Client : MWDSC
40. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
07
MASTERPLANFORTHEDIAMONDVALLEYLAKERETREATCENTERANDMARINA
Cal Poly – Graduate Research Studio – Faculty Retreat Center and
Marina for Diamond Valley Lake. Client : MWDSC
41. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
08
MASTERPLANFORTHEDIAMONDVALLEYLAKERETREATCENTERANDMARINA
Cal Poly – Graduate Research Studio – Faculty Retreat Center and
Marina for Diamond Valley Lake. Client : MWDSC
42. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
09
MASTERPLANFORTHEDIAMONDVALLEYLAKERETREATCENTERANDMARINA
Cal Poly – Graduate Research Studio – Faculty Retreat Center and
Marina for Diamond Valley Lake. Client : MWDSC
43. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
DIAMOND VALLEY LAKE
Faculty Retreat Center and Marina
Cal Poly Architecture
Grad Research Studio
010
MASTERPLANFORTHEDIAMONDVALLEYLAKERETREATCENTERANDMARINA
Cal Poly – Graduate Research Studio – Faculty Retreat Center and
Marina for Diamond Valley Lake. Client : MWDSC
44. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
Cal Poly – Graduate Research Studio – Same, Tanzania Polytechnic
Project with Arup Engineers
45. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
Cal Poly – Graduate Research Studio – Same, Tanzania Polytechnic
Project with Arup Engineers
46. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
SCHEMATIC DESIGN
Cal Poly Architecture and Environmental Design
Graduate Research Studio
DESALINATION PLANT, MONTEREY, CA
Cal Poly Architecture and Environmental Design: Graduate Research Studio
4
01
Aerial View
DESALINATION PLANT, MONTEREY, CA
Cal Poly Architecture and Environmental Design: Graduate Research Studio
8
01
Site Plan : Sustainable Features
Proposed
1. Bike Path(1a) / Bike Racks(1b) / Stor-
age and Showers(1c) Reduces Automo-
bile Pollution
2. On-Site Charging Station and Electri-
cal Powered Vehicles for Staff Reduces
Automobile Pollution
3. Priority Parking for 5% Carpools and
Vanpools Reduces Automobile Pollution
Heat Island Effect
Roof Surface Reducing Heat Island Ef-
fect
6. Service Road Lighting Reducing Light
Pollution
7. Lighting on Motion Sensors Reducing
Light Pollution
8. WaterSense Fixtures and Roof Rain-
water Harvesting Reducing Water Use
9. Building Design that Maximizes Energy
Performance
10. Installation of Solar Panels Utilizing
On-site Renewable Energy
11. Use Sustainable Building Materials
and Reduce Waste
12. Promote Better Indoor Air Quality and
Access to Daylight and Views
Legend
Utilized
1. Minimize Distruption to Existing Eco-
systems protecting and Restoring the
Habitat
2. Supporting the Habitat with Native
and Adaptive Vegetation that Minimizes
Water Use
3. Trees Shading Road Surface Reduc
ing Heat Island Effect
4. Building Design Maximizes Daylighting
and Views
01
02
03
DESALINATION PLANT, MONTEREY, CA
Cal Poly Architecture and Environmental Design: Graduate Research Studio
23
Site Water Flow Diagram
Seawater
Wastewater
Desalinated water
Water pumped from the ocean passes through
the water. The bi-product is displaced into a set
stored in two large cylindrical tanks adjacent the
treatment building. These tanks provide a constant
supply of water to the treatment building and are
located at a higher point on the site, taking advan-
phase continues through to the RO trains, which
After post-treatment the desalinated potable water
is stored in two large cylindrical tanks outside the
treatment building, while the bi-product / brine
water is displaced into the brine pond. The de-
salinated water is disturbed to consumers off-site
while the brine water is set to the outfall, returning
to the ocean.
the length of water lines required. This plan also
reduces the number of bends in the water lines,
saving energy lost due to friction and turbulence.
Cal Poly – Graduate Research Studio – Desalination Plant for
Monterey CA. Client: California American Water
47. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
DESALINATION PLANT, MONTEREY, CA
Cal Poly Architecture and Environmental Design: Graduate Research Studio
9
01
Project Summary
Up to site
To feedwater storage
Backwash ponds to discharge
To high pressure pumps
To 2nd pass or bypass
Out to brine discharge
On to post-stabilization
Pump to storage
To distribution
Brine Pond and discharge
Site:
Principal Use:
Buildings:
Equip. Slabs/Screens:
Charles Benson Rd.
Marina, California
Site Undeveloped
Agricultural and industrial within 1 mile
Treatment Building
Administration Building
Multi-media Filter Area
Identity Screen
sq. ft.
sq. ft.
sq. ft.
sq. ft.
9.4 mi north of Monterey, CA
21,600
11,700
16,800
10,900
Electrical Substation
Generator
Switchgear, inside R.O.
sq. ft.
sq. ft.
sq. ft.
4,500
2,100
1,800
Tanks:
Ponds:
Free-Standing Pumps:
Feedwater Tanks
Clearwells
Backwash Supply
Backwash Wastewater
Brine Storage
Clearwell Pumps
gal.
gal.
gal.
sq. ft.
sq. ft.
sq. ft.
2x500,000
2x1,000,000
200,000
30,000
86,400
1,500
Perimeter Fence:
Roadway Gates:
Security A/V:
Project perimeter
Public and Service Entry
Campus wide surveilance
lin. ft.
loc.
4,690
3
Full Coverage
Supply of feedwater
Feedwater tanks
Loop to backwash
First pass high pressure
Second pass feed pump
Loop to energy recovery
UV reactor
Post treatment stage
Clearwell storage
Brine from 1st and 2nd
Pumps at beach
40 ft. x 8 ft. dia
Backwash waste to pond
5 microns or smaller
Pumps to R.O.
or bypass
Add pressure to 1st pass
Disinfection stage
Add appropriate components
Finished product
Collection from R.O.
1st
pass:
2nd
pass:
3rd
pass:
Treatment Builing:
Administration Building:
Main Courtyard:
Identity Screen:
Water Feature:
Suspended walkway
Exhibition hall
Xeriscape exhibit
Facade of Treatment Building
Through Main Courtyard
View Filtration and R.O.
Exhibits by owner
Landscape in contract
Shows educational graphics
Recycling of test water
Rain harvesting:
Xeriscape landscaping:
Bioswales:
Reduce grading:
Reduce footprint:
Prepare for Solar:
Entire roof, all structures
No water after establishment
Bioswales at all road edges
Build to contours
Organize by process
Structural roof design
Landscape establishment
Also, permeable paving
Maximize undisturbed site
Layout and conduits for solar equip.
Cal Poly – Graduate Research Studio – Desalination Plant for
Monterey CA. Client: California American Water
48. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
01
02
04
DESALINATION PLANT, MONTEREY, CA
Cal Poly Architecture and Environmental Design: Graduate Research Studio
65
06
07
08
10
Scope and Site Comparisons
Original Conventional Design
Proposed Sustainable Design
SF of Buildings 50,100 sf 33,300sf
CY Bulk Excavation 157,357cy 37,100cy
Paving 211,400sf 48.112sf
Original Converntional Design
Sustainable Architecture Design
SF of Buildings CY Bulk Excavation Paving
0
100sf
200sf
Scope Comparisons Diagram
Cal Poly – Graduate Research Studio – Desalination Plant for
Monterey CA. Client: California American Water
49. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
PhilaU – Nexus Sprint Project – Major Media Company sponsored
charrette for House of the Future
50. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
PhilaU – Nexus Sprint Project – Major Media Company sponsored
charrette for House of the Future
51. BTES
Session
–
Architecture
and
Building
Technology
in
a
Post-‐CriQcal
Age
What
academic
environment
enhances
industry
sponsored
research?
52. College
of
Architecture
and
Environmental
Design
Masters
Programs:
M
Architecture
MS
Architecture
(High
Performance
Buildings)
MS
Sustainable
Design
MS
Geodesign
MS
ConstrucQon
Management(IPD)
MS
Interior
Design
Opportuni%es
for
Research:
Industry
–
sponsored
research
Imbedded
research
(externships)
University–wide
Nexus
Sprints
CollaboraQons
with
other
insQtuQons
(Aalto
University
Design
Factory)
53. Jonathan
Massey
California
College
of
the
Arts
PROTOTYPING
A
NEW
PROFESSION
In
the
CreaQve
Architecture
Machines
Studio,
taught
at
California
College
of
the
Arts
by
Jason
Kelly
Johnson
and
Michael
Shiloh,
students
test
new
arQculaQons
between
design
and
construcQon
by
prototyping
roboQc
assemblies
that
scan
the
environment,
apply
a
design
logic,
and
build
through
iteraQve
mechanisms
that
combine
digital
and
material
feedbacks.
This
pedagogy
uses
advanced
technology
to
teach
students
how
they
can
fundamentally
reimagine
the
design-‐and-‐construcQon
process
to
address
the
scale
and
speed
of
contemporary
development
processes.
62. Jason
Kelly
Johnson
and
Michael
Shiloh
Creative
Architecture
Machines
Studio
California
College
of
the
Arts
63.
64.
65.
66.
67.
68.
69.
70.
71.
72.
73.
74.
75. Patricia
Kucker
University
of
CincinnaQ
STEM
The
advent
of
21st
century
technologies,
coupled
with
the
irreversible
consequences
of
global
climate
change
and
the
shicing
urban
needs
for
an
expanding
urban
populaQon
of
2.5
billion
people
delimit
the
core
challenges
that
are
defining
the
future
of
the
discipline
of
Architecture.
This
short
paper
is
an
overview
of
the
STEM
Academy’s
charter,
and
then
promotes
architecture’s
evoluQon
to
a
STEM
discipline.
76. BTES
2015
ACSA
–
Toronto
Patricia
Kucker,
University
of
CincinnaQ
77. BTES
2015
ACSA
–
Toronto
Patricia
Kucker,
University
of
CincinnaQ
Our
problem
is
this:
men
live
on
the
earth.
Why?
How?
Others
will
answer
you.
My
task
is
to
search,
is
to
try
to
save
these
men
of
today
from
misfortune,
from
catastrophes,
to
establish
them
in
condi?ons
of
happiness,
of
everyday
happiness,
of
harmony.
It
concerns
especially
reestablishing
or
establishing
harmony
between
men
and
their
environment.
Le
Corbusier
1928
78. BTES
2015
ACSA
–
Toronto
Patricia
Kucker,
University
of
CincinnaQ
79. BTES
2015
ACSA
–
Toronto
Patricia
Kucker,
University
of
CincinnaQ
Abelardo
Morell
80. BTES
2015
ACSA
–
Toronto
Patricia
Kucker,
University
of
CincinnaQ
81. BTES
2015
ACSA
–
Toronto
Patricia
Kucker,
University
of
CincinnaQ