Recording Device (Part 2)

The Architectist Records the City.


Recording Device, NYC Pier (1996) (This project was about recording an “image” or in my case “movement” and “image.” After visiting the given site and completing a thorough analysis of how a photographic lenses and shutter work, the idea that evolved was to record the movement of the adjacent traffic. The movement (speed and weight) of the passing automobiles and other vehicles that drive over the adjacent roadway would be translated to the recording device in the Hudson River which would in turn sculpt the pier accordingly. These are slides taken by the professor of the models I built to fit into the class site model.)


Recording Device, Image #4
Architectist-0016.jpg
Copyright © 2010 Frank Cunha III


Recording Device, Image #5
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Copyright © 2010 Frank Cunha III

Recording Device, Image #6
Architectist-0018.jpg
Copyright © 2010 Frank Cunha III

Sincerely,
Frank Cunha III – Architect & Visual Artist

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Recording Device (Part 1)

The Architectist Records the City.


Recording Device, NYC Pier (1996) (This project was about recording an “image” or in my case “movement” and “image.” After visiting the given site and completing a thorough analysis of how a photographic lenses and shutter work, the idea that evolved was to record the movement of the adjacent traffic. The movement (speed and weight) of the passing automobiles and other vehicles that drive over the adjacent roadway would be translated to the recording device in the Hudson River which would in turn sculpt the pier accordingly. These are slides taken by the professor of the models I built to fit into the class site model.)

Recording Device, Image #1
Architectist-0014.jpg
Copyright © 2010 Frank Cunha III


Recording Device, Image #2
Architectist-0015.jpg
Copyright © 2010 Frank Cunha III

Recording Device, Image #3
Architectist-0016.jpg
Copyright © 2010 Frank Cunha III

Sincerely,
Frank Cunha III – Architect & Visual Artist

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21 Improvements in Technology Architects Can Expect by 2030 #Innovation #Technology #ilmaBlog

  1. 90% of the population will have unlimited and free data storage.
  2. The first robotic pharmacist will arrive in the US.
  3. 1 trillion sensors will be connected to the internet.
  4. 10% of the world’s population will be wearing clothes connected to the internet.
  5. The first 3D printed car will be in production.
  6. The first implantable mobile phone will become commercially available.
  7. It is likely we will see more widespread adoption of implantable technologies emerge.
  8. The first government to replace its census with big-data technologies.
  9. 10% of reading glasses will be connected to the internet.
  10. 80% of people on earth will have a digital presence online.
  11. A government will collect taxes for the first time via blockchain. 10% of global gross domestic product will be stored using blockchain technology.
  12. 90% of the global population will have a supercomputer in their pocket.
  13. Access to the Internet will become a basic right.
  14. The first transplant of a 3D printed liver will occur.
  15. More than 50% of Internet traffic to homes will be from appliances and device.
  16. 5% of consumer products will be 3D printed.
  17. 30% of corporate audits will be performed by artificial intelligence.
  18. AI will increasingly replace a range of jobs performed by people today, including white collar jobs.
  19. Globally, more trips will be made using car sharing programs than privately owned cars. Driverless cars will account for 10% of all cars in the US.
  20. The first AI machine will join a corporate board of directors.
  21. The first city with more than 50,000 people and no traffic lights will come into existence.

Sources:

We would love to hear from you about what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook


What Will Higher Education Look Like 5, 10 or 20 Years From Now? Some Ways Colleges Can Reinvent Themselves #iLMA #eMBA #Innovation #Technology #Planning #Design #HigherEducation #HigherEd2030 #University #Architect

Introduction

Change is a natural and expected part of running a successful organization. Whether big or small, strategic pivots need to be carefully planned and well-timed. But, how do you know when your organization is ready to evolve to its next phase? Anyone that listens, watches, or reads the news knows about the rising cost of higher education and the increasing debt that education is putting on students and alumni and their families.

At a time when education is most important to keep up with increasing technological changes, institutions need to pivot or face imminent doom in an ever increasing competitive environment. Competition can come from startups or external factors in the higher education market therefore it is increasingly necessary for institutions of higher learning to take a different approach to their business operations.

This post will focus on:

  • Current Trends
  • Demographic Shifts
  • Future of Higher Education (and impacts on University Facilities & Management)
    • Changing Assumptions
    • Implications for the Physical Campus
    • Changing Trajectory
    • More Trends in Higher Education (Towards 2030)
  • Driving Technologies
  • External Forces

Current Trends

  • Online education[i] has become an increasingly accepted option, especially when “stackable” into degrees.
  • Competency-based education lowers costs and reduces completion time for students.
  • Income Share Agreements[ii] help students reduce the risk associated with student loans.
  • Online Program Manager organizations benefit both universities and nontraditional, working-adult students.
  • Enterprise training companies are filling the skills gap by working directly with employers.
  • Pathway programs facilitate increasing transnational education[iii], which serves as an additional revenue stream for universities.

Demographic Shifts

According to data from the National Clearinghouse and the Department of Education[iv]:

  • The Average Age of a College/University Student Hovers Around Twenty-Seven (Though That Is Decreasing as The Economy Heats Up)
  • 38% of Students Who Enrolled In 2011 Transferred Credits Between Different Institutions At Least Once Within Six Years.
  • 38% of Students Are Enrolled Part-Time.
  • 64% of Students Are Working Either Full-Time or Part-Time.
  • 28% of Students Have Children of Their Own or Care For Dependent Family Members.
  • 32% of Students Are from Low-Income Families.
  • The Secondary Education Experience Has an Increasingly High Variation, Resulting In Students Whose Preparation For College-Level Work Varies Greatly.

Future of Higher Education (and impacts on University Facilities & Management)

The future of higher education depends on innovation. 

University leaders who would risk dual transformation are required to exercise full commitment to multiple, potentially conflicting visions of the future. They undoubtedly confront skepticism, resistance, and inertia, which may sway them from pursuing overdue reforms.[v]

Change is upon us.

“All universities are very much struggling to answer the question of: What does [digitization[vi]] mean, and as technology rapidly changes, how can we leverage it?” . . . . Colleges afraid of asking that question do so at their own peril.”[vii]

James Soto Antony, the director of the higher-education program at Harvard’s graduate school of education.

Changing Assumptions

Until recently the need for a physical campus was based on several assumptions:

  • Physical Class Time Was Required
  • Meaningful Exchanges Occurred Face to Face
  • The Value of an Institution Was Tied to a Specific Geography
  • Books Were on Paper
  • An Undergraduate Degree Required Eight Semesters
  • Research Required Specialized Locations
  • Interactions Among Students and Faculty Were Synchronous

Implications for the Physical Campus

  • Learning – Course by course, pedagogy is being rethought to exploit the flexibility and placelessness of digital formats while maximizing the value of class time.
  • Libraries – Libraries are finding the need to provide more usable space for students and faculty.  Whether engaged in study, research or course projects, the campus community continues to migrate back to the library.
  • Offices – While the rest of North America has moved to mobile devices and shared workspaces, academic organizations tend to be locked into the private, fixed office arrangement of an earlier era – little changed from a time without web browsers and cell phones. 
  • Digital Visible – From an institutional perspective, many of the implications of digital transformation are difficult to see, lost in a thicket of business issues presenting themselves with increasing urgency. 

Changing Trajectory

University presidents and provosts are always faced with the choice of staying the course or modifying the trajectory of their institutions.  Due to failing business models, rapidly evolving digital competition and declining public support, the stakes are rising.  All should be asking how they should think about the campus built for the 21st century.[viii]  J. Michael Haggans[ix] makes the following recommendations:

  • Build no net additional square feet
  • Upgrade the best; get rid of the rest
  • Manage space and time; rethink capacity
  • Right-size the whole
  • Take sustainable action
  • Make campus matter

More Trends in Higher Education (Towards 2030)

  • The Rise of The Mega-University[x]
  • ; Public Private Partnerships (P3’s) Procurement Procedures Will Become More Prevalent
  • More Colleges Will Adopt Test-Optional Admissions
  • Social Mobility Will Matter More in College Rankings
  • Urban Colleges Will Expand[xi] — But Carefully
  • Financial Crunches Will Force More Colleges to Merge
  • The Traditional Textbook Will Be Hard to Find; Free and Open Textbooks
  • More Unbundling and Micro-Credentials
  • Continued Focus on Accelerating Mobile Apps
  • Re-Imagining Physical Campus Space in Response to New Teaching Delivery Methods
  • Transforming the Campus into A Strategic Asset with Technology
  • Education Facilities Become Environmental Innovators
  • Ethics and Inclusion: Designing for The AI Future We Want to Live In
  • Visibility (Transparency) And Connectedness
  • Sustainability from Multiple Perspectives
  • Better Customer Experiences with The Digital Supply Chain
  • Individualized Learning Design, Personalized Adaptive Learning
  • Stackable Learning Accreditation
  • Increased Personalization: More Competency-Based Education They’ll Allow Students to Master A Skill or Competency at Their Own Pace.
  • Adaptation to Workplace Needs They’ll Adapt Coursework to Meet Employer Needs for Workforce Expertise
  • Greater Affordability and Accessibility They’ll Position Educational Programs to Support Greater Availability.
  • More Hybrid Degrees[xii]
  • More Certificates and Badges, For Example: Micro-Certificates, Offer Shorter, More Compact Programs to Provide Needed Knowledge and Skills Fast[xiii]
  • Increased Sustainable Facilities – Environmental Issues Will Become Even More Important Due to Regulations and Social Awareness; Reduced Energy Costs, Water Conservation, Less Waste
  • Health & Wellness – Physical, Spiritual and Metal Wellbeing
  • Diversity and Inclusion Will Increase
  • Rise of The Micro-Campus[xiv] And Shared Campuses[xv]
  • E-Advising to Help Students Graduate
  • Evidence-Based Pedagogy
  • The Decline of The Lone-Eagle Teaching Approach (More Collaboration)
  • Optimized Class Time (70% Online, 30% Face to Face)
  • Easier Educational Transitions
  • Fewer Large Lecture Classes
  • Increased Competency-Based and Prior-Learning Credits (Credit for Moocs or From “Real World” Experience)[xvi]
  • Data-Driven Instruction
  • Aggressive Pursuit of New Revenue
  • Online and Low-Residency Degrees at Flagships
  • Deliberate Innovation, Lifetime Education[xvii]
  • The Architecture of The Residential Campus Will Evolve to Support the Future.
  • Spaces Will Be Upgraded to Try to Keep Up with Changes That Would Build In Heavy Online Usage.
  • Spaces Will Be Transformed and Likely Resemble Large Centralized, Integrated Laboratory Type Spaces. 
  • Living-Learning Spaces in Combination Will Grow, But On Some Campuses, Perhaps Not In The Traditional Way That We Have Thought About Living-Learning To Date.

Driving Technologies:

  • Emerging Technologies – Such as Augmented Reality, Virtual Reality, And Artificial Intelligence – Will Eventually Shape What the Physical Campus Of The Future Will Look Like, But Not Replace It.[xviii]
  • Mobile Digital Transformation[xix]
  • Smart Buildings and Smart Cities[xx]
  • Internet of Things
  • Artificial Intelligence (AI), Including Natural Language Processing
  • Automation (Maintenance and Transportation Vehicles, Instructors, What Else?)
  • Virtual Experience Labs, Including: Augmented Reality, Virtual Reality Learning, And Robotic Telepresence 
  • More Technology Instruction and Curricula Will Feature Digital Tools and Media Even More Prominently
  • New Frontiers For E-Learning, For Example, Blurred Modalities (Expect Online and Traditional Face-To-Face Learning to Merge)[xxi]
  • Blending the Traditional; The Internet Will Play Bigger Role in Learning
  • Big Data: Colleges Will Hone Data Use to Improve Outcomes

External Forces:

  • [xxii]: Corporate Learning Is A Freshly Lucrative Market
  • Students and Families Will Focus More on College Return On Investment, Affordability And Student Loan Debt
  • [xxiii]
  • Greater Accountability; Schools will be more accountable to students and graduates
  • Labor Market Shifts and the Rise of Automation
  • Economic Shifts and Moves Toward Emerging Markets
  • Growing Disconnect Between Employer Demands and College Experience 
  • The Growth in Urbanization and A Shift Toward Cities 
  • Restricted Immigration Policies and Student Mobility
  • Lack of Supply but Growth in Demand
  • The Rise in Non-Traditional Students 
  • Dwindling Budgets for Institutions[xxiv]
  • Complex Thinking Required Will Seek to Be Vehicles of Societal Transformation, Preparing Students to Solve Complex Global Issues

Sources & References:


[i] Online education is a flexible instructional delivery system that encompasses any kind of learning that takes place via the Internet. The quantity of distance learning and online degrees in most disciplines is large and increasing rapidly.

[ii] An Income Share Agreement (or ISA) is a financial structure in which an individual or organization provides something of value (often a fixed amount of money) to a recipient who, in exchange, agrees to pay back a percentage of their income for a fixed number of years.

[iii] Transnational education (TNE) is education delivered in a country other than the country in which the awarding institution is based, i.e., students based in country Y studying for a degree from a university in country Z.

[iv] Article accessed on April 16, 2019: https://er.educause.edu/articles/2019/3/changing-demographics-and-digital-transformation

[v]Article accessed on April 16, 2019: https://ssir.org/articles/entry/design_thinking_for_higher_education

[vi] Digitization is the process of changing from analog to digital form.

[vii] Article accessed on April 16, 2019:  https://qz.com/1070119/the-future-of-the-university-is-in-the-air-and-in-the-cloud

[viii] Article accessed on April 16, 2019: http://c21u.gatech.edu/blog/future-campus-digital-world

[ix] Michael Haggans is a Visiting Scholar in the College of Design at the University of Minnesota and Visiting Professor in the Center for 21st Century Universities at Georgia Institute of Technology.  He is a licensed architect with a Masters of Architecture from the State University of New York at Buffalo.  He has led architectural practices serving campuses in the US and Canada, and was University Architect for the University of Missouri System and University of Arizona.

[x] Article accessed on April 16, 2019:  https://www.chronicle.com/interactives/Trend19-MegaU-Main

[xi] Article accessed on April 16, 2019:  https://www.lincolninst.edu/sites/default/files/pubfiles/1285_wiewel_final.pdf

[xii] Article accessed on April 16, 2019: https://www.fastcompany.com/3046299/this-is-the-future-of-college

[xiii] Article accessed on April 16, 2019: https://www.govtech.com/education/higher-ed/Why-Micro-Credentials-Universities.html

[xiv] Article accessed on April 16, 2019: https://global.arizona.edu/micro-campus

[xv] Article accessed on April 16, 2019: https://evolllution.com/revenue-streams/global_learning/a-new-global-model-the-micro-campus

[xvi] Article accessed on April 16, 2019:  https://www.chronicle.com/article/The-Future-Is-Now-15/140479

[xvii] Article accessed on April 16, 2019:  https://evolllution.com/revenue-streams/market_opportunities/looking-to-2040-anticipating-the-future-of-higher-education

[xviii] Article accessed on April 16, 2019: https://www.eypae.com/publication/2017/future-college-campus

[xix] Article accessed on April 16, 2019: https://edtechmagazine.com/higher/article/2019/02/digital-transformation-quest-rethink-campus-operations

[xx] Article accessed on April 16, 2019: https://ilovemyarchitect.com/?s=smart+buildings

[xxi] Article accessed on April 16, 2019: https://www.theatlantic.com/education/archive/2018/04/college-online-degree-blended-learning/557642

[xxii] Article accessed on April 16, 2019: https://qz.com/1191619/amazon-is-becoming-its-own-university

[xxiii] Article accessed on April 16, 2019: https://www.fastcompany.com/3029109/5-bold-predictions-for-the-future-of-higher-education

[xxiv] Article accessed on April 16, 2019: https://www.acenet.edu/the-presidency/columns-and-features/Pages/state-funding-a-race-to-the-bottom.aspx

We would love to hear from you about what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook


Augmented Reality Enables Children to Learn in the Real World #ilmaBlog #Education #VR #Technology #Classroom #MyUniversityArchitect #Architect

MBDs (Mobile broadband devices, or smartphones) allow students to access and collect additional information and clues. Students use EcoMOBILE activities developed with an augmented reality application, to navigate between “hotspots,” view information, answer questions, and observe virtual media overlaid on the physical pond.

Students can capture pictures, video, or voice recordings and take these back to the classroom to help make sense of school lessons. Through augmented reality we provide students with visualizations that would not otherwise be apparent in the natural environment (for example, virtual x-ray vision so that they can “see” a virtual carbon atom as it moves through the processes of photosynthesis and respiration).

These augmented reality experiences allow students to conceptualize and discuss processes and complex relationships that are otherwise difficult to describe or visualize.

We would love to hear from you about what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook


13 Examples of Green Architecture

The Morris & Gwendolyn Cafritz Foundation Environmental Center

The nickname for the Morris and Gwendolyn Cafritz Foundation Environmental Center is the Grass Building, and it perfectly captures its spirit. It’s a structure so thoughtfully designed it’s almost as energy-efficient and low impact as the greenery that surrounds it.

The Maryland building is part of an educational farm on the Potomac River Watershed that the Alice Ferguson Foundation used to teach people about the natural world. This new building—which became the 13th in the world to receive full Living Building Challenge certification in June 2017—is an educational facility designed to blur the lines between indoors and out, while still providing shelter as needed. “Part of the intent of the building is to be in the landscape and still have a bathroom to use,” says Scott Kelly, principal-in-charge at Re:Vision, a Philadelphia-based architecture and design studio.

Further Reading:
https://gbdmagazine.com/2017/grass-building
https://www.aia.org/showcases/92581-the-morris–gwendolyn-cafritz-foundation-env
https://living-future.org/lbc/case-studies/morris-gwendolyn-cafritz-foundation-environmental-center
http://hughloftingtimberframe.com/gallery/commercial/cafritz-foundation-environmental-center
http://www.cafritzfoundation.org/

Brock Environmental Center

Drawing thousands of students, the Brock Environmental Center is a regional hub for the Chesapeake Bay Foundation, in Virginia Beach, Virginia, supporting its education and wetlands restoration initiatives. A connection to nature defines the building’s siting, which provides sweeping views of the marsh and also anticipates sea-level rise and storm surges with its raised design. Parts were sourced from salvage: Its maple floors once belonged to a local gymnasium while school bleachers, complete with graffiti, were used for interior wood trim. The center was recognized for its positive footprint: It has composting toilets, captures and treats rainfall for use as drinking water, and produces 80 percent more energy than it uses, selling the excess to the grid.

Further Reading:
http://www.cbf.org/about-cbf/locations/virginia/facilities/brock-environmental-center
https://living-future.org/lbc/case-studies/the-chesapeake-bay-brock-environmental-center
https://www.visitvirginiabeach.com/listing/chesapeake-bay-foundations-brock-environmental-center/979
https://www.aia.org/showcases/76311-brock-environmental-center

Discovery Elementary School

Students have three distinct, age-appropriate playgrounds—with natural elements such as rocks and fallen trees—at Arlington, Virginia’s Discovery Elementary School. The name honors astronaut John Glenn, who returned to space on the Discovery shuttle and once lived in the neighborhood. Exploration is a theme at the school, whose interior focuses on forests, oceans, atmosphere, and the solar system. The largest zero-energy school in the country, it offers “hands-on learning around energy efficiency and generation,” jurors noted. The school maximizes natural light and provides views to the outside in all classrooms.

Further Reading:
https://www.aia.org/showcases/71481-discovery-elementary-school-
https://www.aiadc.com/sites/default/files/031%20-%20DiscoveryElementarySchool.pdf
https://www.google.com/search?q=Discovery+Elementary+School+AIA&tbm=isch&tbo=u&source=univ&sa=X&ved=0ahUKEwjS-pnHo6LcAhUMON8KHSlUDlYQsAQIdA&biw=1583&bih=1187

Bristol Community College

A laboratory is an energy-intensive enterprise, with specialized lighting and ventilation needs. That’s why jurors praised the airy health and science building at Bristol Community College, in Fall River, Massachusetts, for its net-zero energy achievement, “a difficult feat,” they noted, “in a cold climate like New England’s.” The move saves $103,000 in annual operating costs and allows the college, which offers a suite of courses in sustainability and energy, to practice what it teaches. Part of a holistic campus redesign, the new building’s location increases the density—and thus walkability—of campus for students.

Further Reading:
https://www.aia.org/showcases/71576-bristol-community-college-john-j-sbrega-heal
https://www.mass.gov/service-details/bristol-community-college-john-j-sbrega-health-and-science-building
http://www.architectmagazine.com/project-gallery/bristol-community-college-john-j-sbrega-health-and-science-building_o

Central Energy Facility

Orange and red pipes flaunt their role in “heat recovery” at Stanford University’s Central Energy Facility. The center for powering the California campus—more than a thousand buildings—the facility was transformed from an aging gas-fired plant to one fueled mostly by an off-site solar farm, fulfilling a goal of carbon neutrality and reducing energy use by a third. With large health care and research buildings, the campus needs as much heating as cooling; now a unique recovery system taps heat created in cooling processes to supply 93 percent of the heating and hot water required for campus buildings. The plant reduces Stanford emissions by 68 percent and potable water usage by 18 percent, potentially saving millions of dollars and one of the state’s scarce resources.

Further Reading:
https://www.aia.org/showcases/25976-stanford-university-central-energy-facility
https://sustainable.stanford.edu/new-system
https://www.archdaily.com/786168/stanford-university-central-energy-facility-zgf-architects
https://www.zgf.com/project/stanford-university-central-energy-facility

Ng Teng Fong General Hospital

Like other buildings in Singapore, Ng Teng Fong General Hospital incorporates parks, green roofs, and vertical plantings throughout its campus. But the city-state’s hospitals haven’t traditionally offered direct access to fresh air, light, and outdoor views. This hospital marks a dramatic change, optimizing each for patients. About 70 percent of the facility is naturally ventilated and cooled by fans, cross-ventilation, and exterior shading, saving on precious water resources. The building uses 38 percent less energy than a typical hospital in the area.

Further Reading:
https://www.aia.org/showcases/76821-ng-teng-fong-general-hospital–jurong-commun
http://www.hok.com/about/news/2017/07/25/ng_teng_fong_general_international_academy_for_design_and_health_awards
https://www.archdaily.com/869556/aia-selects-top-10-most-sustainable-projects-of-2017/58f7c23ce58eceac31000615-aia-selects-top-10-most-sustainable-projects-of-2017-photo
http://www.topicarchitecture.com/articles/154396-how-modern-hospitals-recognize-the-impact-o

Eden Hall Farm, Chatham University

After receiving the donation of 388-acre Eden Hall Farm, 20 miles north, Pittsburgh’s Chatham University created a satellite campus centered around a sustainable living experiment. The university views the landscape—an agricultural area adjacent to an urban center—as critical to supporting cities of the future. The original buildings are complemented by new facilities for 250 residential students (and eventually 1,200), including a dormitory, greenhouse, dining commons, and classrooms. Students get hands-on experience in renewable energy systems—the campus generates more than it uses—sustainable agriculture and aquaculture, waste treatment, and water management. Now home to the Falk School of Sustainability, the farm is producing the next generation of environmental stewards, who follow in the footsteps of alum Rachel Carson.

Further Reading:
https://www.aia.org/showcases/76481-chatham-university-eden-hall-campus
http://www.chatham.edu/news/index.php/2018/01/chatham-views/from-eden-hall-pioneer-to-farm-manager
https://www.archdaily.com/869556/aia-selects-top-10-most-sustainable-projects-of-2017
https://falk.chatham.edu/masterplan.cfm

Milken Institute School of Public Health, George Washington University

At George Washington University’s Milken Institute School of Public Health, located in the nation’s capital, design embodies well-being. Built around an atrium that admits light and air, the structure encourages physical activity with a staircase that spans its eight levels. A green roof reduces storm runoff; rainwater is collected and stored for plumbing, resulting in a 41 percent reduction in toilet fixtures’ water use. Limestone panels (left) were salvaged from the previous building on the site. Materials used throughout the building contain recycled content.

Further Reading:
https://www.aia.org/showcases/71306-milken-institute-school-of-public-health
https://publichealth.gwu.edu/content/milken-institute-school-public-health-wins-excellence-architecture-new-building-merit-award
http://designawards.architects.org/projects/honor-awards-for-design-excellence/milken-institute-school-of-public-health-george-washington-university/

National Oceanic and Atmospheric Administration’s Inouye Regional Center

Located at the heart of Pearl Harbor, on Oahu’s Ford Island, the National Oceanic and Atmospheric Administration’s Inouye Regional Center repurposed two airplane hangars—which narrowly escaped destruction in the 1941 attack—linking them with a new steel and glass building (right). The research and office facility for 800 employees was raised to guard it from rising sea levels. Given the size of the hangars, daylight illuminated only a small fraction of the space, so specially crafted lanterns reflect sunlight further into their interiors. Necessity required invention: Due to anti-terrorism regulations, no operable windows were allowed in the space. Through a passive downdraft system that taps prevailing sea breezes, the building is completely naturally ventilated. The adjacent waterfront was returned to a more natural state with native vegetation.

Further Reading:
https://www.aia.org/showcases/76911-noaa-daniel-k-inouye-regional-center
http://www.hpbmagazine.org/NOAA-Daniel-K-Inouye-Regional-Center-Honolulu-Hawaii/
http://www.architectmagazine.com/project-gallery/noaa-daniel-k-inouye-regional-center_o
http://www.hok.com/design/type/government/national-oceanic-and-atmospheric-administration-noaa/

R.W. Kern Center

Serving as the gateway to Hampshire College, in Amherst, Massachusetts, the multipurpose R.W. Kern Center holds classrooms, offices, a café, and gallery space—and is the place where prospective students are introduced to campus. The school converted what was once an oval driveway into a wildflower meadow, now encouraging a pedestrian approach (seen above). The center is self-sustaining, generating its own energy through a rooftop solar array, harvesting its water from rainfall, and processing its own waste. Its gray water treatment system is in a pilot program for the state, and may pave the way for others.

Further Reading:
https://www.aia.org/showcases/76921-rw-kern-center
https://architizer.com/projects/rw-kern-center
https://www.hampshire.edu/discover-hampshire/rw-kern-center

Manhattan 1/2/5 Garage & Salt Shed

Two buildings belonging to New York City’s sanitation department redefine municipal architecture. Resembling a grain of salt, the cubist form of the Spring Street Salt Shed holds 5,000 tons for clearing icy streets. The Manhattan 1/2/5 Garage (background), whose floors are color-coded for each of the three districts, is home to 150 vehicles, wash and repair facilities, and space for 250 workers. The garage is wrapped in 2,600 aluminum “fins,” shading devices that pivot with the sun’s rays, reducing heat gain and glare through the glazed walls while still allowing views to the outside. Municipal steam heats and cools the building, so no fuels are burned. A 1.5-acre green roof reduces heat-island effect and filters rainwater. A condensate by-product of the steam is also captured, and, along with the rainwater, used for toilets and the truck wash. Combined with low-flow fixtures, the process reduced water consumption by 77 percent.

Further Reading:
https://www.dattner.com/portfolio/manhattan-districts-125-garage/
https://www.ohny.org/site-programs/weekend/sites/dsny-manhattan-125-sanitation-garage-salt-shed
https://www.aia.org/showcases/76671-manhattan-districts-125-garage–spring-stree
http://www.architectmagazine.com/project-gallery/manhattan-districts-1-2-5-garage-spring-street-salt-shed_o
https://www.burns-group.com/project/manhattan-125-garage-and-spring-street-salt-shed/

Starbucks Hillsboro, Oregon

Starbucks has been a leader in the development and implementation of a scalable green building program for over a decade .Starbucks joined the U.S. Green Building Council® (USGBC) in 2001 and collaborated with them to develop the LEED® for Retail program, an effort to adapt LEED (Leadership in Energy and Environmental Design) to new construction and commercial interior strategies for retail businesses. In 2008,Starbucks challenged themselves to use LEED certification not just for flagship stores and larger buildings, but for all new, company-operated stores. Many people, even internally, were skeptical, especially with Starbucks growth across the globe. But by collaborating with USGBC and other like-minded organizations, we have been able to integrate green building design not only into new stores but also into our existing store portfolio. Starbucks has also succeeded in providing a practical certification option for retailers of all sizes.

Further Reading:
https://www.starbucks.com/responsibility/environment/leed-certified-stores

The Edge, Deloitte

The Edge, located in Amsterdam, is a model of sustainability.is billed as the world’s most sustainable office building and has the certification to prove it. But, it’s more than that. The place is, well, fun. And interesting. And inviting. So much so that professionals are actually applying for employment with Deloitte Netherlands because they want to work in the building. That it has become a recruiting tool is a satisfying side effect of a project designed to both redefine efficiency and change the way people work. “We wanted to ensure that our building not only had the right sustainability credentials, but was also a real innovative and inspiring place for our employees,” says Deloitte Netherlands CEO Peter Bommel.

Read the rest of this entry »


Connected Spaces

Connected-Life

The internet of things, or IoT, is a system of interrelated computing devices, mechanical and digital machines, objects, animals or people that are provided with unique identifiers and the ability to transfer data over a network without requiring human-to-human or human-to-computer interaction.

Connected spaces are networked to enable the interconnection and interoperability of multiple devices, services and apps, ranging from communications and entertainment to healthcare, security and home automation. These services and apps are delivered over multiple interlinked and integrated devices, sensors, tools and platforms. Connected, real-time, smart and contextual experiences are provided for the household inhabitants, and individuals are enabled to control and monitor the home remotely as well as within it.

Connected-HomeThe technologies behind connected spaces can be grouped in the following categories:

  • Networking: Familiar networking technologies (high bandwidth/high power consumption), such as Multimedia over Coax Alliance (MoCA), Ethernet, Wi-Fi, Bluetooth, as well as 3G and Long Term Evolution (LTE), are complemented with low-power consumption networking standards for devices and sensors that require low bandwidth and consume very little power, such as thermostats.
  • Media and Entertainment: This category, which covers integrated entertainment systems and includes accessing and sharing digital content across different devices, has proved to be the most prolific and contains some of the most mature technologies in the connected home.
  • Security, Monitoring and Automation: The technologies in this category cover a variety of services that focus on monitoring and protecting the home as well as the remote and automated control of doors, windows, blinds and locks, heating/air conditioning, lighting and home appliances, and more.
  • Energy Management: This category is tightly linked to smart cities and government initiatives, yet consumer services and devices/apps are being introduced at mass-market prices that allow people to track, control and monitor their gas/electricity consumption.
  • Healthcare, Fitness and Wellness: Solutions and services around healthcare have proven slow to take off, because they have to be positioned within a health plan and sold to hospitals and health insurance companies. The fitness and wellness segment has strong and quickly developed ecosystems that range from devices to sports wares to apps, which integrate seamlessly with each other to create a strong customer experience.

(Source: https://www.gartner.com)

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

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FRANK CUNHA III
I Love My Architect – Facebook


Benefits of Using Digital Twins for Construction

Technologies like augmented reality in construction are emerging to digitalize the construction industry, making it significantly more effective.

What if we could have instant access to all the information about a construction site, down to smallest details about every person, tool, and bolt? What if we could always be sure about the final measurements of a beam or that soil volumes in the cuts are close to those of the fills? What if we could always track how fast the supply of materials runs out, and re-order supplies automatically?

All this is achievable with a digital twin — a concept of having a real-time digital representation of a physical object.

The following are some real-time digital twins applications on construction sites.

3d-model

Automated Progress Monitoring

Progress monitoring verifies that the completed work is consistent with plans and specifications. A physical site observation is needed in order to verify the reported percentage of work done and determine the stage of the project.

By reconstructing an as-built state of a building or structure we can compare it with an as-planned execution in BIM and take corresponding actions to correct any deviations. This is usually done by reconstructing geometry of a building and registering it to the model coordinate systems, which is later compared to an as-planned model on a shape and object level.

Often data for progress monitoring is collected through the field personnel and can be hugely subjective. For example, the reported percentage of work done can be faster in the beginning and much slower close to the end of the project. People are often initially more optimistic about their progress and the time needed to finish the job.

Hence, having automated means of data collection and comparison means that the resulting model to as-designed BIM models is less liable to human error. Digital twins solve the common construction process problems.

As-Built vs As-Designed Models

With a real-time digital twins, it is possible to track changes in an as-built model — daily and hourly. Early detection of any discrepancies can lead to a detailed analysis of historical modeling data, which adds an additional layer of information for any further decision-making processes.

The project manager can then reconstruct the steps that led to the error and make changes in the future work schedule in order to prevent any similar mistakes from occurring. They can also detect under-performers and try to fix the cause of the problem earlier in the project or plan the necessary changes to the budget and timescale of the whole project.

Resource Planning and Logistics

According to the Construction Industry Institute, about 25% of productive time is wasted on unnecessary movement and handling of materials.

Digital twin technology provides automatic resource allocation monitoring and waste tracking, allowing for a predictive and lean approach to resource management. With digital twin technology companies would avoid over-allocation and dynamically predict resource requirements on construction sites, thus avoiding the need to move resources over long distances and improving time management.

Safety Monitoring

The construction industry is one of the most dangerous sectors in the world. According to the Bureau of Labor Statistics in the United States, more than four thousand construction workers died on-site between 2008 and 2012.

The real-time site reconstruction feature digital twins allows the industry’s companies to track people and hazardous places on a site, so as to prevent inappropriate behavior, usage of unsafe materials, and activity in hazardous zones. A company can develop a system of early notification, letting a construction manager know when a field worker is located in dangerous proximity to working equipment and sending a notification about nearby danger to a worker’s wearable device.

Microsoft recently shared a great vision of how AI combined with video cameras and mobile devices can be used to build an extensive safety net for the workplace.

Quality Assessment

Image-processing algorithms make it possible to check the condition of concrete through a video or photographic image. It is also possible to check for cracks on columns or any material displacement at a construction site. This would trigger additional inspections and thus help to detect possible problems early on.

See an example of how 2D images using 3D scene reconstruction can be used for concrete crack assessments.

Optimization of Equipment Usage

Equipment utilization is an important metric that construction firms always want to maximize. Unused machines should be released earlier to the pool so others can use them on other sites where they are needed. With advanced imaging and automatic tracking, it is possible to know how many times each piece of machinery has been used, at what part of the construction site, and on what type of the job.

Monitoring and Tracking of Workers

Some countries impose tough regulations on how to monitor people presence on a construction site. This includes having a digital record of all personnel and their location within the site, so that this information could be used by rescue teams in case of emergency. This monitoring is another digital twins application. Still, it is better to integrate digital twin-based monitoring with an automatic entry and exit registration system, to have a multi-modal data fused into a single analytics system.

Getting Data for Digital Twins

Some ways to gather data to be used for digital twins includes the following:

  1. Smartphone Cameras
  2. Time-Lapse Cameras
  3. Autonomous UAV and Robots
  4. Video Surveillance Cameras
  5. Head-mounted Cameras and Body Cameras

Image data processing algorithms for digital twins can be created with the following methods:

  1. 3D Reconstruction: Conventional Photogrammetry
  2. 3D Reconstruction: Structure from Motion
  3. Object Detection and Recognition
  4. Localization
  5. Object Tracking

(Source: https://www.intellectsoft.net/blog/advanced-imaging-algorithms-for-digital-twin-reconstruction)

From an Investor’s Viewpoint

On projects to date, this approach has proven to save time, reduce waste and increase efficiencies.

From a Standardization Proponent’s Viewpoint

Open, sharable information unlocks more efficient, transparent and collaborative ways of working throughout the entire life-cycle of buildings and infrastructure.

From a Solution Provider’s Viewpoint 

While the digital twin is needed initially for planning and construction, it’s also intended to provide the basis for building operations moving forward.

(Source: https://www.siemens.com/customer-magazine/en/home/buildings/three-perspectives-on-digital-twins.html)

The vision of “construction 4.0” refers to the 4th industrial revolution and is a fundamental challenge for the construction industry. In terms of automated production and level of digitalization, the construction industry is still significantly behind other industries. Nevertheless, the mega-trends like Big Data or the Internet of Things offer great opportunities for the future development of the construction sector. Prerequisite for the successful Construction 4.0 is the creation of a digital twin of a building. Building Information Modeling (BIM) with a consistent and structured data management is the key to generate such a digital building whose dynamic performance can be studied by building simulation tools for a variety of different boundary conditions.

Along the total life cycle from design to construction, operation and maintenance towards remodeling or demolition, the digital twin follows all modifications of the real building and dynamically readjusts itself in case of recorded performance differences.

Thus, for the whole life span of the real building, performance predictions generated with the virtual twin represent an accurate basis for well-informed decisions. This helps to develop cost-effective operation modes, e.g. by introducing new cyber-controlled HVAC systems. The digital twin may also analyze the building’s dynamic response to changes in occupation or energy supply; it also indicates the need for building maintenance or upgrades.

The digital twin follows all modifications of the real building and dynamically readjusts itself in case of recorded performance differences.

(Source: https://www.bau.fraunhofer.de/en/fieldsofresearch/smartbuilding/digital-twin.html)

Gartner-digital-twin-best-practices-to-tackle-challenges

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook


Drone Technology

Drone-Technology-02Drones—also called unmanned aerial vehicles (UAVs) or unmanned aerial systems (UAS)—are most simply described as flying devices that do not carry a human pilot. They can be remotely piloted or they can pilot themselves based on pre-programmed instructions. They can be equipped with GPS, on board computers, hardware, electronics, sensors, stabilizers, auto-pilots, servo controllers, and any other equipment the user desires to install. Drones can resemble fixed-wing airplanes but more commonly take the form of quad-copters, that is, rotor-wing aircraft that can take off and land vertically. Most people know that drones can be equipped with infra-red cameras (still and video), license-plate readers, “ladar” (laser radar that generate three-dimensional images and can be seen through trees and foliage), thermal-imaging devices, or even sensors that gather data about weather, temperature, radiation or other environmental conditions. All of this can be used to generate images, recordings or data that design professionals eventually will want to use in their business.

Drones could be a valuable tool in construction, widening the spectrum of what’s possible in architecture, according to architect Ammar Mirjan.

“We can fly [drones] through and around existing objects, which a person couldn’t do or a crane couldn’t do,” explains Mirjan. They can be programmed to weave simple tensile structures in the air, for example.

Sources & References:

https://www.dezeen.com/2017/05/04/mark-dytham-interview-drones-uavs-bring-profound-change-architecture-cities/

http://www.theaiatrust.com/architects-guide-using-drones/

https://www.dezeen.com/2018/05/25/10-ways-drones-will-change-the-world/

How are aerial mapping drones helping architects?

Architects are exploring the many benefits of mapping drones for improving and expanding their businesses. Here are just a few examples:

The most popular application for small drones is aerial photography and video capture to track and share “before and after” progress over time.

Ability to securely collaborate on specific areas of interest with your team, contractors, and customers.

Tell the story of your project.  Show current and potential customers before and after fly-throughs of your job site so they can experience and appreciate the scale and impact of your work.

3-D point clouds with centimeter grade accuracy on progress, so you can get the precision updates you need to keep project approvals on time, without physically traveling to the site.

Get context for your project, plan your architecture with a full view of the surrounding area.

See 3D volumetrics so you know what you’re building on and can track progress.

Uses for Drones

  • Project documentation
  • Presentation + marketing
  • Architectural cinematography
  • Site analysis
  • Topographic mapping
  • Construction observation
  • Educational tool
  • Lead generation (working with Realtors)

Conclusion

According to an interview in Dezeen.com with Mark Dytham, architect and co-founder of Tokyo-based Klein Dytham Architecture, “Drones will transform the way buildings are designed, the way they look and the way they are used.

One way in which drones are proving to be a useful tool in architecture is through surveying. Due to their small size and relative ease of maneuverability, drones make an easy task of accessing difficult to reach places.

According to ArchDaily.com, “While using satellite imagery for site planning is common among architects, these visuals are often available in low resolution and produce less accurate data. Data collected by drones can completely eliminate the need for hiring land surveyors for creating topographic surveys. Instead, architects can use this information to build accurate 3D models of the terrain and site and import them directly into drafting and modeling software like Rhino.” In the past, architects would have relied on planes, helicopters, or satellite imaging for aerial footage.

Sources & References:

https://www.identifiedtech.com/blog/construction-drones/how-aerial-mapping-drones-can-help-architects/

http://residencestyle.com/the-use-of-drones-in-architecture-soars-to-new-heights/

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook


Immersive Experience in Architecture

VR-HeroPotential uses for VR and AR in architectural design are not science fiction fantasy.

New VR devices allow designers and clients inside conceptual designs. We simply load a VR device with a three-dimensional rendering of a space, and let the user experience it virtually. These VR experiences are far more effective than two-dimensional renderings at expressing the look and feel of a design. VR allows our clients to make better-educated assessments of the total sensory experience and the small details of our design. VR is helping us bridge the divide between our ideas and our clients’ perception of them, letting us effectively simulate our designs before a single nail is driven, part is molded or footing is poured. Our existing modeling programs let us render views in VR devices that are single point-of-view. The user gets to look around from that point and immerse themselves in 360-degree views. Needless to say, the ability to experience spaces before they’re paid for and built increases clients’ peace of mind about their investments.
(Source: https://www.archdaily.com/872011/will-virtual-reality-transform-the-way-architects-design)

While conversational interfaces are changing how people control the digital world,
virtual, augmented and mixed reality are changing the way that people perceive and
interact with the digital world. The virtual reality (VR) and augmented reality (AR) market is currently adolescent and fragmented. Interest is high, resulting in many novelty VR applications that deliver little real business value outside of advanced entertainment, such as video games and 360-degree spherical videos. To drive real tangible business benefit, enterprises must examine specific real-life scenarios where VR and AR can be applied to make employees more productive and enhance the design, training and visualization processes. (Source: https://www.gartner.com)
VR-Architect
Mixed reality, a type of immersion that merges and extends the technical functionality of
both AR and VR, is emerging as the immersive experience of choice providing a
compelling technology that optimizes its interface to better match how people view and
interact with their world. Mixed reality exists along a spectrum and includes head-
mounted displays (HMDs) for augmented or virtual reality as well as smartphone and
tablet-based AR and use of environmental sensors. Mixed reality represents the span of
how people perceive and interact with the digital world. (Source: https://www.gartner.com)

VR has already excelled in one area of the travel industry, in what’s been termed as ‘try
before you fly’ experiences – giving prospective tourists a chance to see their potential
destinations before booking their trip. Virgin Holidays have created Virgin Holidays
Virtual Holidays using VR and have seen a rise in sales to one of their key destinations.
In terms of creating these experiences from a design perspective, technology is both a
help and a hindrance. It’s allowing designers to get to know their audiences better, but
it’s also making it easier for businesses to lose track of the users who will eventually
own or experience the product. (Source: https://www.virgin.com/entrepreneur/how-internet-things-will-change-our-spaces)
VR-Virgin

Immersive Architecture

“Visualization matters. It’s really, really critical that people understand what they’re looking at and can contribute meaningfully to the dialogue. You want experts and non-experts to be able to derive actionable insight from what they’re seeing.”

–Matthew Krissel, Partner at KieranTimberlake

More Information:

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook

 


Big Data in Architecture

Big-Data-02Big data is a term that describes the large volume of data – both structured and unstructured – that inundates a business on a day-to-day basis. But it’s not the amount of data that’s important. It’s what organizations do with the data that matters. Big data can be analyzed for insights that lead to better decisions and strategic business moves.

(Source: https://www.sas.com/en_us/insights/big-data/what-is-big-data.html)

In buildings, data might be generated by a very wide variety of sources, including:

  • Design and construction (for example building information modeling)
  • Post occupancy evaluation
  • Utilities, building services, meters, building management systems and so on
  • Infrastructure and transport systems
  • Enterprise systems such as purchasing systems, performance reporting, work
    scheduling and so on
  • Maintenance and replacement systems
  • Operational cost monitoring
  • Information and Communications Technology (ICT) systems and equipment

Data from these sources can be used to understand behavior, assess
performance, improve market competitiveness, allocate resources and so on.
Smart buildings focus on the use of these interconnected technologies to make
buildings more intelligent and responsive, ultimately improving their performance, and
might include technologies such as:

  • Automated systems
  • Intelligent building management systems
  • Energy efficiency measures
  • Wireless technologies
  • Digital infrastructures
  • Adaptive energy systems
  • Networked appliances
  • Data gathering devices
  • Information and communications networks
  • Assistive technologies
  • Remote monitoring
  • Fault diagnostics and prognostics

(Source:https://medium.com/studiotmd/designing-with-data-8fd73345afb8)

Big-Data-01{Repost} How Big Data is Transforming Architecture

The phenomenon presents huge opportunities for the built environment and the firms that design it.

Clients are demanding data from architects

Clients are starting to ask architects to deliver more than just drawing sets. They are eyeing the data-rich BIM models that firms use to document projects as a way to supply data for downstream applications, such as facilities management.

With BIM achieving some level of maturity within the industry, there is a growing expectation that architects will produce datasets, such as the COBie (Construction-Operations Building Information Exchange) spreadsheet, as part of their regular deliverables. The COBie spreadsheet is essentially a list of building assets—such as chairs and HVAC systems—that the owner can then use to manage the facility. Next year, the U.K. government will require architects working on any publicly funded project to produce COBie spreadsheets. For architects, this means that their data needs to be as rigorous as their drawings.

Clients are demanding data from buildings

Clients have also become interested in the data generated by the buildings. As previously mentioned, everything from thermostats to doors is being connected to the Internet so it can broadcast its use. At last year’s Venice Biennale, the exhibition’s director Rem Koolhaas, Hon. FAIA, predicted that “every architectural element is about to associate itself with data-driven technology.”

This data enables building owners to measure and improve their facilities’ performance quantitatively. Many are already doing this—albeit in a limited sense—with their HVAC systems. But what we are seeing from innovative building owners is the use of data to conduct a holistic assessment of their performance. The Walt Disney Co., for example, combines location tracking with sales data and other user-experience metrics to optimize the performance of its parks. As more owners come to rely on building data to improve the performance of their assets, architects need to ensure that their buildings can supply this critical data.

Data is changing the process as much as it is changes the output

The abundance of data may give rise to data warehouses and COBie spreadsheets, but the much more profound changes for architects will be procedural. For instance, using BIM to design and document a building has required a whole new set of business processes. The building might be visually similar to what would have been designed in the past, but everything behind the scenes, from contract wording to staff training, needs to be rethought.

(Source: http://www.architectmagazine.com/technology/how-big-data-is-transforming-architecture_o)

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

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FRANK CUNHA III
I Love My Architect – Facebook


Architecture Robots

Environmental Robots

Robots Revolutionizing Architecture's Future 003

Robots are increasingly being utilized in everyday life to monitor and improve our environments. For example, Researchers from theNational University of Singapore have created a bevy of robotic swans that are designed to monitor the quality of freshwater lakes and reservoirs – such as levels of dissolved oxygen or chlorophyll – while blending in with the natural environment. The robotic birds, fitted with a number of sensors, autonomously swim across the water’s surface using underbody propellers.

(Source: https://www.dezeen.com/tag/robots/)

Robots in Construction

060306_040_ProduktionCurtainWal_SilvanOesterle_023

At ETH Zurich, Gramazio & Kohler, an architectural partnership that is especially
known for its contribution to digital fabrication and robotic construction, taught at class
using a robot arm to lay bricks. This is the course as they describe it:

“If the basic manufacturing conditions of architecture shift from manual work to digital
fabrication, what design potential is there for one of the oldest and most widespread
architectural elements — the brick? Students investigated this question in a four-week
workshop, designing brick walls to be fabricated by an industrial robot. Unlike a mason,
the robot has the ability to position each individual brick in a different way without optical reference or measurement, i.e. without extra effort. To exploit this potential, the students developed algorithmic design tools that informed the bricks of their spatial disposition according to procedural logics. Positioning this way it was possible to draft a brick wall in which each of over 400 bricks took up a specific position and rotation in space. The students defined not the geometry of the wall, but the constructive logic according to which the material was organized in a particular temporal order, and which thus produced an architectonic form.”

Though robot arms are currently the most prevalent form of robotics in architecture,
architects and designers have begun to employ other, and sometimes more radical,
robotic strategies for design. Gramazio & Kohler, in collaboration with Raffaello
d’Andrea recently put together an exhibition titled ‘Flight Assembled Architecture’ for
which small quad-rotor helicopter bots assembled a 6m-tall and 3.5m wide tower out of
1500 polystyrene foam blocks in Orléans, France.

(Source:https://www.archdaily.com/336849/5-robots-revolutionizing-architectures-future)

Robots Revolutionizing Architecture's Future 002

Walmart filed five more patents for farming processes

The patent was one of six filed by Walmart, including several focused on automating agricultural processes. The supermarket chain also plans to use drones for spraying pesticides and monitoring crop conditions.

However artificial pollination has the bigger potential to significantly affect the company’s business.

According to research by Greenpeace, pollination by bees contributes $265 billion to the global economy. So, with the world’s bee population now in major decline, robotic alternatives could prove necessary to meet the global demand for food production.

Walmart isn’t the first to have invested in artificial-pollination technology. Brisbane-based artist Michael Candy recently unveiled his design for a device featuring 3D-printed robotic flowers, while a research lab in Japan recently became the first to successfully achieve pollination using a drone.

(Source: https://www.dezeen.com/2018/03/20/walmart-patent-autonomous-robot-bees-pollinating-drones/)

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

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FRANK CUNHA III
I Love My Architect – Facebook


Internet of Spaces

SpaceThe connectivity concept resonates way beyond the mobile device and the digital screen; it transcends all kind of environments: body, home, city, industry and the environment. If we chose, the connectivity phenomenon could take us to a far more interesting place: connected spaces.

Consider everything that can be connected in a space: it’s far more than connecting wearable devices and phones to a few gadgets or screens. It is about a fundamental change in the information flow direction. Most of us have some kind of device, most of them with some level of connectivity capability. Environments can detect our devices and react to them on many different levels. The more connected spaces are, the more information is available, and so devices can react better, faster and more accurately.

The beauty about this fundamentally different way of thinking about connectivity, is that it makes our environments, our urban spaces, work harder for us. It can power completely new ways to interact with our environment; interactions that go beyond the screen, wearables and simple connected “things”.

Connected spaces can truly change the way we interact with our world. As the intersection between the digital and the physical continues to blur, our environments could really start to create more accurate, engaging and useful experiences. Buildings detecting our presence, querying our phones for details we want to publicly share, tapping into public services and welcoming us with the right information. Stores could completely change the way they serve their customers. Restaurants could provide the correct menus to people according to their diet preferences or known allergies.

201603-raman-figure1
Here is where the power of information and data will make a real difference. Adaptive environments will be able to retrieve and use contextual, relevant, timely and accurate information to interact with us. Spaces will adapt to people, from groups to individuals, contextually and appropriately. The experience a brand can provide to their consumers from this angle exceeds anything that we currently have through the digital screen and the mobile device. A good example of this approach is 2014 Coachella Music Festival, where Spotify partnered with organizers to create connected space experience with the #WeWereThere campaign.

Connected spaces will rely on a myriad of connectivity protocols, platforms and technologies. Native applications, web experiences, lighting, sound, environment, architecture – all will be a part of the connected experience. As a result, agencies and brands will need to diversify and work with interdisciplinary teams across different environments, platforms and technologies.

Sources & References: 

https://www.theguardian.com/media-network/2015/feb/05/connected-spaces-should-be-the-next-step-for-the-internet-of-things)

https://iot.ieee.org/newsletter/march-2016/the-internet-of-space-ios-a-future-backbone-for-the-internet-of-things.html

https://www.virgin.com/entrepreneur/how-internet-things-will-change-our-spaces

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook


What Can Architects Do To Design Safer Classrooms For Our Children? Part 4: Safety Guidelines For Schools

ILMA Classroom 11.pngPhoto Source: The National Association of School Psychologists (NASP)

The Following is Based on the Final Report of the Sandy Hook Advisory Commission

School Site Perimeter Standards

  1. Crime Prevention Through Environmental Design (CPTED) is a crime prevention strategy that uses architectural design, landscape planning, security systems, and visual surveillance to create a potentially crime free environment by influencing human behavior and should be applied when appropriate.
  2. Fencing, landscaping, edge treatment, bollards, signage, exterior furnishings and exterior lighting may be used to establish territorial boundaries and clearly delineate areas of public, semi-public, semi-private, and private space.

Access Control

  1. School boundaries and property lines shall be clearly demarcated to control access to a school facility and shall clearly delineate areas of public, semi-public, semi-private, and private space.
  2. Where a school is a shared use facility that serves the community, internal boundaries shall be clearly defined to establish a distinct perimeter for both the school and the shared use facilities with separate and secure access points that are clearly defined. Boundaries may be defined by installing fencing, signage, edge treatment, landscaping, and ground surface treatment.
  3. The number of vehicle and pedestrian access points to school property shall be kept to a minimum and shall be clearly designated as such.
  4. Directional signage shall be installed at primary points of entry to control pedestrian and vehicular access and to clearly delineate vehicular and pedestrian traffic routes, loading/unloading zones, parking and delivery areas. Signage should be simple and have the necessary level of clarity. Signage should have reflective or lighted markings.
  5. A means shall be provided to achieve and enforce identity authentication and entry authorization at locations and areas established by school operations protocols.

Surveillance

  1. The design shall allow for the monitoring of points of entry/egress by natural and/or electronic surveillance during normal hours of operation and during special events.
  2. At minimum, electronic surveillance shall be used at the primary access points to the site for both pedestrian and vehicular traffic.
  3. All points of vehicular entry/egress shall be adequately illuminated to enhance visibility for purposes of surveillance.
  4. Designated pedestrian and vehicular traffic routes shall be adequately illuminated to reinforce natural and or electronic surveillance during evening hours.
  5. Locate access points in areas of high visibility that can be easily observed and monitored by staff and students in the course of their normal activities. Natural surveillance may be maximized by controlling access points that clearly demarcate boundaries and spaces.
  6. Video surveillance systems may be used around the site perimeter to provide views of points of entry/egress and as a means to securely monitor an area when natural surveillance is not available.
  7. Lighting should be sufficient to illuminate potential areas of concealment, enhance observation, and to provide for the safety of individuals moving between adjacent parking areas, streets and around the school facility.
  8. Consider the design of video surveillance systems which have the ability to be used locally (on site) by emergency responders and viewed off-site at appropriate locations.

Parking Areas and Vehicular and Pedestrian Routes

  1. At the minimum, electronic surveillance shall be used at the primary access points to the site for both pedestrian and vehicular traffic.
  2. Designated pedestrian and vehicular points of entry/egress and traffic routes shall be adequately illuminated to reinforce natural and or electronic surveillance.
  3. Signage shall be posted at all vehicular access points and in delivery zones, parking areas and bus loading/unloading zones with rules as to who is allowed to use parking facilities and when they are allowed to do so. Signage should be simple and have the necessary level of clarity. Signage should have reflective or lighted markings.
  4. Parking areas shall be adequately illuminated with vandal resistant lighting.
  5. Parking shall be prohibited under or within the school building.
  6. Adequate lighting shall be provided at site entry locations, roadways, parking lots, and walkways from parking to buildings.
  7. Gas service rooms, exterior meters/regulators shall be secured.
  8. External access to school facilities shall be kept to a limited number of controlled entrances. Vehicular circulation routes shall be separated and kept to a minimum of two routes per project site for purposes of separating service and delivery areas from visitors‘ entry, bus drop-off, student parking and staff parking. Circulation routes shall be separated, clearly demarcated, and easily supervised. Provide vehicle interdiction devices at building entries to preclude vehicle access into the building.
  9. A drop-off/pick-up lane shall be designated for buses only with a dedicated loading and unloading zone designed to adequately allow for natural and/or electronic surveillance and to avoid overcrowding and accidents.
  10. Design entry roads so that vehicles do not have a straight-line approach to the main building. Use speed-calming features to keep vehicles from gaining enough speed to penetrate barriers. Speed-calming features may include, but are not limited to, speed bumps, safety islands, differing pavement surfaces, landscape buffers, exterior furnishings and light fixtures.
  11. Signage text should prevent confusion over site circulation, parking, and entrance location. Unless otherwise required, signs should not identify sensitive or high risk areas. However, signs should be erected to indicate areas of restricted admittance and use of video surveillance.
  12. Parking areas should be designed in locations that promote natural surveillance. Parking should be located within view from the occupied building, while maintaining the maximum stand-off distance possible.
  13. Locate visitor parking in areas that provide the fewest security risks to school personnel. The distance at which a potentially threatening vehicle can park in relation to school grounds and buildings should be controlled.
  14. Consider illuminating areas where recreational activities and other nontraditional uses of the building occur. If video surveillance systems are installed, adequate illumination shall be designed to accommodate it.
  15. Consider blue light emergency phones with a duress alarm in all parking areas and athletic fields. If utilized, blue light emergency phones shall be clearly visible, readily accessible and adequately illuminated to accommodate electronic surveillance.
  16. Review vehicle access routes to the school and the site civil design with emergency responders to address their incident response requirements.
  17. Design walkways from all parking areas so that they can be observed from within the school by appropriate school staff.

Recreational Areas – Playgrounds, Athletic Areas, Multipurpose Fields

  1. The design shall allow for ground level, unobstructed views, for natural and/or electronic surveillance of all outdoor athletic areas, playgrounds and recreation areas at all times.
  2. Pre-kindergarten and kindergarten play areas shall be separated from play areas designed for other students and physically secured.
  3. Athletic areas and multipurpose fields at elementary school buildings shall contain a physical protective barrier to control access and protect the area.
  4. Playgrounds and other student gathering areas shall be located away from public vehicle access areas, such as streets or parking lots by a minimum of fifty (50) feet unless prohibited by site constraints.
  5. Consider a physical protective barrier around athletic areas and multipurpose fields at secondary school buildings to control access and protect the area.
  6. Locate access points to recreational areas in areas of high visibility that can be easily observed and monitored by staff and students in the course of their normal activities. Natural surveillance may be maximized by controlling access points that clearly demarcate boundaries and spaces.
  7. Pre-K and K play areas should be designed so that they have visual sight-lines to school staff. Fencing should not diminish this visual connection.
  8. Review the design of these areas with emergency responders to address their incident response requirements.

Communication Systems

  1. All classrooms shall have two way communications with the administrative office.
  2. All communication systems shall be installed in compliance with state building and fire code requirements.
  3. Emergency Communication Systems (ECS) and/or alarm systems shall have redundant means to notify first responders, supporting agencies, public safety officials and others of an event to allow for effective response and incident management. Alarm systems must be compatible with the municipal systems in place. These systems may include radio, electronic, wireless or multimedia technology which provides real time information (such as audio, visual, mapping and relevant data) directly to first responders. Points of Broadcast input for these systems shall be reviewed with emergency responders.  A minimum of 2 shall be provided.
  4. Emergency Communication Systems (ECS) shall be installed and maintained in accordance with NFPA 72, 2010, or the most current fire code standard adopted by the local/state construction code authority. ECS may include but is not limited to public address (PA) systems, intercoms, loudspeakers, sirens, strobes, SMS text alert systems, and other emerging interoperable resource sharing communication platforms. The design of these systems shall be reviewed with emergency responders.
  5. All new buildings shall have approved radio coverage for first responders within the building based upon the existing coverage levels of communication systems at the exterior of the building. The system as installed must comply with all applicable sections of the Federal Communication Commission (FCC) Rules for Communication Systems and shall coordinate with the downlink and uplink pass band frequencies of the respective first responders. Perform a radio audibility and intelligibility test and modify system design accordingly.
  6. All in-building radio systems shall be compatible with systems used by local first responders at the time of installation.
  7. Call buttons with direct intercom communication to the central administrative office and/or security office should be installed at key public contact areas.
  8. Develop a strategy and “security team” and equip them with hand-held radios so they can be effective participants in the radio communications system.

School Building Exterior – Points of Entry/Egress and Accessibility

  1. Points of entry/egress shall be designed to allow for monitoring by natural and/or electronic surveillance during normal hours of operation and during special events.
  2. At minimum electronic surveillance shall be used at the primary points of entry.
  3. Lighting shall be sufficient to adequately illuminate potential areas of concealment and points of building entry, and, enhance natural and/or electronic surveillance, and discourage vandalism.
  4. Consider blue light emergency phones with a duress alarm along the building perimeter as needed to enhance security. If utilized, blue light emergency phones shall be clearly visible, readily accessible and adequately illuminated to accommodate electronic surveillance.
  5. Consider the use of forced entry resistance glazing materials for windows and glazed doors using laminated glass and/or polycarbonate to significantly improve forced entry delay time beyond standard glazing techniques. A five (5) minute forced entry solution should be the design standard.

Main Entrance / Administrative Offices / Lobby

  1. Main entrances shall be well lit and unobstructed to allow for natural and/or electronic surveillance at all times.
  2. The design shall allow for visitors to be guided to a single control point for entry.
  3. The main entrance assembly (glazing, frame, & door) shall be forced entry resistant to the project standard, with a forced entry time rating as informed by local law enforcement response timing.
  4. Plans shall carefully address the extent to which glazing is used in primary entry ways, areas of high risk and areas of high traffic and the degree to which glazing is installed or treated to be bullet, blast, or shatter resistant to enhance the level of security. The district‘s priorities for the use of natural surveillance, electronic surveillance, natural light and other related security measures may affect this decision and the overall level of security.
  5. Main entrance doors shall be capable of being secured from a central location, such as the central administrative office and/or the school security office.
  6. Video surveillance cameras shall be installed in such a manner to show who enters and leaves the building and shall be monitored at locations which are attended whenever the school is occupied.
  7. The design shall allow for providing visitor accessibility only after proper identification.
  8. The use of vestibules with forced entry resistant doors and glazing to the project standard should be the design standard.
  9. The central administrative offices and/or security offices should have an unobstructed view of the main entrance lobby doors and hallways. If feasible, administrative offices abutting the main entrance should be on an exterior wall with windows for natural surveillance of visitor parking, drop off areas, and exterior routes leading to the main entrance.
  10. Walls, forced entry resistant to the project standard, should be hardened in foyers and public entries. Interior and exterior vestibule doors should be offset from each other in airlock configuration.
  11. Use vestibules to increase security. The entrance vestibule shall have both interior and exterior doors that are lockable and controllable from a remote location and be designed to achieved enhanced force entry performance as identified to the project forced entry standards.
  12. When possible, the design should force visitors to pass directly through a screening area prior to entering or leaving the school. The screening area should be an entrance vestibule, the administration/reception area, a lobby check in station, an entry kiosk, or some other controlled area. This controlled entrance should serve as the primary control point between the main entrance and all other areas of the school.
  13. Control visitor access through electronic surveillance with intercom audio and remote lock release capability at the visitor entrance.
  1. Restrict visitor access during normal hours of operation to the primary entrance. If school buildings require multiple entry points, regulate those entry points with no access to people without proper identity authentication and entry authorization. Consider an electronic access control system for authorized persons if multiple entry points are utilized during normal hours of operation.
  2. Install a panic/duress alarm or call button at an administrative/security desk as a protective measure.
  3. Proximity cards, keys, key fobs, coded entries, or other devices may be used for access control of students and staff during normal hours of operation. The system may be local (residing in the door hardware) or global (building or district- wide). Prior to installing a customized door access control system refer to the local authority having jurisdiction for compliance with state building and fire code.
  4. Consider sensors that alert administrative offices when exterior doors at all primary and secondary points of entry are left open.
  5. Consider radio frequency access control devices at primary points of entry to allow rapid entry by emergency responders. Review this technology with the emergency responders which serve the school facility.
  6. Where “forced entry” required construction is required, the forced entry delay time shall be based on the ERTA, and have the forced entry designs informed/validated by a licensed architect, professional engineer or qualified security consultant.
  7. Provide closers on these doors so that they automatically return to a closed, latched, and locked position to preclude unauthorized entry.

Exterior Doors

  1. The design shall allow for the points of entry/egress to be monitored by natural and/or electronic surveillance during normal hours of operation and during special events.
  2. Lighting at these entry points shall be sufficient to illuminate potential areas of concealment, enhance natural and/or electronic surveillance, discourage and protect against vandalism.
  3. Tertiary exterior doors shall be hardened to be penetration resistant and burglar resistant.
  4. All exterior doors shall be equipped with hardware capable of implementing a full perimeter lockdown by manual or electronic means and shall be numbered per the SSIC standards.
  5. All exterior doors shall be easy to lock and allow for quick release in the event of an emergency by authorized personnel and emergency responders.
  6. All exterior doors that allow access to the interior of the school shall be numbered in sequential order in a clockwise manner starting with the main entrance. All numbers shall be visible from the street or closest point of entry/egress, contrast with its background and be retro-reflective.
  7. Doors vulnerable to unauthorized access may be monitored by adding door contacts or sensors, or may be secured through the use of other protective measures, such as delayed opening devices, or video surveillance cameras that are available for viewing from a central location, such as the central administrative office and/or security office.
  8. Specify high security keys and cylinders to prove access control.
  9. Provide closers on these doors so that they automatically return to a closed, latched, and locked position to preclude unauthorized entry.

Exterior Windows/Glazing/Films

  1. Windows may serve as a secondary means of egress in case of emergency. Any “rescue window” with a window latching device shall be capable of being operated from not more than forty-eight (48) inches above the finished floor.
  2. Each classroom having exterior windows shall have the classroom number affixed to the upper right-hand corner of the first and last window of the corresponding classroom. The numbers shall be reflective, with contrasting background and shall be readable from the ground plain at a minimum distance of fifty (50) feet.
  3. Plans shall carefully address the extent to which glazing is used in primary entry ways, areas of high risk and areas of high traffic and the degree to which glazing is installed or treated to be bullet, blast, or shatter resistant to enhance the level of security. The district‘s priorities for the use of natural surveillance, electronic surveillance, natural light and other related security measures may affect this decision and the overall level of security.
  4. Design windows, framing and anchoring systems to be shatter resistant, burglar resistant, and forced entry resistant to the project forced entry standards, especially in areas of high risk. Whenever feasible, specify force entry resistant glazing on all exterior glazing.
  5. Resistance for glazing may be built into the window or applied with a film or a suitable additional forced entry resistant “storm” window.
  6. Classroom windows should be operable to allow for evacuation in an emergency. Review with the authority having jurisdiction and fire department to balance emergency evacuation, external access, and security requirements.

School Building Interior

  1. Interior physical security measures are a valuable part of a school‘s overall physical security infrastructure. Some physical measures such as doors, locks, and windows deter, prevent or delay an intruder from freely moving throughout a school and from entering areas where students and personnel may be located. Natural and electronic surveillance can assist in locating and identifying a threat and minimizing the time it takes for first responders to neutralize a threat.
  2. The design shall provide for controlled access to classrooms and other areas in the interior that are predominantly used by students during normal hours of operation to protect against intruders.
  3. All interior room numbers shall be coordinated in a uniform room numbering system format. Numbering shall be in sequential order in a clockwise manner starting with the interior door closest to the main point of entry. Interior room number signage shall be wall mounted. Additional room number signage may be ceiling or flag mounted. Interior room number signage specifications and installation shall be in compliance with ADA standards and other applicable regulations as required.
  4. Record documentation drawings shall be kept which include floor plans with the room numbering system. These drawings shall be safeguarded but available for emergency responders. Review opportunities for emergency responders agencies to have these drawings as well.
  5. Review design opportunities to create interior safe havens with forced entry resistant walls and doors. These may be libraries, auditoriums, cafeterias, gyms or portions of school wings or blocks of classrooms.
  6. Establish separate entrance and exit patterns for areas that have concentrated high- volume use, such as cafeterias and corridors, to reduce time required for movement into and out of spaces and to reduce the opportunity for personal conflict. Separation of student traffic flow can help define orderly movement and save time, and an unauthorized user will perceive a greater risk of detection.
  7. Consider intruder doors that automatically lock when an intruder alarm or lockdown is activated to limit intruder accessibility within the building. If installed, intruder doors shall automatically release in the event of an emergency or power outage and must be equipped with a means for law enforcement and other first responders to open as necessary.

Interior Surveillance

  1. An intrusion detection system shall be installed in all school facilities.
  2. If video surveillance systems are utilized, the surveillance system shall be available for viewing from a central location, such as the central administrative office and/or the school security office, and at points of emergency responder incident management. Review these locations with emergency responders in the design phase.
  3. Consider electronic surveillance in lobbies, corridors, hallways, large assembly areas, stairwells or other areas (such as areas of refuge/safe havens) as a means to securely monitor those areas when natural surveillance is not available.
  4. The design of a school facility should allow for the designation of controlled hiding spaces. A controlled hiding place should create a safe place for students and personnel to hide and protect themselves in the event of an emergency. The controlled hiding space should be lockable and readily accessible. A controlled hiding space could be a classroom or some other designated area within the building.
  5. Design interior hallways and adjacent spaces to provide situational awareness of hallway conditions from these rooms, but also provide means to eliminate vision into these rooms as activated by room occupants.

Classroom Security

  1. All classrooms shall be equipped with a communications system to alert administrators in case of emergency. Such communication systems may consist of a push-to-talk button system, an identifiable telephone system, or other means.
  2. Door hardware, handles, locks and thresholds shall be ANSI/BHMA Grade 1.
  3. All classroom doors shall be lockable from the inside without requiring lock activation from the hallway, and door locks shall be tamper resistant.
  4. Classroom door locks shall be easy to lock and allow for quick release in the event of an emergency.
  5. Classroom doors with interior locks shall have the capability of being unlocked/ released from the interior with one motion.
  6. All door locking systems must comply with life safety and state building and fire codes to allow emergency evacuation.
  7. Provide doors between adjacent classrooms to provide means of moving classroom occupants from one classroom to the next as a means to relocate students and teachers from an impending hallway threat. Provide such doors with suitable locking hardware to preclude unauthorized tailgating.
  8. Provide closers on these doors so that they automatically return to a closed, latched, and locked position to preclude unauthorized entry.
  9. If classroom doors are equipped with a sidelight, the glazing should be penetration/forced entry resistant to the project forced entry standard.
  10. If interior windows are installed to provide lines of sight into/out of classrooms or other populated areas, certain factors should be taken into consideration relating to the size, placement and material used for those windows, including:
  11. Minimizing the size of windows or the installation of multiple interspersed smaller windows with barriers in a larger window area to deter intruder accessibility.
  12. Placing windows at a sufficient distance from the interior locking mechanism to prevent or make difficult the opening of a door or lock from outside.
  13. Concealing or obstructing window views to prevent an assailant‘s ability to ascertain the status or presence of persons inside of a classroom during lockdown.
  14. Hardening window frames and glazing to the project forced entry standards to lessen window vulnerability.

Large Assembly Areas (gym, auditorium, cafeteria, or other areas of large assembly)

  1. Points of entrance and egress shall be clearly demarcated and designed to meet the project forced entry standards.
  2. Lighting shall be sufficient to illuminate potential areas of concealment, enhance natural and/or electronic surveillance, discourage vandalism and protect against vandalism.
  3. Electronic surveillance should be used in large assembly areas and at all exit doors to securely monitor those areas when natural surveillance is not available.

Shared Space or Mixed Occupancy (library, BOE, mixed use or other community service)

  1. Shared space shall have separate, secure and controllable entrances.
  2. The design of shared space should prevent unauthorized access to the rest of the school.
  3. The design of shared space shall allow for the monitoring of points of entry/egress by natural and/or electronic surveillance during normal hours of operation.

Roofs

  1. The design shall allow for roof accessibility to authorized personnel only.
  2. Access to the roof should be internal to the building. Roof access hatches shall be locked from the inside.
  3. If external access exists, roof ladders should be removable, retractable, or lockable. Screen walls around equipment or service yards should not provide easy access to the roof or upper windows.
  4. Provide adequate lighting and controls for roof access means and roof access points into the school.

Critical Assets/Utilities

  1. Screens at utilities, such as transformers, gas meters, generators, trash dumpsters, or other equipment shall be designed to minimize concealment opportunities and adequate to preclude unauthorized access. Installation of screens at utilities shall be compliant with utility company requirements.
  2. Access to building operations systems shall be restricted to designated users with locks, keys and/or electronic access controls. Secure all mechanical rooms with intruder detection sensors.
  3. Loading docks shall be designed to keep vehicles from driving into or parking under the facility.
  4. Spaces with critical systems shall be provided appropriate graphics to be recognizable to emergency responders.
  5. Gas meter/regulator rooms shall be provided with forced entry resistant doors and to the project standards.
  6. Gas leak detection systems/sensors shall be installed wherever gas metering or appliances are installed.
  7. Shipping and receiving areas shall be separated from all utility rooms by at least fifty (50) feet unless prohibited by site constraints. If a site is determined to be physically constrained from reasonably meeting the fifty (50) foot separation requirement, maximize the separation distance between the receiving area and the utility room to the greatest extent possible. Utility rooms and service areas include electrical, telephone, data, fire alarm, fire suppression rooms, and mechanical rooms.
  8. Critical building components should be located away from vulnerable areas. Critical building components may include, but are not limited to:
    1. Emergency generator;
    2. Normal fuel storage;
    3. Main switchgear;
    4. Telephone distribution;
    5. Fire pumps;
    6. Building control centers;
    7. Main ventilation systems if critical to building operation.
    8. Elevator machinery and controls.
    9. Shafts for stairs, elevators, and utilities.

Security Infrastructure and Design Strategies

  1. The design shall include special rooms for hazardous supplies that can be locked.
  2. The design shall include secured spaces, closets, cabinets or means of protection to minimize the use of dangerous objects from shop, cooking or other similar occupancies.
  3. Egress stairwells should be located remotely and should not discharge into lobbies, parking or loading areas.
  4. Trash receptacles, dumpsters, mailboxes and other large containers shall be kept at least thirty (30) feet from the building unless prohibited by site constraints. If a site is determined to be physically constrained from reasonably meeting the thirty (30) foot separation requirement, maximize the separation distance to the greatest extent possible.

(Source: Final Report Of The Sandy Hook Advisory Commission)

Look out for our next post about “What Architects Can Do to Design Safer Classrooms for Our Children.”

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook

 


What Can Architects Do To Design Safer Classrooms For Our Children? Part 1: Door Security Guidelines

 ILMA Classroom 01.pngPhoto Source: The National Association of School Psychologists (NASP)

The increased number of school violence has created a growing public concern for safety in schools across North America and around the world. Each year, school administrators are faced with the challenge of finding ways of improving student safety from an active shooter situation despite budget cuts forcing them to defer costs for security upgrades. Unfortunately, these necessary improvements are put off, and only revisited after a horrific tragedy, such as a deadly school shooting. As a result of this type of reactionary response, coupled with mounting pressure from parent organizations, several states have or are considering changes to their building codes to allow for the installation of classroom door barricade devices. While these devices are perceived to provide immediate security, they have the significant potential to facilitate unintended consequences that could put students at even more risk and the school in risk of liability. (Source: “The Liability of Classroom Door Barricades” by Door Security & Safety Foundation)

Active Shooter Graph.pngModifying building codes to allow for door barricade devices might keep a gunman out of classrooms, but the unintended consequences associated with the devices could put children at even more risk and the school in liability. Yet, many states are seeking to change their codes under the false pretenses that door barricade devices are the only product that can secure a classroom. (Source: “Opening the Door to School Safety” by Door Security & Safety Foundation)

Door barricade devices in schools are intended to keep dangerous individuals out of classrooms, but what if that person is already in the room?

(Source: “Door barricade devices” by Door Security & Safety Foundation)

The National Association of State Fire Marshals “Guidelines” address door security devices, which are mandatory in many states as they are included as part of the International Building and Fire Codes and Life Safety Codes. They mandate that that locking mechanisms should be able to do the following: (1) provide immediate egress by being located between 34” and 48” above the floor, and not require special knowledge or effort, nor key or tool, nor require tight grasping, twisting, or pinching to operate, and accomplished with one operation; (2) be easily lockable in case of emergency from within the classroom without opening the door; (3) lockable and unlockable from outside the door.

Is your school secure in the event of a lockdown situation or an active shooter scenario? Safety isn’t just about closing the door; it’s also about opening it.

The National Association of State Fire Marshals recommends what classroom locking mechanisms can and should do. Follow these 3 easy steps to see if your classroom door locks meet these recommendations: (1) Opens from inside the room without requiring tight grasping, pinching or twisting of the wrist, and accomplished with one operation; (2) Locked and unlocked from the inside of a classroom without requiring the door to be opened, while still allowing staff entry in an emergency; (3) Locked automatically or have a simple locking mechanism such as a pushbutton, key, card, fob, fingerprint, etc., that can be locked from inside the classroom without having to open the door.

Safety Concerns Associated with Door Barricade Devices:

Non-Code Compliant:

  • These products fall short of building code requirements.
  • In most cases, these devices are not tested through the formal code process to ensure that the proper balance of life safety and security are met.

Delayed Response:

  • When someone, other than the classroom teacher, who doesn’t know where the barricade device is kept or how to install it properly is required to engage the device this could result in a delay at a critical time.

Unauthorized Engagement:

  • Storing a barricade device in a classroom makes crimes easier to carry out.
  • When used by an unauthorized person, barricades have the significant potential to facilitate unintended consequences such as bullying, harassment or physical violence.
  • According to the Centers for Disease Control and Prevention (CDC) and the FBI, a member of the student body is most likely to commit violence on school grounds.

Blocked Entry:

  • Because these devices are intended to serve as a barricade and prevent access from the outside, a staff member or emergency responder would not be able to enter a classroom.
  • The intruders who carried out school shootings at Virginia Tech, the West Nickel Mines School and Platte Canyon High School each used materials to barricade the doors.
  • School districts looking to install classroom door barricades devices must also weigh the possibility of an exit being blocked during an emergency.
  • In the event of a fire, these devices could delay egress resulting in fatalities.
  • Fire is one of the leading reasons, in addition to countless other tragedies, that building codes have been adopted.
  • A case could be made by someone injured in a barricaded classroom against the school district because they failed to keep him or her safe while on school property.
  • The injured party could claim he or she was trapped inside a locked classroom with no way for safety officers to enter freely.
  • School administrators should only consider traditional, tested, locking products that meet the code requirements for providing life safety in addition to security.
  • These products allow the door to be locked from the inside of a classroom without requiring the door to be opened, yet allow authorized access by staff and emergency responders in case someone inside the room intends to cause harm or injury.

(Source: The Liability of Classroom Door Barricades by Door Security & Safety Foundation)

According to testimony presented to the Sandy Hook 1 “Barricade Device? Think Twice!” Lori Greene, AHC/CDC, FDAI, FDHI, CCPR. Doors & Hardware, May 2015. Advisory Commission, there is not one documented incident of an active shooter breaching a locked classroom door by defeating the lock. Maintaining a balance of life safety and security is possible today using proven products that meet the NFPA 101 Life Safety Code. New devices being introduced may provide some level of additional security but can seriously compromise certain other aspects of life safety; that is why we have codes and standards. Unfortunately, these devices do not meet codes and may negatively affect life safety in the case of other emergencies such as a fire, which statistically is more than three times more likely to happen than an active shooter situation.  (Source: Final Report Of The Sandy Hook Advisory Commission)

What are we trying to correct if there is not one documented incident of a classroom lock being defeated?” Based on the statistics cited by the National Center for Education Statistics (NCES), to allow these products to be employed when they do not meet the codes is to put the public at greater harm.

  • “In 2012, students ages 12–18 were victims of about 1,364,900 nonfatal victimizations at school, including 615,600 thefts and 749,200 violent victimizations, 89,000 of which were serious violent victimizations.”
  • “During the 2009–10 school year, 85 percent of public schools recorded that one or more of these incidents of violence, theft, or other crimes had taken place, amounting to an estimated 1.9 million crimes.”
  • “During the 2011–12 school year, 9 percent of school teachers reported being threatened with injury by a student from their school. The percentage of teachers reporting that they had been physically attacked by a student from their school in 2011–12 (5 percent) was higher than in any previous survey year (ranging from 3 to 4 percent).”

(Source: DSSF White Paper Classroom Door Security)

When considering the selection of hardware which allows classroom doors to be lockable from inside the classroom, consideration should be given to the risks and potential consequences of utilizing a device which blocks the classroom door from the inside. For example, devices which prevent classroom doors from being unlocked and openable from outside the classroom may place the inhabitants of the room in peril. In addition to the requirement that classroom doors must be unlatchable in a single motion from inside the classroom (discussed above), these doors should always be unlockable and openable from outside the classroom by authorized persons.

RealView-Emergency-trends-infographic-FINAL.jpgSchool Security – Suggested Classroom Door Checklist

The “School Security – Suggested Classroom Door Checklist” identifies many parameters which should be satisfied when selecting and installing hardware on classroom doors intended to increase security in the classroom. (Source: Fire Marshals Classroom Door Security)

  • The door should be lockable from inside the classroom without requiring the door to be opened;
  • Egress from the classroom through the classroom door should be without the use of a key, a tool, special knowledge, or effort;
  • For egress, unlatching the classroom door from inside the classroom should be accomplished with one operation;
  • The classroom door should be lockable and unlockable from outside the classroom;
  • Door operating hardware shall be operable without tight grasping, tight pinching, or twisting of the wrist;
  • Door hardware operable parts should be located between 34 and 48 inches above the floor;
  • The bottom 10 inches of the “push” side of the door surface should be smooth;
  • If the school building does not have an automatic fire sprinkler system, the classroom door and door hardware may be required to be fire-rated and the door should be self-closing and self latching;
  • If the door is required to be fire-rated, the door should not be modified in any way that invalidates the required fire-rating of the door and / or door hardware;
  • In the Suggested Classroom Door Checklist, “should” is used throughout. However, based upon building codes, life safety codes, fire codes, and federal, state, and / or local laws and regulations that are applicable to a particular school, these requirements may be MANDATORY. Always check, and comply with, all applicable building and fire codes, life safety codes, and laws, regulations and other requirements.

Look out for our next post about “What Architects Can Do to Design Safer Classrooms for Our Children.”

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook