Architecture tells us a great deal about society. In fact, glass and glazing are used to blur the lines between inside and out, helping elevate performance and the experiences of people. Yet while humans can use environmental cues to identify glass as a barrier, there is growing realization that birds cannot. The solution is bird-friendly glass that delivers on performance, energy efficiency and the needs of people. This course from Guardian Glass is intended to provide the basis for a better understanding of how to recognize issues affecting the bird population while learning about best practices and design fundamentals for smarter, safer buildings.

The pattern map evaluates a pattern on two key elements: structure and nature. This course explains why these two elements affect how we recognize and respond to patterns and examines ways to bridge architecture and nature by using architectural panel systems with patterned openings, and provide a sense of space, privacy, shade, or camouflage with cladding, screens, or railings.

HSW Justification: Architectural use of patterns plays a vital role in enhancing the Health, Safety, and Welfare (HSW) in of our built environments. Our mental well-being, for example, can be positively impacted through organic biophilic geometries that connect occupants to nature to positively affect mood and reduce stress, while geometric or crystalline patterns create the dynamic visual interest necessary for effective way-finding elements to prevent accidents and ensure safer navigation. Some patterns can also be visually transparent while others act as camouflage which can be an important consideration for surface treatment in circulation areas. From a macro perspective, patterns can promote inclusivity and community engagement, while enriching their overall user experience.

Learning Objective 1: Students will learn to compare patterns on a pattern map and explore how different geometries are perceived and processed in the mind of the user, how they contribute to issues affecting safety, and even encourage engagement in built environments.

Learning Objective 2: Students will learn to explain how different characteristics and application of a pattern’s functionality can impact on how we perceive visual space to improve safety and social interaction, as well as contribute to positive mental health.

Learning Objective 3: Students will learn the importance of selecting the most appropriate openness factor and base material for the given project objectives, for example, how to enhance natural light, improve air quality, and create a welcoming atmosphere in built environments.

Learning Objective 4: Students will learn how to apply HSW Best Practices to provide privacy, facade screening, camouflage, shade, or railings with architectural panels with patterned openings to best create a positive user experience.

Program: Architecture, Design and Building Science

This course explores a few of the many ways that interiors impact the health and well-being of the people inside them. From restrooms being designed to reduce contact with contaminated surfaces and inhibit the presence of bacteria, to acoustics solutions that absorb or isolate noise, making interiors more comfortable and productive. Biophilic design, a health-focused design concept that encourages the inclusion of plants, daylight, and natural elements like wood and stone, is also discussed, as are the options designers have for bringing stone elements inside.

The building envelope has a lot of different jobs to do—from insulating the building so that it can be efficiently heated and cooled to providing air and water barriers that keep harmful moisture at bay, as well as providing the aesthetic face of the project. High performance building envelopes do all of those things extremely well. This article explores some of the latest high-performance solutions that can be used to create those high-performance envelopes.

HSW Justification:
A high-performance building envelope is necessary to create a building that is efficient and healthy. This article takes a look at how different components in the building envelope perform—giving architects the information they need to choose high-performance components that will produce a high-performing envelope.

Learning Objective 1:
Compare different types of continuous insulation in terms of the thermal performance they offer and the way they behave when exposed to water and fire.

Learning Objective 2:
Describe how insulated metal panels (IMPs) can be used on the envelope to improve building performance, create efficient and healthy interiors, and enhance design flexibility.

Learning Objective 3:
Explain how PET bottles can be upcycled into insulation creating a new product that contains recycled material and improves thermal performance of the building envelope.

Learning Objective 4:
Describe the ways that architectural metal wall systems enable architects to push the creative boundaries of their designs.

This course will introduce you to the custom balanced door. You will learn about the system components and the differences between a Balanced door and a conventional hinged or pivoted swing door. Then we'll take a closer look at how a balanced door works in an installation. Finally you'll learn about the specific engineering requirements needed to accommodate balanced doors.

HSW Justification:
Balanced doors are safer than conventional doors because they require a smaller interference zone on the sidewalk. Also, they open with ease which benefits smaller people, weak or disabled persons, and the elderly. The majority of this course deals with those benefits and with the mechanical features of the door that make these health and safety benefits possible.

Learning Objective 1:
Understand the differences between the balanced door and a conventional hinged or pivoted swing door

Learning Objective 2:
Know specific requirements for ADA handicap guidelines LO 5: Understand how the balanced door interfaces with power operation LO 6: Understand specific engineering requirements to accommodate balanced doors

Learning Objective 3:
Understand what components make up a typical balanced door system

Learning Objective 4:
Know how the design concept works in an actual installation

Addressing student behaviors, improving the learning environment, and enhancing the sustainability of educational buildings with design.

Learning Objective 1: After reading this article, you should be able to: describe how the inclusive restroom design concept addresses the bad behaviors plaguing bathroom spaces and improves student safety

Learning Objective 2: After reading this article, you should be able to: summarize the ways that acoustical surfaces, lighting, and HVAC systems are being used to improve the comfort of the learning environment, helping students perform better in class.

Learning Objective 3: After reading this article, you should be able to: identify various solutions that can be incorporated to heighten security throughout a school.

Learning Objective 4: After reading this article, you should be able to: explain some of the sustainability strategies making schools more environmentally friendly.

This course is designed to teach the history of synthetic turf, its application in water and energy conservation, pollution abatement, sustainable design, and its versatility in numerous landscaping applications and designs. Participants will become knowledgeable about synthetic turf and innovative applications that could be applied to their residential and commercial projects. The most current technological advances in the industry and the positive role synthetic turf plays in the environment.

Learning Objective 1:
Students will gain an increased awareness of the positive environmental impact of synthetic turf on water use, reduced energy demand and reduction of use of fossil fuels, reduced chemical application, and resulting reduction of water and noise pollution.

Learning Objective 2:
Students will become more informed on the newest synthetic turf material technologies available, including the use of soy based materials, as well as how the proper application of infills and proper material selection can benefit the health and safety of athletes.

Learning Objective 3:
Students will be more knowledgeable about the history and evolution of the technology and of landscaping and sports applications using synthetic turf.

Learning Objective 4:
Students will better understand the versatility of synthetic turf and its many uses in sustainable landscape design.

Neuroarchitecture is a design discipline that seeks to incorporate neuroscience into design to augment the built environment’s positive influence on the emotional and physical health of people.

Beauty, functionality, and wellness-enhancing can co-exist in design, with the right products. This article explores solutions that help architects achieve these important multi-benefits. Pavers that create beautiful outdoor spaces that are easy to maintain. Skylights that allow daylight and fresh air into the interior. Underlayment that improves acoustics and sound management, while protecting the integrity of the interior air quality. Each improves the functionality of the space and the wellness of the people in the built environment.

 The class is a high-density orientation to lighting considerations and methods in the healthcare environment. Topics will include application situations, impacted populations, design methods, and a review and critique of examples of successful and less-than-successful healthcare lighting designs.

At the end of this course, participants will:

1. Identify current trends in the healthcare lighting design and the impact lighting has on its occupants and the environment. 
2. Identify who is impacted by our lighting design decisions and learn best practices on how to light the spaces they occupy.
3. Identify specific lighting needs of patient rooms.
4. Identify emerging lighting methods including design for circadian health.