Inverters are a modern, simple way to achieve an emergency lighting solution while minimizing maintenance costs and utilizing existing architectural fixtures for emergency purposes. This course will give the student the skills they require to design and specify inverter-based emergency lighting systems.

The building envelope separates the conditioned interior space from the environmental elements of the great outdoors, and this course explores a few solutions to equip the building envelope to defend the interior from nature's onslaughts, manage moisture, improve thermal performance, and admit daylight without glare.

HSW Justification:
Improper use of vapor barriers is one of the leading causes of moisture-related issues in buildings today. Those moisture related issues can include the growth of mold and mildew, which compromises the quality of the indoor environment and can even cause structural damage. Designing a proper air barrier system is crucial to moisture protection and protecting the thermal performance of the original design. This article provides best practices for designing an air barrier system that will function properly. We also discuss some solutions that can improve the functionality of the building envelope’s thermal performance. The course explores a translucent and an opaque solution that improve the thermal performance of the envelope, while offering additional benefits. Translucent wall panels allow diffuse, glare-free daylight into an interior, without compromising thermal efficiency at the opening and precast structural panels offer code-exceeding thermal performance and structural load-bearing capabilities.

Learning Objective 1:
Students will be able to explain why controlling air leakage in the building envelope is crucial to safeguarding the quality of the interior environment and protecting the energy efficiency of the building.

Learning Objective 2:
Students will learn to apply best practices to design an air barrier system that will effectively manage moisture intrusion and avoid moisture-related issues in the building envelope.

Learning Objective 3:
Students will be able to describe how translucent daylight panels allow daylight into the interior, mitigate glare and provide better thermal performance than many other glazing solutions.

Learning Objective 4:
Students will learn to use structural precast concrete panels to reduce the amount of perimeter steel needed on a project, while achieving and exceeding code-compliant thermal performance.

In this session, we will learn the fundamentals of all successful AE firms and provide the basis for making well-grounded business decisions. We will learn how firms can transition from being professionals providing services, to highly tuned businesses that can identify the needs of the marketplace and create services and products that are appropriately priced and yield consistent and greater profits.

Rather than seeking out new projects that merely build upon your current skills, you will start from a business-thinking mindset, where processes that are critical to building a thriving firm are examined and constituted in your firm. We will explore the importance of data within an architect firm and demonstrate how careful collection and interpretation can lead your firm into more exciting and profitable territory.

Following are the course's Learning Objectives:

1. Identify why a “business-thinking” mindset is of utmost importance for service professionals
2. Explain best practices for implementing a metrics-oriented leadership system
3. Summarize how data-based performance management drives smarter business decisions
4. Analyze how profitability drives growth rather than being merely a result
5. Reframe your firm as a platform that enables you to achieve your business and personal goals

This course will cover introductory level descriptions of various sectional door styles and how they impact energy efficiency, maximize ambient light, add to design aesthetics. Additionally, applicable varieties of industrial doors will also be included.

HSW Justification: Understanding upward acting door and safety device specification and installation contribute to health, safety and welfare of building occupants, including infants, children and the elderly, by helping avoid entrapment, injury, or exposure to exhaust gasses. Additionally, proper installation helps assure comfort control, energy efficiency and better design aesthetics.

Learning Objective 1: Students will be able to recognize and differentiate various types of sectional and industrial doors, with a focus on selecting door types that enhance occupant safety, support energy efficiency, and improve building design aesthetics for a healthier environment.

Learning Objective 2: Students will learn to specify upward-acting doors, prioritizing occupant health and safety by understanding how door selection impacts injury prevention, exhaust gas exposure, and energy conservation, while also enhancing natural light and aesthetic integration.

Learning Objective 3: Students will gain skills in assessing mounting conditions, headroom and side room requirements, and types of lifts and operators, with particular attention to how these considerations affect safety, mechanical reliability, and occupant welfare.

This course will explore the cutting-edge union of design and technology by delving into parametric design and its symbiosis with digital fabrication, and how the vision is best achieved via vertically-integrated, technology-forward product manufacturers. We will also discuss strategies for effective collaboration with these manufacturers throughout the architectural design process.

Learning Objective 1: Students will learn about the use of parametric design in architecture, including its definition, history and current state.

Learning Objective 2: Students will learn about the marriage between parametric design and digital fabrication.

Learning Objective 3: Students will understand why vertical integration is an important operating model for product manufacturers looking to leverage parametric design.

Learning Objective 4: Students will understand how to partner with vertical manufacturers throughout the architectural design process and learn the advantages of this digital collaborative approach.

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 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

This article explores some of the latest products and solutions improving the air quality, thermal comfort, electric light, and daylight control that can be incorporated into a project. Each improves the wellness of the people in the built environment.

Learning Objective 1: Explain how air circulation improves thermal comfort and alertness.

Learning Objective 2: Describe the ways that increasing the presence of plants and greenery on a project have been shown to clean the air, reduce urban heat island effect, and positively affect the health and wellbeing of people in the built environment.

Learning Objective 3: Summarize how circadian LED lighting technology delivers health benefits—improving overall sleep quality, daytime productivity, and feelings of wellbeing—that modern architectural lighting lacks.

Learning Objective 4: Discuss how using an underfloor air distribution system (UFAD) improves indoor air quality.

Learning Objective 5: Identify the latest advancements in smart window technology that allows these solutions to control glare and solar heat gains, while maintaining views to the outdoors.

Program: Architecture, Design, and Building Science

The purpose of this presentation is to give you a clear understanding of the features and benefits of textured metals and discover how to best specify stainless steel and metal alloys in your projects. The first part of our talk will introduce the ecological and economic properties of textured stainless steel as well as educate you on the composition of metals and alloys. The second portion of this presentation will illustrate the process of texturing metals and their applications, as well as how to specify them. The session will also review projects that use textured metals - with beautiful results.

HSW Justification:
Most of this course is dedicated to explaining the aesthetic, ecological and economic advantages of textured metals. Most often, the metal used in stainless steel, which is very long-lived, valuable and 100 percent recyclable. The case studies focus on many beautiful installations that enhance the lives of occupants and visitors through the art and craftsmanship of the installations.

Learning Objective 1:
Students will understand ecological, economic, health and safety benefits of utilizing metals that can be deep textured.

Learning Objective 2:
Students will explore current applications that employ deep textured metals because of their ecological benefits, enhanced performance, and aesthetic attributes.

Learning Objective 3:
Students will learn compositions of metals that can be deep textured, how each performs under varying environmental constraints, and how to safely and economically specify deep textured metals.

Learning Objective 4:
Students will discover end user benefits of deep texturing metals, including performance enhancement, material usage reduction and longer product lifecycles.

This course will describe the aesthetic and biophilic benefits, as well as the objective sustainability standards achieved by innovative metal wall materials that mimic wood. The course will describe how the materials provide both physical and emotional comfort to occupants, protection from harsh weather, and the community benefits of sustainable construction. A variety of applications are also detailed in case studies of actual projects.

Learning Objective 1:
The student will understand how and why the use of materials that mimic but outperform natural materials is highly desirable.

Learning Objective 2:
The student will be able to explain the technologies applied to materials and methods of construction that mimic wood in order to improve sustainability and resist environmental attack.

Learning Objective 3:
The student will recognize the favorability of these materials and methods of construction through a recitation of their achievements in testing and evaluation, how they meet construction standards, and what contributions they make to LEED v4.

Learning Objective 4:
The student will become familiar with a variety of existing projects that demonstrate successful adoption of these products and methods.