Program: The Art and Technology of Lighting

This course will explore the use of exterior lighting to illuminate building facades, landscapes, pathways, plazas, and points of interest, like statues. Popular techniques (moonlighting, wall washing, grazing, etc.) will be defined and the performance of various lighting fixtures will be compared to help designers identify the fixtures best-suited for particular applications. Important considerations including: energy codes, dark sky criteria, and occupant safety will be addressed. The renovation of the exterior lighting at the Greater Columbus Convention Center, designed by Ardra Zinkon, will be profiled.

HSW Justification:
Exterior lighting can facilitate the enjoyment of an outdoor space and enhance the feeling of safety and security people experience in these areas, but the design of exterior lighting systems must accomplish more than bathing an area in illumination indiscriminately. Energy codes limit the amount of energy that the lighting system can consume and define lighting controls requirements to minimize energy waste. In addition, the Model Lighting Ordinance (MLO), developed by the International Dark Sky Association (IDA) and the Illuminating Engineering Society (IES), provides guidance on ways to reduce light pollution and glare that can be created by outdoor lighting. This course will provide designers with tips on how to create exterior lighting solutions that satisfy energy codes and dark sky criteria, while providing ample illumination to create beautiful and inviting outdoor spaces.

Learning Objective 1:
Create exterior lighting designs that provide the recommended levels of illumination for highlighting facades, supporting wayfinding, and accenting features of the outdoor space, while satisfying code-mandated energy use and controls requirements as well as dark sky criteria.

Designing with Pre-Crimped Woven Wire Mesh is a streaming video course that explores interior and exterior applications and functions for woven metal mesh products in architectural design. The course examines key functions of these materials, details the manufacturing process, and outlines critical specification considerations to ensure beautiful and long lasting installations.

Designing buildings for life safety and wellness is getting easier.

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.

This course will teach students how to recognize non-compliant rooftop equipment support scenarios and will discuss their impact on safety and the public health, general welfare, and property value.

Solar shading devices, while available in numerous weaves, textures, and colors, go beyond contributing to the aesthetics of a space. Specified correctly, solar shading devices can maximize daylighting benefits and contribute to occupant well-being, productivity, and engagement, while mitigating the detrimental effects of UV rays and glare.

Learning Objective 1:
Students will understand the benefits daylighting, including the psychological and physiological well-being of occupants, as well as its drawbacks, such as glare and solar heat gain

Learning Objective 2:
Students will become familiar with the types of solar shading fabrics available for use in commercial settings and their components, including operating systems, weave, color, and openness factor, and the ways in which these contribute to the control of daylighting.

Learning Objective 3:
Students will explore the benefits of solar shading devices that extend beyond light management, such as sound mitigation, sustainability, and antimicrobial properties.

Learning Objective 4:
Students will determine how to select the right fabric for an application, taking into account aesthetics and room conditions

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 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.

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.

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.