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Description
Rebuilt is a project that looks to understand what Syrian refugees experience in camps, specifically Za'atari, the world's largest Syrian camp. The intent of Rebuilt was to create a product that would help their living conditions. By applying Design Thinking & Process, Rebuilt ultimately yielded a room partition system to

Rebuilt is a project that looks to understand what Syrian refugees experience in camps, specifically Za'atari, the world's largest Syrian camp. The intent of Rebuilt was to create a product that would help their living conditions. By applying Design Thinking & Process, Rebuilt ultimately yielded a room partition system to help improve the living conditions of refugees. To design a product for a world most of the world is ignorant of, research is paramount. Research for Rebuilt involved gather many facts from various international databases, such as UNHCR and Mercy Corps. By understanding the demographics, the culture, and needs, Rebuilt was able to focus on some key points that lead to a potential design project: over half of the camp is consisted of adolescents (under age 18), and are living in small, essentially shipping-container homes, and the environment of the Jordanian desert where the camp is situated is extremely variable between freezing winters and blistering summers. Looking over the resources provided by humanitarian organizations, Rebuilt pinpointed a missing niche product that could help the living conditions of refugee's lives: a room partition system that could regulate ambient temperatures. The need for private space is important for the development of a refugee adolescent as it encourages stability and a sense of home. Ambient temperature is also vastly important for the productivity and health of anyone. Rebuilt is consisted of two main parts: the design of a bracket that could be used to accommodate the widths of multiple building materials and would be cheap to manufacture, and a pre-made panel that incorporated the use of phase-change-material technology. The design process is documented with a finalized design that should be low-cost and light-weight to ship from manufacturers to those in need.
ContributorsLee, Anna Jade (Author) / Shin, Dosun (Thesis director) / Bacalzo, Dean (Committee member) / Department of Marketing (Contributor) / The Design School (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
For my creative project, I built a musical robot and explored the possibilities for robots in music education. In addition, I wrote a guide to share what I learned and to provide helpful information to anyone who is planning on building their own musical robot. This is not a step-by-ste

For my creative project, I built a musical robot and explored the possibilities for robots in music education. In addition, I wrote a guide to share what I learned and to provide helpful information to anyone who is planning on building their own musical robot. This is not a step-by-step set of instructions; however, it gives the reader a preview of many options they have for building a musical robot. This guide includes information about existing musical robots, outlines possible strategies for brainstorming ideas, and describes various capabilities of musical robots. While this project focused on the intersection of music and robotics, my approach also included design thinking, which helped provide a focus and shaped my creative process.

The robot building guide is targeted toward an audience with little or no knowledge of robotics. It begins by exploring existing musical robots and explaining how existing products can be used as a source for inspiration. Next, this guide outlines various methods of design thinking and encourages the reader to use design thinking throughout the brainstorming and building process. This guide also highlights options for designing 3D-printed parts, which can be added to a robot. After that, the guide explains options for robot movement, specifically chassis kit assembly and using a 1Sheeld board with Arduino. This guide also explores the possibilities for the interaction of lights and sound, including sound-reactive lights and remote-control lights. Practical information about materials and their organization is provided, as well. The guide concludes with exciting possibilities for robots in music education.
ContributorsDemassa, Katelyn Debra (Author) / Tobias, Dr. Evan (Thesis director) / Bacalzo, Dean (Committee member) / School of Music (Contributor) / Barrett, The Honors College (Contributor)
Created2020-05