Barrett, The Honors College Thesis/Creative Project Collection
Barrett, The Honors College at Arizona State University proudly showcases the work of undergraduate honors students by sharing this collection exclusively with the ASU community.
Barrett accepts high performing, academically engaged undergraduate students and works with them in collaboration with all of the other academic units at Arizona State University. All Barrett students complete a thesis or creative project which is an opportunity to explore an intellectual interest and produce an original piece of scholarly research. The thesis or creative project is supervised and defended in front of a faculty committee. Students are able to engage with professors who are nationally recognized in their fields and committed to working with honors students. Completing a Barrett thesis or creative project is an opportunity for undergraduate honors students to contribute to the ASU academic community in a meaningful way.
Humans use emotions to communicate social cues to our peers on a daily basis. Are we able to identify context from facial expressions and match them to specific scenarios? This experiment found that people can effectively distinguish negative and positive emotions from each other from a short description. However, further research is needed to find out whether humans can learn to perceive emotions only from contextual explanations.
Radiation hardening of electronic devices is generally necessary when designing for the space environment. Non-volatile memory technologies are of particular concern when designing for the mitigation of radiation effects. Among other radiation effects, single-event upsets can create bit flips in non-volatile memories, leading to data corruption. In this paper, a Verilog implementation of a Reed-Solomon error-correcting code is considered for its ability to mitigate the effects of single-event upsets on non-volatile memories. This implementation is compared with the simpler procedure of using triple modular redundancy.
In collaboration with Moog Broad Reach and Arizona State University, a<br/>team of five undergraduate students designed a hardware design solution for<br/>protecting flash memory data in a spaced-based radioactive environment. Team<br/>Aegis have been working on the research, design, and implementation of a<br/>Verilog- and Python-based error correction code using a Reed-Solomon method<br/>to identify bit changes of error code. For an additional senior design project, a<br/>Python code was implemented that runs statistical analysis to identify whether<br/>the error correction code is more effective than a triple-redundancy check as well<br/>as determining if the presence of errors can be modeled by a regression model.
The colossal global counterfeit market and advances in cryptography including quantum computing supremacy have led the drive for a class of anti-counterfeit tags that are physically unclonable. Dendrites, previously considered an undesirable side effect of battery operation, have promise as an extremely versatile version of such tags, with their fundamental nature ensuring that no two dendrites are alike and that they can be read at multiple magnification scales. In this work, we first pursue a simulation for electrochemical dendrites that elucidates fundamental information about their growth mechanism. We then translate these results into physical dendrites and demonstrate methods of producing a hash from these dendrites that is damage-tolerant for real-world verification. Finally, we explore theoretical curiosities that arise from the fractal nature of dendrites. We find that uniquely ramified dendrites, which rely on lower ion mobility and conductive deposition, are particularly amenable to wavelet hashing, and demonstrate that these dendrites have strong commercial potential for securing supply chains at the highest level while maintaining a low price point.
Chloe Bosmeny and Audree López, senior marketing students at W. P. Carey have created a proposal for W. P. Carey School of Business and Herberger Institute for Design and the Arts to join together to create an interdisciplinary resource for students interested in pursuing a career in fashion. There are three recommendations in the thesis: the implementation of a Fashion Merchandising certificate encompassing both W. P. Carey and Herberger curriculum, ASU joining the Fashion Institute of Technology’s 3+1 program for dual degrees in New York City, and lastly, improving professional development and career recruitment for ASU students interested in fashion.
But why fashion at Arizona State University? Throughout college, Bosmeny and López struggled to gain the background, skills and experience needed to understand the fashion industry. They, like many of their peers, felt that without the credentials of a university-sponsored fashion program, they weren't marketable to employers. These challenges drove Bosmeny and López to advocate for more fashion resources at ASU.
Based on support from student surveys, in-depth interviews with industry professionals, feedback from ASU Alumni and input from ASU’s largest fashion organization, The Business of Fashion Club- there is a strong desire for increased fashion programming at ASU. There are currently 266 student theses surrounding the keyword “fashion” from Barrett, the Honors College, but there has not been a direct push from students to implement a program at ASU. This thesis aims to illustrate the important ways such programming will greatly benefit ASU and its stakeholders.
In our thesis we will investigate current ASU opportunities related to fashion, gather information from fashion business professionals, gauge student interest in pursuing careers in fashion, and look to peer and aspirational schools in an effort to better understand fashion career resources nationwide. Our hope is to build a stronger curriculum and more successful resources for students to give them the skillsets needed for a successful career in fashion.
