3D printing prosthetics for amputees is an innovative opportunity to provide a lower cost and customized alternative to current technologies. Companies, such as E-NABLE and YouBionic are developing myoelectric prosthetics, electrically powered terminal devices activated by electromyography (EMG), for transradial amputees. Prosthetics that are 3D printed are less expensive for juvenile use, more sustainable, and more accessible for those without insurance. Although they are typically not outfitted with the same complex grip patterns or durability of a traditional myoelectric prosthetic, they offer a sufficient durability (withstanding up to 150 N on average) and allow for new opportunities in prosthetic development. Devils Prosthetics, a student research and development group associated with Engineering Projects in Community Service (EPICS), has investigated the benefits and pitfalls of utilizing polyethylene terephthalate glycol (PETG) for 3D printing prosthetics as well as combining a MyoWare EMG sensor with machine learning for optimal control of the prosthetic.

3D printing prosthetics for amputees is an innovative opportunity to provide a lower cost and customized alternative to current technologies. Companies, such as E-NABLE and YouBionic are developing myoelectric prosthetics, electrically powered terminal devices activated by electromyography (EMG), for transradial amputees. Prosthetics that are 3D printed are less expensive for juvenile use, more sustainable, and more accessible for those without insurance. Although they are typically not outfitted with the same complex grip patterns or durability of a traditional myoelectric prosthetic, they offer a sufficient durability (withstanding up to 150 N on average) and allow for new opportunities in prosthetic development. Devils Prosthetics, a student research and development group associated with Engineering Projects in Community Service (EPICS), has investigated the benefits and pitfalls of utilizing polyethylene terephthalate glycol (PETG) for 3D printing prosthetics as well as combining a MyoWare EMG sensor with machine learning for optimal control of the prosthetic.

This honors thesis proposes a sustainable solution for providing off-grid solar energy to rural communities lacking grid energy infrastructure. The proposed design emphasizes sustainability, low cost, reliability, and ease of maintenance and manufacturing. The report compares pre-built solar systems currently available for purchase with the proposed design. The project includes a user manual draft to ensure long-term sustainability and troubleshooting. Additionally, there is a detailed engineering design for a battery storage solution, electrical component design, and solar panel mounting system. A rural community in northern Arizona serves as an example for the project completed in collaboration with ASU's EPICS program and EWB Chapter. The project is ongoing, with future work to optimize and improve the proposed system design.

This honors thesis proposes a sustainable solution for providing off-grid solar energy to rural communities lacking grid energy infrastructure. The proposed design emphasizes sustainability, low cost, reliability, and ease of maintenance and manufacturing. The report compares pre-built solar systems currently available for purchase with the proposed design. The project includes a user manual draft to ensure long-term sustainability and troubleshooting. Additionally, there is a detailed engineering design for a battery storage solution, electrical component design, and solar panel mounting system. A rural community in northern Arizona serves as an example for the project completed in collaboration with ASU's EPICS program and EWB Chapter. The project is ongoing, with future work to optimize and improve the proposed system design.