STEM Project Research
Reference Websites
Jan 5, 2002 ... The purpose of this paper was to determine the energy input, return and dissipation of sport surfaces using the FE analysis based on actual ...
onlinelibrary.wiley.comDec 25, 2001 ... ... Sports Engineering · Volume 3, Issue 4 p. 205-218 Sports Engineering ... energy losses in the pole plant and take-off phases of the vault. A ...
onlinelibrary.wiley.comNov 14, 2002 ... ... Sports Engineering · Volume 5, Issue 4 p. 173-182 Sports Engineering. Drag levels and energy requirements on a SCUBA diver. M. A. Passmore ...
onlinelibrary.wiley.com
Dec 25, 2001 ... ... Sports Engineering · Volume 3, Issue 4 p. 205-218 Sports Engineering. Full Access. Energy loss in the pole vault take-off and the advantage of ...
onlinelibrary.wiley.comOct 9, 2021 ... Ákos Kmetty, Department of Polymer Engineering, Faculty of Mechanical Engineering, Budapest University of Technology and Economics, Muegyetem ...
onlinelibrary.wiley.comAug 19, 2021 ... Lower-limb motion monitoring is highly desired in various application scenarios ranging from rehabilitation to sports training.
onlinelibrary.wiley.comAug 19, 2021 ... A Motion Capturing and Energy Harvesting Hybridized Lower-Limb System for Rehabilitation and Sports Applications ... Engineering Drive 3 ...
onlinelibrary.wiley.comJul 16, 2017 ... MIT 3-Sigma Sports aims to solve the biggest engineering problems across sports. ... energy-harvesting shoe to convert each stride into power.
news.mit.eduDec 21, 2001 ... Since for an elastic ball there are no energy losses due to inelastic material behaviour, the analysis assumes that all energy losses are ...
onlinelibrary.wiley.comFeb 3, 1999 ... ... Energy storage and return in sport surfaces · Baroud, Nigg, Stefanyshyn,. Pages: 173-180; First Published: 05 January 2002. Abstract · PDF ...
onlinelibrary.wiley.comAI-Generated Project Ideas
- Designing an energy-efficient soccer ball: Create a soccer ball that captures and stores energy generated during play to power small electronic devices.
- Building a wind-powered skateboard: Construct a skateboard with a small wind turbine that generates renewable energy while cruising, which can be used to charge a built-in battery.
- Developing a smart basketball: Design a basketball embedded with sensors to track shot accuracy, provide real-time feedback on dribbling techniques, and monitor player performance during basketball games.
- Constructing a solar-powered remote-controlled car: Build a remote-controlled car that operates solely on solar energy. Explore different methods of harnessing solar power and optimizing the car's performance.
- Designing an energy-efficient solar-powered bike: Investigate the use of solar panels to power a bicycle. Explore different designs and materials to optimize energy conversion and storage, and evaluate the overall efficiency and performance of the solar-powered bike.
- Enhancing sports performance through biomechanical engineering: Study different sports movements and analyze the biomechanical aspects involved, such as force, motion, and energy transfer. Develop innovative equipment or techniques using engineering principles to improve athletes' performance and reduce the risk of injuries.
- Generating electricity from sports activities: Explore the possibility of harnessing energy from physical activities during sports by incorporating energy-generating devices into sports equipment. Investigate how motion, impact, or pressure can be converted into electrical energy and assess the efficiency of different energy conversion mechanisms.
- Designing an eco-friendly stadium: Focus on sustainable engineering practices in stadium design. Analyze the energy usage and environmental impact of traditional stadiums and propose innovative ideas to minimize energy consumption, utilize renewable energy sources, and implement efficient waste management systems.