A device for augmented feedback during the practice of relay changeovers in swimming
In competitive swimming, to achieve optimal performance, an athlete must effectively combine technical skills with their physical and mental capabilities. This can be achieved through various approaches which include consistent training in swimming techniques and strengthening the body. With the...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2023
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| Online Access: | https://hdl.handle.net/10356/172894 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | In competitive swimming, to achieve optimal performance, an athlete must effectively combine
technical skills with their physical and mental capabilities. This can be achieved through
various approaches which include consistent training in swimming techniques and
strengthening the body. With the current state of technology, it is possible to enhance the
training experience of swimmers by incorporating technology into their training routines. Much
research has been conducted to investigate and optimise an athletes' swim technique and
training methods using technology such as computation fluid dynamics (CFD) and underwater
motion analysis. CFD simulates swimming strokes and examines the hydrodynamic effects of
the aquatic environment, while underwater motion analysis uses a three-dimensional motion
capture system to analyse a swimmer's underwater motions. These work together to target
adjustments to a swimmer's form and technique to improve performance. [1]. The swim start
is a crucial segment in any swimming race; how an athlete performs during a swim start can
significantly impact their race timing. The swim start consists of the Starting Block Phase,
Diving Phase, Underwater Phase, and Breakout Phase. To achieve an optimal swim start,
swimmers should practice each phase and work on seamless linking between phases. The
ability to measure forces exerted during swimming can provide valuable insights into a
swimmer’s technique, enabling coaches to identify areas for improvement [2]. The objective
of this project is to therefore develop a system that provides real-time force measurements and
analysis during swim start training with the use of sensors and microcontroller units (MCUs)
or microprocessors. This system has the potential to revolutionize swim training by providing
a level of detail and insight that was previously unavailable to the human eye. By analysing the
forces exerted by the swimmer when leaping off the starting block or tumbling on the wall,
coaches and athletes can gain a deeper understanding of the swimmer’s swim start techniques
and help make targeted improvements for them. A graphical user interface was developed to
provide live data collection results and training summaries that display the change over time
(COT), peak forces when leaping off the starting block, and the time taken to leap off the
starting block. These data will be displayed in line and bar graph formats. With these data,
scientists can also review and research new ways for athletes to improve their swimming
performance. |
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