My heel strikes the pavement, calf muscles flexed to brace for the mechanical load of the impact. As my weight shifts forward, I imagine horizontal velocity vectors extending directly ahead. The angle created by my knee increases as I hit the propulsion phase of my stride, and with a final drive of force, I push off from my forefoot.
I discovered my fascination with sports biomechanics in the USC Biomechanics Research Lab. In my research project, I apply scientific principles to running to prevent stress-induced injuries in athletes. By analyzing video frames of PAC-12 athletes in motion and linking them to force plate data, I seek to understand the forces behind running. Comparing these conclusions to the data of athletes after a stress fracture, I can deduce the tangible differences that increase susceptibility to injury. To accomplish this goal, I have learned to use Python and MATLAB to sync the video and force plate data to create graphs for analysis. I have also used sports analysis programs to identify the locations of joints in individual frames and create videos overlaid by force vectors. Through this work, I hope to use my passion for sports biomechanics to improve the health of athletes.
My interest in sports biomechanics also extends outside of the lab, where I see my knowledge in motion. Neighborhood runs are scientific feats where I analyze my movements with principles of physics. With every step, I seek to improve my performance, putting sports biomechanics into action as an athlete.
