Fusion Motion Capture set to revolutionise biomechanical analysis

Brodie developed FMC to measure a complete ski run and the gear he put together enables us to measure for the first time how a human performs complex tasks in the everyday world. The subject is free to travel unconstrained for any length of time while fusion motion capture collects their movement data.

Biomechanical analysis of most sports is routine at the elite level these days, and is usually done using video but there have been some sports which are very difficult to do this with because the sportspeople travel over longer distances or difficult terrain. Skiing in particular brings an enormous challenge to measuring the real-time biomechanics of athletes, because, as Brodie explains, “there just aren’t enough cameras available to do things in the traditional way.” While video analysis requires several weeks to measure only a few movements, FMC is able to collect and analyze several hundred turns in a single day.

The development in FMC for real time sports monitoring in the hostile and difficult alpine environment is hence very relevant for cross country runners, sailors, rowers, cyclists, and a host of other out-and-about sports. The data is stored on the athlete and analysis is performed later.

Brodie’s thesis which will be finished later this year, is titled 'The Optimisation of Athlete Movement in Alpine Ski Racing'. His Fusion Motion Capture (FMC) technology was developed to capture the 3D kinetics and kinematics of alpine ski racing using inertial sensors, pressure pads and GPS.

The system uses sensors attached to the athlete’s limbs, helmet and feet to generate raw data from the athlete’s movement. The numbers are then crunched with the aid of a computer to reproduce accurate estimates of the position, velocity and acceleration of the athlete’s limb segments.

FMC is a general term to describe motion capture when several different streams of data are fused to measure athlete motion. Brodie combines inertial measurement units (IMU), global positioning system (GPS), pressure sensitive insoles, video and theodolite measurements to obtain his raw data though in the future, it’s possible that other data might be used from gyroscopes or magnetometers. GPS data is fused with local acceleration data to track the global trajectory of the athlete.

“With FMC, it is possible to capture motion and dynamics of alpine ski racing throughout the ski run while maintaining high resolution. This is the first time full body motion of an athlete skiing an entire course can be captured with results returned as soon as the run is completed”, says Brodie.

Brodie adds, “FMC-enabled biomechanical analysis which provides insights into how technique, race strategy and equipment changes can increase the athlete’s speed. It is now possible to measure how ski friction, wind drag, gravity and ground reaction forces affect performance and see how variability in technique is beneficial to race time.”

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