Karol O’Donovan scite author profile

Body-worn kinematic sensors have been widely proposed as the optimal solution for portable, low cost, ambulatory monitoring of gait. This study aims to evaluate an adaptive gyroscope-based algorithm for automated temporal gait analysis using body-worn wireless gyroscopes. Gyroscope data from nine healthy adult subjects performing four walks at four different speeds were then compared against data acquired simultaneously using two force plates and an optical motion capture system. Data from a poliomyelitis patient, exhibiting pathological gait walking with and without the aid of a crutch, were also compared to the force plate. Results show that the mean true error between the adaptive gyroscope algorithm and force plate was -4.5 ± 14.4 ms and 43.4 ± 6.0 ms for IC and TC points, respectively, in healthy subjects. Similarly, the mean true error when data from the polio patient were compared against the force plate was -75.61 ± 27.53 ms and 99.20 ± 46.00 ms for IC and TC points, respectively. A comparison of the present algorithm against temporal gait parameters derived from an optical motion analysis system showed good agreement for nine healthy subjects at four speeds. These results show that the algorithm reported here could constitute the basis of a robust, portable, low-cost system for ambulatory monitoring of gait.

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The identification of vertical velocity profiles using an inertial sensor to investigate pre-impact detection of falls

Bourke

O’Donovan

ÓLaighin

2008

Medical Engineering & Physics

132

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Gyroscope-based assessment of temporal gait parameters during treadmill walking and running

et al. 2012

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SHIMMER™: An extensible platform for physiological signal capture

Burns

Doheny

Greene

et al. 2010

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Wireless sensor networks have become increasingly common in everyday applications due to decreasing technology costs and improved product performance, robustness and extensibility. Wearable physiological monitoring systems have been utilized in a variety of studies, particularly those investigating ECG or EMG during human movement or sleep monitoring. These systems require extensive validation to ensure accurate and repeatable functionality. Here we validate the physiological signals (EMG, ECG and GSR) of the SHIMMER (Sensing Health with Intelligence, Modularity, Mobility and Experimental Reusability) against known commercial systems. Signals recorded by the SHIMMER EMG, ECG and GSR daughter-boards were found to compare well to those obtained by commercial systems.

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Karol O’Donovan

An inertial and magnetic sensor based technique for joint angle measurement

An adaptive gyroscope-based algorithm for temporal gait analysis

The identification of vertical velocity profiles using an inertial sensor to investigate pre-impact detection of falls

Gyroscope-based assessment of temporal gait parameters during treadmill walking and running

SHIMMER™: An extensible platform for physiological signal capture

Contact Info

Product

Resources

About

Karol O’Donovan

An inertial and magnetic sensor based technique for joint angle measurement

An adaptive gyroscope-based algorithm for temporal gait analysis

The identification of vertical velocity profiles using an inertial sensor to investigate pre-impact detection of falls

Gyroscope-based assessment of temporal gait parameters during treadmill walking and running

SHIMMER&#x2122;: An extensible platform for physiological signal capture

Contact Info

Product

Resources

About

SHIMMER™: An extensible platform for physiological signal capture