TY - GEN
T1 - Statistical machine learning for automatic assessment of physical activity intensity using multi-axial accelerometry and heart rate
AU - García-García, Fernando
AU - García-Sáez, Gema
AU - Chausa, Paloma
AU - Martínez-Sarriegui, Iñaki
AU - Benito, Pedro José
AU - Gómez, Enrique J.
AU - Hernando, M. Elena
PY - 2011
Y1 - 2011
N2 - This work explores the automatic recognition of physical activity intensity patterns from multi-axial accelerometry and heart rate signals. Data collection was carried out in free-living conditions and in three controlled gymnasium circuits, for a total amount of 179.80 h of data divided into: sedentary situations (65.5%), light-to-moderate activity (17.6%) and vigorous exercise (16.9%). The proposed machine learning algorithms comprise the following steps: time-domain feature definition, standardization and PCA projection, unsupervised clustering (by k-means and GMM) and a HMM to account for long-term temporal trends. Performance was evaluated by 30 runs of a 10-fold cross-validation. Both k-means and GMM-based approaches yielded high overall accuracy (86.97% and 85.03%, respectively) and, given the imbalance of the dataset, meritorious F-measures (up to 77.88%) for non-sedentary cases. Classification errors tended to be concentrated around transients, what constrains their practical impact. Hence, we consider our proposal to be suitable for 24 h-based monitoring of physical activity in ambulatory scenarios and a first step towards intensity-specific energy expenditure estimators.
AB - This work explores the automatic recognition of physical activity intensity patterns from multi-axial accelerometry and heart rate signals. Data collection was carried out in free-living conditions and in three controlled gymnasium circuits, for a total amount of 179.80 h of data divided into: sedentary situations (65.5%), light-to-moderate activity (17.6%) and vigorous exercise (16.9%). The proposed machine learning algorithms comprise the following steps: time-domain feature definition, standardization and PCA projection, unsupervised clustering (by k-means and GMM) and a HMM to account for long-term temporal trends. Performance was evaluated by 30 runs of a 10-fold cross-validation. Both k-means and GMM-based approaches yielded high overall accuracy (86.97% and 85.03%, respectively) and, given the imbalance of the dataset, meritorious F-measures (up to 77.88%) for non-sedentary cases. Classification errors tended to be concentrated around transients, what constrains their practical impact. Hence, we consider our proposal to be suitable for 24 h-based monitoring of physical activity in ambulatory scenarios and a first step towards intensity-specific energy expenditure estimators.
KW - F-measure
KW - Gaussian Mixture Models
KW - Hidden Markov Models
KW - accelerometry
KW - heart rate
KW - k-means
KW - physical activity intensity
UR - https://www.scopus.com/pages/publications/80052992804
U2 - 10.1007/978-3-642-22218-4_9
DO - 10.1007/978-3-642-22218-4_9
M3 - Conference contribution
AN - SCOPUS:80052992804
SN - 9783642222177
T3 - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
SP - 70
EP - 79
BT - Artificial Intelligence in Medicine - 13th Conference on Artificial Intelligence in Medicine, AIME 2011, Proceedings
T2 - 13th Conference on Artificial Intelligence in Medicine, AIME 2011
Y2 - 2 July 2011 through 6 July 2011
ER -