TNO, Leiden, The Netherlands.
Med Sci Sports Exerc. 2011 Oct;43(10):1994-9. doi: 10.1249/MSS.0b013e318219d939.
The study's purpose was to identify children's physical activity type using artificial neural network (ANN) models based on uniaxial or triaxial accelerometer data from the hip or the ankle.
Fifty-eight children (31 boys and 27 girls, age range = 9-12 yr) performed the following activities in a field setting: sitting, standing, walking, running, rope skipping, playing soccer, and cycling. All children wore uniaxial and triaxial ActiGraph accelerometers on both the hip and the ankle. Four ANN models were developed using the following accelerometer signal characteristics: 10th, 25th, 75th, and 90th percentiles; absolute deviation; coefficient of variability; and lag-one autocorrelation. The accuracy of the models was evaluated by leave-one-subject-out cross-validation.
The models based on hip accelerometer data correctly classified the activities 72% and 77% of the time using uniaxial and triaxial accelerometer data, respectively, whereas the models based on ankle accelerometer data achieved a percentage of 57% and 68%. The hip models were better able to correctly classify the activities walking, rope skipping, and running, whereas the ankle models performed better when classifying sitting. The models based on triaxial accelerometer data produced a better classification of the activities standing, running, rope skipping, playing soccer, and cycling than its uniaxial counterparts.
Applying ANN models to processing accelerometer data from children is promising for classifying common physical activities. The highest percentage of correctly classified activities was achieved when using triaxial accelerometer data from the hip.
本研究旨在使用基于单轴或三轴加速度计数据(来自髋部或踝部)的人工神经网络(ANN)模型来识别儿童的身体活动类型。
58 名儿童(31 名男孩和 27 名女孩,年龄范围=9-12 岁)在野外环境中进行了以下活动:坐、站、走、跑、跳绳、踢足球和骑自行车。所有儿童均在髋部和踝部佩戴单轴和三轴 ActiGraph 加速度计。使用以下加速度计信号特征开发了四个 ANN 模型:第 10、25、75 和 90 百分位数;绝对偏差;变异系数;和滞后自相关。通过逐个受试者外交叉验证评估模型的准确性。
基于髋部加速度计数据的模型分别使用单轴和三轴加速度计数据正确分类活动的时间为 72%和 77%,而基于踝部加速度计数据的模型则分别为 57%和 68%。髋部模型能够更好地正确分类行走、跳绳和跑步等活动,而踝部模型在分类坐姿时表现更好。基于三轴加速度计数据的模型在分类站立、跑步、跳绳、踢足球和骑自行车等活动方面优于其单轴对应物。
将 ANN 模型应用于处理儿童的加速度计数据有望用于分类常见的身体活动。使用来自髋部的三轴加速度计数据可实现最高比例的正确分类活动。
