Abstract
Data gloves capable of measuring finger joint kinematics can provide objective range of motion information useful for clinical hand assessment and rehabilitation. Data glove sensors are strategically placed over specific finger joints to detect movement of the wearers’ hand. The construction of the sensors used in a data glove, the number of sensors used, and their positioning on each finger joint are influenced by the intended use case. Although most glove sensors provide reasonably stable linear output, this stability is influenced externally by the physical structure of the data glove sensors, as well as the wearer’s hand size relative to the data glove, and the elastic nature of materials used in its construction. Data gloves typically require a complex calibration method before use. Calibration may not be possible when wearers have disabled hands or limited joint flexibility, and so limits those who can use a data glove within a clinical context. This paper examines and describes a unique approach to calibration and angular calculation using a neural network that improves data glove repeatability and accuracy measurements without the requirement for data glove calibration. Results demonstrate an overall improvement in data glove measurements. This is particularly relevant when the data glove is used with those who have limited joint mobility and cannot physically complete data glove calibration.
Highlights
Sensor data gloves have been successfully used in many use cases to detect finger joint movement of the hand including virtual reality (VR) [1], robot control [2], gesture recognition [3], animation modeling [4], medicine [5] and rehabilitation [6]
Results from test C showed that angles generated linearly were minimally affected by the glove donning and doffing procedure, which suggested that a set of data glove calibrations are sufficient when using a data glove
The results for test D are demonstrated as Pearson’s correlation coefficients (R2 ) that are used to compare the measure of linear correlation between measurements generated from the linear and neural networks (NN) methods with traditional goniometric measurement
Summary
Sensor data gloves have been successfully used in many use cases to detect finger joint movement of the hand including virtual reality (VR) [1], robot control [2], gesture recognition [3], animation modeling [4], medicine [5] and rehabilitation [6]. Mainstream data gloves typically use piezoresistive [7], fiber-optic [8], hall effect [9] or inertial measurement unit (IMU) [10] sensors to detect finger joint movement. Knuckle and palm length and circumference differ, as do range of motion (ROM) values between each finger joint, and between genders [18,19]. Typical flexion ROM at metacarpophalangeal (MCP) and proximal interphalangeal (PIP) finger joints increase linearly from the index to little finger by up to 13 degrees [5,13,20]. Goniometric studies focusing on the effects of age on ROM [21] found a correlation between age and decreasing joint flexion. Women generally have greater hyper-extension flexibility for all finger joints than men [20]
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