Abstract
The design, prototyping and validation of an innovative test bench for the characterization and the hysteresis measurement of flexion sensors are presented in this paper. The device, especially designed to test sensors employed in the biomedical field, can be effectively used to characterize also sensors intended for other applications, such as wearable devices. Flexion sensors are widely adopted in devices for biomedical purposes and in this context are commonly used in two main ways: to measure movements (i) with fixed radius of curvature and (ii) with variable radius of curvature. The test bench has been conceived and designed with reference to both of these needs of use. The technological choices have been oriented towards simplicity of manufacture and assembly, configuration flexibility and low cost of realization. For this purpose, 3D printing technology was chosen for most of the structural components of the device. To verify the test bench performances, a test campaign was carried out on five commercial bending sensors. To characterize each sensor, the acquired measurements were analysed by assessing repeatability and linearity of the sensors and hysteresis of the system sensor/test bench. A statistical analysis was performed to study the positioning repeatability and the hysteresis of the device. The results demonstrate good repeatability and low hysteresis.
Highlights
The measurement of flexion or extension of specific elements in a system is a requirement that can arise in many application fields
The tests were executed with the test bench configuration for fixed radius of commercial flexion sensors to verify the test bench adequacy and to evaluate its perforcurvature
The tests were executed with the test bench configuration for fixed radius of curfor a complete evaluation on the system performance, tests were executed in this first vature
Summary
The measurement of flexion or extension of specific elements in a system is a requirement that can arise in many application fields. Some works discuss the use of flex sensors for the evaluation of the range of motion (ROM), for example for clinical monitoring in rehabilitation [6,7,8] or for monitoring body postures [9,10]. Many publications concern the development or application of instrumented gloves with flexion sensors to control exoskeletons for different purposes, such as: hand rehabilitation [11], and more generally, control of robotic devices [12,13,14], translation of sign language [15], recognition of hand gestures [16,17], development of an advanced human/computer interface [18], tele-operation [13] and prosthetic devices control [19,20]
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