Gait Analysis Methods: An Overview of Wearable and  Non-Wearable Systems, Highlighting Clinical Applications

Muro-de-la-Herran, Alvaro; Garcia‐Zapirain, Begonya; Zorrilla, Amaia Méndez

doi:10.3390/s140203362

Cited by 863 publications

(620 citation statements)

References 77 publications

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“…They are widely used mainly in wearable gait analysis systems (Herran et al, 2014); Piezoresistive sensors are the most widely used in off-the-shelf platforms, mainly for gait analysis, measuring forces and moments, being sensitive to accelerations as well; Strain gauges are bonded to the surface of a mechanical structure and present relevant advantages over piezoelectric and piezoresistive sensors, such as better stability for long-term measurements, providing absolute measurements instead of relative ones (Roriz et al, 2014).…”

Section: Force Platform Designmentioning

confidence: 99%

“…There are various types of sensors used in FP: Piezoelectric sensors are known for their excellent linearity and reactivity but cannot be easily adapted to surfaces due to their large size (Duarte and Freitas, 2010;Herran et al, 2014); Capacitive sensors are based on the principle of condenser capacity changes, according to different parameters. They are widely used mainly in wearable gait analysis systems (Herran et al, 2014); Piezoresistive sensors are the most widely used in off-the-shelf platforms, mainly for gait analysis, measuring forces and moments, being sensitive to accelerations as well; Strain gauges are bonded to the surface of a mechanical structure and present relevant advantages over piezoelectric and piezoresistive sensors, such as better stability for long-term measurements, providing absolute measurements instead of relative ones (Roriz et al, 2014).…”

Section: Force Platform Designmentioning

confidence: 99%

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Development of a low cost force platform for biomechanical parameters analysis

2017

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Introduction: The maintenance of balance and body orientation during standing is essential to perform different activities. One of the devices used to measure balance them is the force platform. This device measures the ground reaction force (GRF) and displacement of the center of pressure (COP), both biomechanical parameters involved in human motion. This article proposes a new design for non-commercial low-cost force platforms for scientific research purposes. Methods for calibration and validation are also described. Methods: A force platform, developed according to International Standards of Measurement and dedicated to measuring feet contact forces was built for approximately one tenth of the cost of commercial platforms. Calibration was performed by loading known masses, centralized or distributed, on the platform. An experimental study was conducted with four volunteers in different conditions to validate and verify the practical applicability of the device. Results: The platform calibration showed an adequate connectivity, linearity and reliable measurement of the variables proposed in this research, being suitable for studies of human postural behavior. Conclusion: Based on the validation results, we believe the low-cost platform can be used as stabilometric device to measure postural control and balance in clinical or sports experiments. However future studies will be required to provide a final validation and compare its performance with other force platforms.

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Section: Force Platform Designmentioning

confidence: 99%

Section: Force Platform Designmentioning

confidence: 99%

Development of a low cost force platform for biomechanical parameters analysis

2017

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“…Although the accuracy and location where movements can be measured vary depending on the number and location of sensors, a technology has been developed lately to the level that user motions can be captured [17]. Research on hands and upper limbs or gait analysis for rehabilitation purposes has been conducted [18,19]. Research on interactive interfaces using gestures for handicapped people has also been carried out.…”

Section: Related Workmentioning

confidence: 99%

Biological-Signal-Based User-Interface System for Virtual-Reality Applications for Healthcare

2018

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Biosignal interfaces provide important data that reveal the physical status of a user, and they are used in the medical field for patient health status monitoring, medical automation, or rehabilitation services. Biosignals can be used in developing new contents, in conjunction with virtual reality, and are important factors for extracting user emotion or measuring user experience. A biological-signal-based user-interface system composed of sensor devices, a user-interface system, and an application that can extract biological-signal data from multiple biological-signal devices and be used by content developers was designed. A network-based protocol was used for unconstrained use of the device so that the biological signals can be freely received via USB, Bluetooth, WiFi, and an internal system module. A system that can extract biological-signal data from multiple biological-signal data and simultaneously extract and analyze the data from a virtual-reality-specific eye-tracking device was developed so that users who develop healthcare contents based on virtual-reality technology can easily use the biological signals.

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“…Recent advances in wearable technologies have enabled field gait analysis, outside of laboratory measurement, to evaluate the subject's function at the workplace, and during activities of daily life [9]. This can better represent the sensorimotor function of individuals, provide a more comprehensive assessment of treatment or rehabilitation programs in place, and could provide predictors of risk factors such as the risk of fall in elder adults [11].…”

Section: Introductionmentioning

confidence: 99%

An Accurate Wearable Foot Clearance Estimation System: Toward a Real-Time Measurement System

2017

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Abstract-This work presents an accurate, robust, wearable measurement system for foot clearance estimation along with algorithms to provide a real-time estimate of foot height and orientation. Different configurations of infrared distance meter sensors were used, both alone and in combination with an inertial measurement unit. In order to accurately estimate the foot clearance when in presence of daylight and when the foot orientation changes dynamically during walking, several algorithms were designed based on physics of sensors and tuned using the acquired data against a reference system. These algorithms, specific to the number of sensors, include the estimators of the foot orientation and estimators of the foot clearance. These estimators are tested on normal walking (RMS error ≤ 8.4mm) and walking with exaggerated step heights and inversion-eversion rotations. A Bayesian fusion of estimators was also implemented to better cope with the extreme and abnormal walking kinematics while maintaining a high performance for normal walking. All estimators were trained on uniformly distributed bootstrapped sub-samples of data and tested on several normal and abnormal walking data. The results proved the robustness of the proposed system against variations in the gait kinematics (|mean| ± standard deviation of error for heel and toe clearance was equal to or smaller than 3.1±9.3 mm when using a Bayesian fusion of three different estimators) and environment lighting (with an introduced error of 1 to 4% of actual distance).Index Terms-Foot clearance, infrared range meter, inertial measurement unit, Bayesian fusion.

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Gait Analysis Methods: An Overview of Wearable and Non-Wearable Systems, Highlighting Clinical Applications

Cited by 863 publications

References 77 publications

Development of a low cost force platform for biomechanical parameters analysis

Development of a low cost force platform for biomechanical parameters analysis

Biological-Signal-Based User-Interface System for Virtual-Reality Applications for Healthcare

An Accurate Wearable Foot Clearance Estimation System: Toward a Real-Time Measurement System

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