Virtual Sensors for Advanced Controllers in Rehabilitation Robotics

Mancisidor, Aitziber; Cabanes, Itziar; Portillo, Eva; Jung, Je Hyung

doi:10.3390/s18030785

Cited by 9 publications

(7 citation statements)

References 30 publications

(32 reference statements)

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“…Where the error minimization result in acceptable therapy trajectories. Table (5) illustrates the error presented in joint motor responses before and after using the spring system. The above table illustrate the oscillation minimization in robot joints through the presence of the load, that means the designed spring system is working effectively, where it increases the required torque by the first joint motor in the execution phase and damping the links motion through the retraction phase, all of these results overcome via the power of the PD fuzzy controller that can overcome the oscillation with wide range of universe of discourse in input and output signals.…”

Section: Simulation Results Of the Simulated And Implemented Robotmentioning

confidence: 99%

“…Aitziber et al, proposed in 2018 the effective sensors, were used as a substitute for the actual force and motion sensors of the proposed assisting robot that used for upper limb recover. These virtual sensors established the required stimulates of force and motion at the contact points, where the person interacts with the assisting arm using the arm mathematical model [5]. In 2018, Monica, et al, provide a control structure used the electromyography signals for drive the joint motion and control the assisting arm.…”

Section: Introductionmentioning

confidence: 99%

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Design, Implementation, Interfacing and Control of Internet of Robot Things for Assisting Robot

Karam¹,

Abdulkadhim²

2022

IJCDS

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Robotic arm plays a great role in assisting the human hand in current life. This project involves the design and implementation of two degrees of freedom (DOF's) assistant arm robot for aiding humans in the medical recovery for the upper left limb motion. The contribution in this work involves three parts: the first one, design special interfacing circuits based on (Arduino card) for controlling the designed arm motion, where the motion execution and record is done by designed reading and writing circuits, these circuits controlled by a designed MATLAB fuzzy proportional derivative (PD) controller, this control structure implemented by assisting of special Arduino Simulink library In MATLAB Simulink, where it will be used for control the signals transition, a new Simulink design proposed and investigated to interfacing the controller with the arm motors and encoders via the circuits. The second contribution is adding an assisting spring system to the arm first motor joint, where this addition rises the motion stability through the control phase by increasing the required torque in the arm first joint, especially after the human hand load is attached to the robot links, where its tested effectively without needing for replacing the motor with increased torque. The results illustrate the power of these circuits design and the error reduction occurred after supporting the system's spring. The Third contribution, An Internet of robotic thing (IoRT) model is designed, and then the robot arm is connected using our designed internet -based control system using IoT protocols for communication.

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Section: Simulation Results Of the Simulated And Implemented Robotmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design, Implementation, Interfacing and Control of Internet of Robot Things for Assisting Robot

Karam¹,

Abdulkadhim²

2022

IJCDS

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“…Virtual Sensors allow to estimate the robot/user interaction force and motion [129]. It is cheaper and equally effective alternative to standard contact force and motion sensors.…”

Section: Sensory Systemmentioning

confidence: 99%

Upper Limb Bionic Orthoses: General Overview and Forecasting Changes

Rzyman¹,

Szkopek²,

Redlarski³

et al. 2020

Applied Sciences

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Using robotics in modern medicine is slowly becoming a common practice. However, there are still important life science fields which are currently devoid of such advanced technology. A noteworthy example of a life sciences field which would benefit from process automation and advanced robotic technology is rehabilitation of the upper limb with the use of an orthosis. Here, we present the state-of-the-art and prospects for development of mechanical design, actuator technology, control systems, sensor systems, and machine learning methods in rehabilitation engineering. Moreover, current technical solutions, as well as forecasts on improvement, for exoskeletons are presented and reviewed. The overview presented might be the cornerstone for future research on advanced rehabilitation engineering technology, such as an upper limb bionic orthosis.

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“…Rehabilitation exoskeletons robot are emerging as important components of the rehabilitation training process for patients affected by hemiplegia and cerebral apoplexy [ 1 , 2 ]. The rehabilitation training system comprises a lower extremity exoskeleton, where the robotics are employed for sensing, control, information fusion and mobile computing [ 3 , 4 , 5 , 6 ]. Accurate data from measurement systems can be provided to the feedback control of exoskeleton system.…”

Section: Introductionmentioning

confidence: 99%

Physical Extraction and Feature Fusion for Multi-Mode Signals in a Measurement System for Patients in Rehabilitation Exoskeleton

Yang

Wei

et al. 2018

Sensors

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Measurement system of exoskeleton robots can reflect the state of the patient. In this study, we combined an inertial measurement unit and a visual measurement unit to obtain a repeatable fusion measurement system to compensate for the deficiencies of the single data acquisition mode used by exoskeletons. Inertial measurement unit is comprised four distributed angle sensors. Triaxial acceleration and angular velocity information were transmitted to an upper computer by Bluetooth. The data sent to the control center were processed by a Kalman filter to eliminate any noise. Visual measurement unit uses camera to acquire real time images and related data information. The two data acquisition methods were fused and have its weight. Comparisons of the fusion results with individual measurement results demonstrated that the data fusion method could effectively improve the accuracy of system. It provides a set of accurate real-time measurements for patients in rehabilitation exoskeleton and data support for effective control of exoskeleton robot.

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Virtual Sensors for Advanced Controllers in Rehabilitation Robotics

Cited by 9 publications

References 30 publications

Design, Implementation, Interfacing and Control of Internet of Robot Things for Assisting Robot

Design, Implementation, Interfacing and Control of Internet of Robot Things for Assisting Robot

Upper Limb Bionic Orthoses: General Overview and Forecasting Changes

Physical Extraction and Feature Fusion for Multi-Mode Signals in a Measurement System for Patients in Rehabilitation Exoskeleton

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