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46 results on '"Chénier, Félix"'

1. Using a quantitative assessment of propulsion biomechanics in wheelchair racing to guide the design of personalized gloves: a case study

Author

Chénier, Félix, Parent, Gerald, Leblanc, Mikaël, Bélaise, Colombe, and Andrieux, Mathieu

Subjects
Quantitative Biology - Quantitative Methods
Abstract

This study with a T-52 class wheelchair racing athlete aimed to combine quantitative biomechanical measurements to the athlete's perception to design and test different prototypes of a new kind of rigid gloves. Three personalized rigid gloves with various, fixed wrist extension angles were prototyped and tested on a treadmill in a biomechanics laboratory. The prototype with 45{\deg} wrist extension was the athlete's favourite as it reduced his perception of effort. Biomechanical assessment and user-experience data indicated that his favourite prototype increased wrist stability throughout the propulsion cycle while maintaining a very similar propulsion technique to the athlete's prior soft gloves. Moreover, the inclusion of an innovative attachment system on the new gloves allowed the athlete to put his gloves on by himself, eliminating the need for external assistance and thus significantly increasing his autonomy. This multidisciplinary approach helped to prototype and develop a new rigid personalized gloves concept and is clearly a promising avenue to tailor adaptive sports equipment to an athlete's needs., Comment: 17 pages, 6 figures

Published
2023

2. Tracking the whole-body centre of mass while seated in a wheelchair using motion capture

Author

Chénier, Félix, Marquis, Etienne, and Fleury-Rousseau, Maude

Subjects
Computer Science - Human-Computer Interaction, Physics - Biological Physics
Abstract

Estimating the position of the whole-body centre of mass (CoM) based on skin markers and anthropometric tables requires tracking the pelvis and lower body, which is impossible for wheelchair users due to occlusion. In this work, we present a method to track the user's whole-body CoM using visible markers affixed to the user and wheelchair where the user remains seated in their wheelchair, by expressing the pelvis and lower body segments in wheelchair coordinates. The accuracy of this method was evaluated on the anterior-posterior (AP) and medial-lateral (ML) axes by comparing the projected CoM to the centre of pressure measured by four force plates, for 11 able-bodied participants adopting 9 static postures that include extreme reaching postures. The estimation accuracy was within 33 mm (AP) and 9 mm (ML), with a precision within 23 mm (AP) and 12 mm (ML). Tracking the whole-body CoM during wheelchair propulsion will allow researchers to better understand the dynamics of propulsion, which may help devise new approaches to increase the energy transfer from the arms to the ground and reduce the risks of developing musculoskeletal disorders., Comment: 13 pages, 5 figures, 1 table

Published
2023

3. Interpreting the Tilt-and-Torsion Method to Express Shoulder Joint Kinematics

Author

Chénier, Félix, Alberca, Ilona, Faupin, Arnaud, and Gagnon, Dany H

Subjects
Quantitative Biology - Quantitative Methods, Physics - Medical Physics
Abstract

Background: Kinematics is studied by practitioners and researchers in different fields of practice. It is therefore critically important to adhere to a taxonomy that explicitly describes positions and movements. However, current representation methods such as cardan and Euler angles fail to report shoulder angles in a way that is easily and correctly interpreted by practitioners, and that is free from numerical instability such as gimbal lock. Methods: In this paper, we comprehensively describe the recent Tilt-and-Torsion method and compare it to the Euler YXY method currently recommended by the International Society of Biomechanics. While using the same three rotations (plane of elevation, elevation, humeral rotation), the Tilt-and-Torsion method reports humeral rotation independently from the plane of elevation. We assess how it can be used to describe shoulder angles (1) in a simulated assessment of humeral rotation with the arm at the side, which constitutes a gimbal lock position, and (2) during an experimental functional task, with 10 wheelchair basketball athletes who sprint in straight line using a sports wheelchair. Findings: In the simulated gimbal lock experiment, the Tilt-and-Torsion method provided both humeral elevation and rotation measurements, contrary to the Euler YXY method. During the wheelchair sprints, humeral rotation ranged from 14{\deg} (externally) to 13{\deg} (internally), which is consistent with typical maximal ranges of humeral rotation, compared to 65{\deg} to 50{\deg} with the Euler YXY method. Interpretation: Based on our results, we recommend that shoulder angles be expressed using Tilt-and-Torsion angles instead of Euler YXY., Comment: 19 pages, 5 figures, 2 tables

Published
2021

5. Handrim Reaction Force and Moment Assessment Using a Minimal IMU Configuration and Non-Linear Modeling Approach during Manual Wheelchair Propulsion.

Author

Aissaoui, Rachid, De Lutiis, Amaury, Feghoul, Aiman, and Chénier, Félix

Subjects
RECURRENT neural networks, WRIST joint, TORQUE, LINEAR acceleration, SHOULDER joint
Abstract

Manual wheelchair propulsion represents a repetitive and constraining task, which leads mainly to the development of joint injury in spinal cord-injured people. One of the main reasons is the load sustained by the shoulder joint during the propulsion cycle. Moreover, the load at the shoulder joint is highly correlated with the force and moment acting at the handrim level. The main objective of this study is related to the estimation of handrim reactions forces and moments during wheelchair propulsion using only a single inertial measurement unit per hand. Two approaches are proposed here: Firstly, a method of identification of a non-linear transfer function based on the Hammerstein–Wiener (HW) modeling approach was used. The latter represents a typical multi-input single output in a system engineering modeling approach. Secondly, a specific variant of recurrent neural network called BiLSTM is proposed to predict the time-series data of force and moments at the handrim level. Eleven subjects participated in this study in a linear propulsion protocol, while the forces and moments were measured by a dynamic platform. The two input signals were the linear acceleration as well the angular velocity of the wrist joint. The horizontal, vertical and sagittal moments were estimated by the two approaches. The mean average error (MAE) shows a value of 6.10 N and 4.30 N for the horizontal force for BiLSTM and HW, respectively. The results for the vertical direction show a MAE of 5.91 N and 7.59 N for BiLSTM and HW, respectively. Finally, the MAE for the sagittal moment varies from 0.96 Nm (BiLSTM) to 1.09 Nm for the HW model. The approaches seem similar with respect to the MAE and can be considered accurate knowing that the order of magnitude of the uncertainties of the dynamic platform was reported to be 2.2 N for the horizontal and vertical forces and 2.24 Nm for the sagittal moments. However, it should be noted that HW necessitates the knowledge of the average force and patterns of each subject, whereas the BiLSTM method do not involve the average patterns, which shows its superiority for time-series data prediction. The results provided in this study show the possibility of measuring dynamic forces acting at the handrim level during wheelchair manual propulsion in ecological environments. [ABSTRACT FROM AUTHOR]

Published
2024
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21. A high sample rate, wireless instrumented wheel for measuring 3D pushrim kinetics of a racing wheelchair

Author

Chénier, Félix, Pelland-Leblanc, Jean-Philippe, Parrinello, Antoine, Marquis, Etienne, Rancourt, Denis, Chénier, Félix, Pelland-Leblanc, Jean-Philippe, Parrinello, Antoine, Marquis, Etienne, and Rancourt, Denis

Abstract

In wheelchair racing, measuring pushrim kinetics such as propulsion forces and moments is paramount for improving performance and preventing injuries. However, there is currently no instrumented racing wheel that records 3D pushrim kinetics wirelessly and at a high sample rate, which is necessary for accurately analyzing wheelchair racing biomechanics. In this work, we present an instrumented wheel that measures 3D kinetics at 2500 Hz. Bidirectional wireless communication is used to interface the wheel through a smart phone. The wheel was tested with a world-class racing athlete who propelled at maximal acceleration and maximal speed on a training roller. During acceleration, the peak total force increased continuously from 186 N to 484 N while the peak tangential force was constant at 171 N ± 15 N. At higher speeds, a counterproductive tangential force was measured during the first 15 and the last 25 of the push phase, peaking at -78 N. This wheel may be of great value for both coaches and athletes to help with planning and validating training programs and adaptations to the wheelchair such as positioning. This wheel also has very high potential for further research on wheelchair racing biomechanics and on preventing shoulder pathologies associated with this sport.

Published
2020

30. Estimating pushrim temporal and kinetic measures using an instrumented treadmill during wheelchair propulsion: A concurrent validity study

Author

Gagnon, Dany H, Jouval, Camille, Chénier, Félix, Gagnon, Dany H, Jouval, Camille, and Chénier, Félix

Abstract

The use of the ground reaction forces recorded while propelling a manual wheelchair on an instrumented treadmill may represent a valuable alternative to the use of instrumented pushrim to compute temporal and kinetic parameters during propulsion. Sixteen manual wheelchair users propelled their wheelchair, equipped with instrumented pushrims (i.e., SmartWheel), on an instrumented dual-belt treadmill set a 1 m/s during a 1-minute period. Spatiotemporal (i.e., push and recovery phase durations) and kinetic measures (i.e. propulsive moments) were computed for 20 consecutive strokes for each participant. Strong associations were confirmed between between the treadmill and the instrumented pushrim for the mean duration of the push phase (r=0.98) and of the recovery phase (r=0.99). A good agreement between these two measurement instrument was also confirmed with mean differences of only 0.028s (push phase) and 0.012s (recovery phase). Strong associations were confirmed between the instrumented wheelchair pushrim and treadmill for the mean (r=0.97) and peak propulsive moments (r=0.96). A good agreement between these two measurement instruments was also confirmed with mean differences of 0.50 N.m (mean moment) and 0.71 N.m (peak moment). The use of a dual-belt instrumented treadmill represents an alternative to characterize temporal parameters and propulsive moment during manual wheelchair propulsion.

Published
2016

31. A simplified upper body model to improve the external validity of wheelchair simulators

Author

Chénier, Félix, Gagnon, Dany H, Blouin, Martine, Aissaoui, Rachid, Chénier, Félix, Gagnon, Dany H, Blouin, Martine, and Aissaoui, Rachid

Abstract

During overground wheelchair propulsion, upper body movement causes intra-cycle velocity variations that are neglected by current wheelchair simulators. This could affect the external validity of wheelchair propulsion on simulators. In this work, we investigated ways to incorporate these dynamics into the dynamic model (DM) reproduced by wheelchair simulators. We aimed to maximize the DM accuracy and minimize the number of required inputs. First, two DMs were presented: Model RL represented propulsion on a typical roller-based wheelchair simulator and model UB (upper body) represented overground propulsion, modelling the upper body as 5 rigid bodies. Then, three new DMs were presented: Model TR (trunk), model UA (upper arm) and model FA (forearm); these models simplified model UB by estimating the upper body kinematics based on the acceleration of only one segment. For all DMs, wheelchair velocity prediction was tested overground at a self-selected velocity among 19 experienced manual wheelchair users with a spinal cord injury. Upper body kinematics was reconstructed based on personalized kinematic patterns recorded on a wheelchair simulator. Models UB and UA were the most accurate: they reduced the root-mean-square intra-cycle velocity prediction error from 0.044 m/s (RL) to 0.026 m/s (UB) and 0.024 m/s (UA), and reduced the velocity peak time prediction error from -27.7 % (RL) to 1.7 % (UB) and -7.3 % (UA). Implementing model UA instead of model RL on a wheelchair simulator may improve the external validity of wheelchair propulsion on a simulator.

Published
2016

34. A new dynamic model of the wheelchair propulsion on straight and curvilinear level-ground paths.

Author

Chénier, Félix, Bigras, Pascal, and Aissaoui, Rachid

Subjects
*WHEELCHAIRS, *DYNAMOMETER, *PROPULSION systems, *DYNAMIC simulation
Abstract

Independent-roller ergometers (IREs) are commonly used to simulate the behaviour of a wheelchair propelled in a straight line. They cannot, however, simulate curvilinear propulsion. To this effect, a motorised wheelchair ergometer could be used, provided that a dynamic model of the wheelchair–user system propelled on straight and curvilinear paths (WSC) is available. In this article, we present such a WSC model, its parameter identification procedure and its prediction error. Ten healthy subjects propelled an instrumented wheelchair through a controlled path. Both IRE and WSC models estimated the rear wheels' velocities based on the users' propulsive moments. On curvilinear paths, the outward wheel shows root mean square (RMS) errors of 13% in an IRE vs 8% in a WSC. The inward wheel shows RMS errors of 21% in an IRE vs 11% in a WSC. Differences between both models are highly significant (p < 0.001). A wheelchair ergometer based on this new WSC model will be more accurate than a roller ergometer when simulating wheelchair propulsion in tight environments, where many turns are necessary. [ABSTRACT FROM AUTHOR]

Published
2015
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35. Characterization of the Immediate Effect of a Training Session on a Manual Wheelchair Simulator With Haptic Biofeedback: Towards More Effective Propulsion.

Author

Blouin, Martine, Lalumière, Mathieu, Gagnon, Dany H., Chénier, Félix, and Aissaoui, Rachid

Subjects
WHEELCHAIRS, COMPUTER simulation, PHYSIOLOGICAL control systems, SPINAL cord injuries, ROBOTICS
Abstract

Eighteen manual wheelchair users (MWUs) with spinal cord injury participated in a training session on a new manual wheelchair simulator with haptic biofeedback (HB). The training aimed to modify participants' mechanical effective force (MEF) along the push phase to achieve a target MEF pattern slightly more effective than their pre-training pattern. More HB was provided if the participants' achieved MEF pattern deviated from the target. Otherwise, less HB was provided. The deviation between the participants' achieved MEF and the target, as well as the mean achieved MEF, were computed before, during and after the training session. During the training, participants generally exceeded the target pattern at the beginning of the push cycle and achieved it towards the end. On average, participants also increased their mean MEF by up to 15.7% on the right side and 12.4% on the left side between the pre-training and training periods. Finally, eight participants could modify their MEF pattern towards the target in post-training. The simulator tested in this study represents a valuable tool for developing new wheelchair propulsion training programs. Haptic biofeedback also provides interesting potential for training MWUs to improve propulsion effectiveness. [ABSTRACT FROM AUTHOR]

Published
2015
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36. Tracking the Whole-Body Centre of Mass of Humans Seated in a Wheelchair Using Motion Capture

Author

Chénier, Félix, Marquis, Etienne, Fleury-Rousseau, Maude, Chénier, Félix, Marquis, Etienne, and Fleury-Rousseau, Maude

Abstract

Estimating the position of the whole-body centre of mass (CoM) based on skin markers and anthropometric tables requires tracking the pelvis and lower body, which is impossible for wheelchair users due to occlusion. In this work, we present a method to track the user’s whole-body CoM using visible markers affixed to the user and wheelchair where the user remains seated in their wheelchair, by expressing the pelvis and lower body segments in wheelchair coordinates. The accuracy of this method was evaluated on the anterior-posterior (AP) and medial–lateral (ML) axes by comparing the projected CoM to the centre of pressure measured by four force plates, for 11 able-bodied participants adopting 9 static postures that include extreme reaching postures. The estimation accuracy was within 33 mm (AP) and 9 mm (ML), with a precision within 23 mm (AP) and 12 mm (ML). Tracking the whole-body CoM during wheelchair propulsion will allow researchers to better understand the dynamics of propulsion, which may help devise new approaches to increase the energy transfer from the arms to the ground and reduce the risks of developing musculoskeletal disorders.

37. Impact of dribbling on spatiotemporal and kinetic parameters in wheelchair basketball athletes

Author

Chénier, Félix, Alberca, Ilona, Marquis, Etienne, Gagnon, Dany H., Faupin, Arnaud, Chénier, Félix, Alberca, Ilona, Marquis, Etienne, Gagnon, Dany H., and Faupin, Arnaud

Abstract

Background: Wheelchair basketball is one of the most popular Paralympic sports. Dribbling a ball while propelling is a key feature of wheelchair basketball. Very few studies have investigated the biomechanical impact of dribbling. This study aims to analyze the impact of dribbling on the amplitude and symmetry of spatiotemporal and kinetic parameters of wheelchair propulsion. Methods: Ten experienced wheelchair basketball athletes (31.5 ± 10.6 years old; 7 men, 3 women) with various classifications performed eight 9-m sprints along a straight line on a basketball court: four sprints using classic synchronous propulsion, and four sprints while dribbling a ball down the court. Findings: Dribbling decreased velocity, mean propulsive moments and the force rate of rise, as well as increased push time, force rate of rise asymmetry and angular impulse asymmetry. All kinetic variables were asymmetric and higher on the dominant limb. Interpretation: The combination of reduced velocity and propulsive moments when dribbling indicates that wheelchair basketball athletes may deliberately preserve a safety margin of acceleration to adapt to uncontrolled ball rebounds. Dribbling was not associated with any factors associated with an increased risk of musculoskeletal disorders.

38. Interpreting the tilt-and-torsion method to express shoulder joint kinematics

Author

Chénier, Félix, Alberca, Ilona, Faupin, Arnaud, Gagnon, Dany H., Chénier, Félix, Alberca, Ilona, Faupin, Arnaud, and Gagnon, Dany H.

Abstract

Background: Kinematics is studied by practitioners and researchers in different fields of practice. It is therefore critically important to adhere to a taxonomy that explicitly describes positions and movements. However, current representation methods such as cardan and Euler angles fail to report shoulder angles in a way that is easily and correctly interpreted by practitioners, and that is free from numerical instability such as gimbal lock. Methods: In this paper, we comprehensively describe the recent Tilt-and-Torsion method and compare it to the Euler YXY method currently recommended by the International Society of Biomechanics. While using the same three rotations (plane of elevation, elevation, humeral rotation), the Tilt-and-Torsion method reports humeral rotation independently from the plane of elevation. We assess how it can be used to describe shoulder angles (1) in a simulated assessment of humeral rotation with the arm at the side, which constitutes a gimbal lock position, and (2) during an experimental functional task, with 10 wheelchair basketball athletes who sprint in straight line using a sports wheelchair. Findings: In the simulated gimbal lock experiment, the Tilt-and-Torsion method provided both humeral elevation and rotation measurements, contrary to the Euler YXY method. During the wheelchair sprints, humeral rotation ranged from 14 deg (externally) to 13 deg (internally), which is consistent with typical maximal ranges of humeral rotation, compared to 65 deg to 50 deg with the Euler YXY method. Interpretation: Based on our results, we recommend that shoulder angles be expressed using Tilt-and-Torsion angles instead of Euler YXY.

39. Proposing a new index to quantify instantaneous symmetry during manual wheelchair propulsion

Author

Chénier, Félix, Malbequi, Julien, Gagnon, Dany H., Chénier, Félix, Malbequi, Julien, and Gagnon, Dany H.

Abstract

Propelling a manual wheelchair (MWC) is a strenuous task that causes upper limb musculoskeletal disorders (MSD) in a large proportion of MWC users. Although most studies on MWC propulsion biomechanics assume that MWC propulsion is a relatively symmetric task, recent literature suggests that this is the case only when the assessed outcome measures are averaged over long periods of time, and not over short periods (i.e., instantaneously). No method is currently available to assess instantaneous symmetry. In this work, we present the Instantaneous Symmetry Index (ISI), a new method that quantifies how a variable has been instantaneously asymmetric during a selected time period. Thirteen experienced MWC users propelled on different cross slopes of 0%, 2%, 4%, 6% and 8%. As the cross slope is increased, the upper hand produced less propulsive moments and the lower hand produced more propulsive movements. This has been reflected in the ISI, which increased from 0.20 (0% slope) to 0.84 (8% slope) with a Spearman’s coefficient of 0.90. The ISI has great potential to evaluate the ability of a user to propel symmetrically and synchronously, and will be a relevant measure to include in future studies on the impact of MWC propulsion asymmetry on MSD risk.

40. Estimating pushrim temporal and kinetic measures using an instrumented treadmill during wheelchair propulsion: A concurrent validity study

Author

Gagnon, Dany H, Jouval, Camille, Chénier, Félix, Gagnon, Dany H, Jouval, Camille, and Chénier, Félix

Abstract

The use of the ground reaction forces recorded while propelling a manual wheelchair on an instrumented treadmill may represent a valuable alternative to the use of instrumented pushrim to compute temporal and kinetic parameters during propulsion. Sixteen manual wheelchair users propelled their wheelchair, equipped with instrumented pushrims (i.e., SmartWheel), on an instrumented dual-belt treadmill set a 1 m/s during a 1-minute period. Spatiotemporal (i.e., push and recovery phase durations) and kinetic measures (i.e. propulsive moments) were computed for 20 consecutive strokes for each participant. Strong associations were confirmed between between the treadmill and the instrumented pushrim for the mean duration of the push phase (r=0.98) and of the recovery phase (r=0.99). A good agreement between these two measurement instrument was also confirmed with mean differences of only 0.028s (push phase) and 0.012s (recovery phase). Strong associations were confirmed between the instrumented wheelchair pushrim and treadmill for the mean (r=0.97) and peak propulsive moments (r=0.96). A good agreement between these two measurement instruments was also confirmed with mean differences of 0.50 N.m (mean moment) and 0.71 N.m (peak moment). The use of a dual-belt instrumented treadmill represents an alternative to characterize temporal parameters and propulsive moment during manual wheelchair propulsion.

43. A simplified upper body model to improve the external validity of wheelchair simulators

Author

Chénier, Félix, Gagnon, Dany H, Blouin, Martine, Aissaoui, Rachid, Chénier, Félix, Gagnon, Dany H, Blouin, Martine, and Aissaoui, Rachid

Abstract

During overground wheelchair propulsion, upper body movement causes intra-cycle velocity variations that are neglected by current wheelchair simulators. This could affect the external validity of wheelchair propulsion on simulators. In this work, we investigated ways to incorporate these dynamics into the dynamic model (DM) reproduced by wheelchair simulators. We aimed to maximize the DM accuracy and minimize the number of required inputs. First, two DMs were presented: Model RL represented propulsion on a typical roller-based wheelchair simulator and model UB (upper body) represented overground propulsion, modelling the upper body as 5 rigid bodies. Then, three new DMs were presented: Model TR (trunk), model UA (upper arm) and model FA (forearm); these models simplified model UB by estimating the upper body kinematics based on the acceleration of only one segment. For all DMs, wheelchair velocity prediction was tested overground at a self-selected velocity among 19 experienced manual wheelchair users with a spinal cord injury. Upper body kinematics was reconstructed based on personalized kinematic patterns recorded on a wheelchair simulator. Models UB and UA were the most accurate: they reduced the root-mean-square intra-cycle velocity prediction error from 0.044 m/s (RL) to 0.026 m/s (UB) and 0.024 m/s (UA), and reduced the velocity peak time prediction error from -27.7 % (RL) to 1.7 % (UB) and -7.3 % (UA). Implementing model UA instead of model RL on a wheelchair simulator may improve the external validity of wheelchair propulsion on a simulator.

45. A high sample rate, wireless instrumented wheel for measuring 3D pushrim kinetics of a racing wheelchair

Author

Chénier, Félix, Pelland-Leblanc, Jean-Philippe, Parrinello, Antoine, Marquis, Etienne, Rancourt, Denis, Chénier, Félix, Pelland-Leblanc, Jean-Philippe, Parrinello, Antoine, Marquis, Etienne, and Rancourt, Denis

Abstract

In wheelchair racing, measuring pushrim kinetics such as propulsion forces and moments is paramount for improving performance and preventing injuries. However, there is currently no instrumented racing wheel that records 3D pushrim kinetics wirelessly and at a high sample rate, which is necessary for accurately analyzing wheelchair racing biomechanics. In this work, we present an instrumented wheel that measures 3D kinetics at 2500 Hz. Bidirectional wireless communication is used to interface the wheel through a smart phone. The wheel was tested with a world-class racing athlete who propelled at maximal acceleration and maximal speed on a training roller. During acceleration, the peak total force increased continuously from 186 N to 484 N while the peak tangential force was constant at 171 N ± 15 N. At higher speeds, a counterproductive tangential force was measured during the first 15 and the last 25 of the push phase, peaking at -78 N. This wheel may be of great value for both coaches and athletes to help with planning and validating training programs and adaptations to the wheelchair such as positioning. This wheel also has very high potential for further research on wheelchair racing biomechanics and on preventing shoulder pathologies associated with this sport.

46. A new dynamic model of the manual wheelchair for straight and curvilinear propulsion.

Author

Chénier F, Bigras P, and Aissaoui R

Subjects
Biomechanical Phenomena, Equipment Design, Ergometry methods, Humans, Models, Theoretical, Wheelchairs
Abstract

Due to their mechanical design, current wheelchair ergometers cannot simulate the behaviour of a wheelchair propelled on curvilinear paths. This is because they implement a dynamic model of the Wheelchair-user system propelled on Straight Line only (WSL). In this paper, we present a new dynamic model of the Wheelchair-user propelled on Straight and Curvilinear paths (WSC), along with a characterization method based on measurements recorded on the field. Other than measured geometrical constants and kinetic/kinematic data from instrumented wheels, no information about the dynamic parameters such as the system's mass and its moment of inertia are necessary. The accuracy of the new WSC model was compared with the WSL model. To this end, ten subjects propelled an instrumented wheelchair following straight and curvilinear patterns. The recorded kinetics were fed to both models, and their estimated kinematics were compared to the recorded ones. For the curvilinear patterns, the RMS relative error between the estimated and measured rear wheels velocities over a complete push cycle are lower for the WSC model than for the WSL model. Outward wheel: 7.98% (WSC) vs 12.98% (WSL). Inward wheel: 10.76% (WSC) vs 20.73% (WSL)., (© 2011 IEEE)

Published
2011
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