Uncertainty propagation in multibody human model dynamics

Muller, Antoine; Pontonnier, Charles; Dumont, Georges

doi:10.1007/s11044-017-9566-7

Cited by 14 publications

(5 citation statements)

References 35 publications

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“…Yet, when reported, methodological differences in kinetic and kinematic acquisition (opto-electronic motion capture system, system based on inertial measurement units) and in data processing (musculoskeletal model used for computation of joint angles and moments [ 66 , 67 ], point and basis of expression of net joint moments [ 68 , 69 ]) hinder rigorous comparisons of studies on the same barrier, and prevent the formulation of a reliable evidence-based synthesis of the propulsion biomechanics for each barrier. Lastly, poor data acquisition accuracy may lead to improper conclusions, especially for kinematics and kinetics quantities [ 70 , 71 ]. This observation may explain some of the contradictory results reported in the studies such as those involving slopes.…”

Section: Discussionmentioning

confidence: 99%

Manual wheelchair biomechanics while overcoming various environmental barriers: A systematic review

et al. 2022

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During manual wheelchair (MWC) locomotion, the user’s upper limbs are subject to heavy stresses and fatigue because the upper body is permanently engaged to propel the MWC. These stresses and fatigue vary according to the environmental barriers encountered outdoors along a given path. This study aimed at conducting a systematic review of the literature assessing the biomechanics of MWC users crossing various situations, which represent physical environmental barriers. Through a systematic search on PubMed, 34 articles were selected and classified according to the investigated environmental barriers: slope; cross-slope; curb; and ground type. For each barrier, biomechanical parameters were divided into four categories: spatiotemporal parameters; kinematics; kinetics; and muscle activity. All results from the different studies were gathered, including numerical data, and assessed with respect to the methodology used in each study. This review sheds light on the fact that certain situations (cross-slopes and curbs) or parameters (kinematics) have scarcely been studied, and that a wider set of situations should be studied. Five recommendations were made at the end of this review process to standardize the procedure when reporting materials, methods, and results for the study of biomechanics of any environmental barrier encountered in MWC locomotion: (i) effectively reporting barriers’ lengths, grades, or heights; (ii) striving for standardization or a report of the approach conditions of the barrier, such as velocity, especially on curbs; (iii) reporting the configuration of the used MWC, and if it was fitted to the subject’s morphology; (iv) reporting rotation sequences for the expression of moments and kinematics, and when used, the definition of the musculoskeletal model; lastly (v) when possible, reporting measurement uncertainties and model reconstruction errors.

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Section: Discussionmentioning

confidence: 99%

Manual wheelchair biomechanics while overcoming various environmental barriers: A systematic review

et al. 2022

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“…Fourthly, BSIP were extracted from anthropometric tables. Errors in BSIP estimation induce errors in GRF prediction [ 38 ] and in joint torque estimation [ 39 , 40 ]. Improving the estimation of BSIP using calibration methods could improve the joint torque estimation, especially for subjects distant from the 50th percentile.…”

Section: Discussionmentioning

confidence: 99%

“…An interesting extension of this current study would be to adapt prediction methods to wearable technologies such as magnetic and inertial measurement units [ 41 – 43 ], depth cameras [ 44 , 45 ] or video cameras [ 46 ]. Since the accuracy of kinematic data plays a major role in prediction methods [ 38 ], studies must be carried out to verify the accuracy levels that can be obtained with this type of instrumentation.…”

Section: Discussionmentioning

confidence: 99%

Back loading estimation during team handling: Is the use of only motion data sufficient?

Muller

Corbeil

2020

PLoS ONE

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Analyzing back loading during team manual handling tasks requires the measurement of external contacts and is thus limited to standardized tasks. This paper evaluates the possibility of estimating L5/S1 joint moments based solely on motion data. Ten subjects constituted five two-person teams and handling tasks were analyzed with four different box configurations. Three prediction methods for estimating L5/S1 joint moments were evaluated by comparing them to a gold standard using force platforms: one used only motion data, another used motion data and the traction/compression force applied to the box and one used motion data and the ground reaction forces of one team member. The three prediction methods were based on a contact model with an optimization-based method. Using only motion data did not allow an accurate estimate due to the traction/compression force applied by each team member, which affected L5/S1 joint moments. Back loading can be estimated using motion data and the measurement of the traction/compression force with relatively small errors, comparable to the uncertainty levels reported in other studies. The traction/compression force can be obtained directly with a force measurement unit built into the object to be moved or indirectly by using force platforms on which one of the two handlers stands during the handling task. The use of the proposed prediction methods allows team manual handling tasks to be analyzed in various realistic contexts, with team members who have different anthropometric measurements and with different box characteristics.

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“…Pioneering work by Zatsiorsky and Seluyanov (1983) – which was later advanced by De Leva (1996) – developed mathematical equations to characterize the inertial properties of each body segment. Efforts continue to develop new methods to improve model assumptions and reduce measurement errors (El Habachi et al, 2015; Muller et al, 2017; Rao et al, 2006; Reinbolt et al, 2007). Advanced imaging is leveraged to develop subject specific musculoskeletal models (Davidson et al, 2008; Sheets et al, 2010), and techniques like the residual reduction algorithm reconcile dynamic inconsistencies between mass properties and experimental measurements (Delp et al, 2007; Langenderfer et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Experimental recommendations for estimating lower extremity loading based on joint and activity

Hullfish

Drazan

Baxter

2021

Preprint

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Researchers often estimate joint loading using musculoskeletal models to solve the inverse dynamics problem. This approach is powerful because it can be done non-invasively, however, it relies on assumptions and physical measurements that are prone to measurement error. The purpose of this study was to determine the impact of these errors - specifically, segment mass and shear ground reaction force - have on analyzing joint loads during activities of daily living. We preformed traditional marker-based motion capture analysis on 8 healthy adults while they completed a battery of exercises on 6 degree of freedom force plates. We then scaled the mass of each segment as well as the shear component of the ground reaction force in 5% increments between 0 and 200% and iteratively performed inverse dynamics calculations, resulting in 1,681 mass-shear combinations per activity. We compared the peak joint moments of the ankle, knee, and hip at each mass-shear combination to the 100% mass and 100% shear combination to determine the percent error. We found that the ankle was most resistant to changes in both mass and shear and the knee was resistant to changes in mass while the hip was sensitive to changes in both mass and shear. These results can help guide researchers who are pursuing lower-cost or more convenient data collection setups.

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Uncertainty propagation in multibody human model dynamics

Cited by 14 publications

References 35 publications

Manual wheelchair biomechanics while overcoming various environmental barriers: A systematic review

Manual wheelchair biomechanics while overcoming various environmental barriers: A systematic review

Back loading estimation during team handling: Is the use of only motion data sufficient?

Experimental recommendations for estimating lower extremity loading based on joint and activity

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