Establishing metrics and control laws for the learning process: ball and beam balancing

Buza, Gergely; Milton, John; Bencsik, László; Insperger, Tamás

doi:10.1007/s00422-020-00815-z

Cited by 13 publications

(13 citation statements)

References 48 publications

(63 reference statements)

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“…No significant changes were observed on the parameters over the trials implying that the identified feedback mechanism has been already learned and practiced before during the activities of daily living. The effect of learning process is more pronounced when a new and unknown task is to be performed, e.g, ball-and-beam balancing 45 , balancing on balance board 54 , beam walking 55 or combined quiet standing and stick balancing 28 . A question arises whether practice or other techniques can be developed to further improve the performance against sudden perturbations.…”

Section: Discussionmentioning

confidence: 99%

“…Lighter shaded region to the right of the dashed line is associated with Im(λ 1 ) > 0 and the corresponding solution component reads B 1 e λ 1 t +B 1 eλ 1 t , which is oscillatory with angular frequency Im(λ 1 ) (hereλ 1 andB 1 are the complex conjugate of λ 1 and B 1 , respectively). The black-green dashed line is called node-spiral separation line since it separates node type and spiral type solutions 45 . Note that the point (p * , d * ) corresponding to the fastest response lies on the node-spiral separation line.…”

Section: Mathematical Modelmentioning

confidence: 99%

“…We pose three hypotheses related to the location of the fitted control gains. We base our hypotheses on three observations: 1) PD controllers with gains located in the lower left quadrant of the stability diagram are most robust to the effects of random perturbations 43 ; 2) expert pole balancers increase maneuverability while minimizing energetic costs for balance control by adapting gains in the lower left quadrant of the stability diagram 44 ; and 3) the control gains for subjects who do ball-and-beam balancing are progressively tuned towards the node-spiral separation line as their skill improves 45 . Statistical analysis show that H1 and H3 are accepted and H2 is rejected.…”

Section: Introductionmentioning

confidence: 99%

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Response to Perturbation During Quiet Standing Matches Delayed State Feedback With Precisely Tuned Control Gains

Zelei¹,

Milton

Stépàn

et al. 2021

Preprint

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Postural sway is a result of a complex action-reaction feedback mechanism generated by the interplay between the environment, the sensory perception, the neural system and the musculation. Postural oscillations are complex, possibly even chaotic. Therefore fitting deterministic models on measured time signals is ambiguous. Here we analyse the response to large enough perturbations during quiet standing such that the resulting responses can clearly be distinguished from the local postural sway. Measurements show that typical responses very closely resemble those of a critically damped oscillator. The recovery dynamics is modelled by an inverted pendulum subject to delayed state feedback and is described in the space of the control parameters. We hypothesize that the control gains are tuned such that (H1) the response is at the border of oscillatory and nonoscillatory motion; (H2) the response is the fastest possible; (H3) the response is a result of a combined optimization of fast response and robustness to sensory perturbations. Parameter fitting shows that H1 and H3 are accepted while H2 is rejected. Thus, the responses of human postural balance to “large” perturbations matches a delayed feedback mechanism that is optimized for a combination of performance and robustness.

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Section: Discussionmentioning

confidence: 99%

Section: Mathematical Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Response to Perturbation During Quiet Standing Matches Delayed State Feedback With Precisely Tuned Control Gains

Zelei¹,

Milton

Stépàn

et al. 2021

Preprint

Self Cite

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“…Since the model of the human body and the operation of the CNS involve many uncertain parameters, it is advantageous to consider tasks associated with low-degree-of-freedom mechanical models with well-defined physical properties. For instance, stick balancing [4,6,11,16], ankle strategy during quiet standing [5,9,15,17,18] and ball and beam balancing [19] are often modelled as a single inverted pendulum system, while ankle-hip strategy during quiet standing [20,21] and standing on a balance board [22][23][24] are modelled as a generalized double inverted pendulum.…”

Section: Introductionmentioning

confidence: 99%

Rolling balance board of adjustable geometry as a tool to assess balancing skill and to estimate reaction time delay

Molnar

Zelei²,

Insperger

2021

J. R. Soc. Interface.

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The relation between balancing performance and reaction time is investigated for human subjects balancing on rolling balance board of adjustable physical parameters: adjustable rolling radius R and adjustable board elevation h . A well-defined measure of balancing performance is whether a subject can or cannot balance on balance board with a given geometry ( R , h ). The balancing ability is linked to the stabilizability of the underlying two-degree-of-freedom mechanical model subject to a delayed proportional–derivative feedback control. Although different sensory perceptions involve different reaction times at different hierarchical feedback loops, their effect is modelled as a single lumped reaction time delay. Stabilizability is investigated in terms of the time delay in the mechanical model: if the delay is larger than a critical value (critical delay), then no stabilizing feedback control exists. Series of balancing trials by 15 human subjects show that it is more difficult to balance on balance board configuration associated with smaller critical delay, than on balance boards associated with larger critical delay. Experiments verify the feature of the mechanical model that a change in the rolling radius R results in larger change in the difficulty of the task than the same change in the board elevation h does. The rolling balance board characterized by the two well-defined parameters R and h can therefore be a useful device to assess human balancing skill and to estimate the corresponding lumped reaction time delay.

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“…The behavior of the CNS can be analyzed by performing simple balancing tasks that can be described by lowdegree-of-freedom mechanical models. For example, stick balancing [9][10][11], ankle strategy during quiet standing [12][13][14][15] and ball and beam [16] balancing are often modelled as a single-segment single-joint inverted pendulum, while hip strategy during quiet standing [17][18][19] and standing on a balance board [20][21][22] are modelled as a system of double inverted pendulum.…”

Section: Introductionmentioning

confidence: 99%

Parametric Study of Changes in Human Balancing Skill by Repeated Balancing Trials on Rolling Balance Board

Molnar

Insperger

2020

Period. Polytech. Mech. Eng.

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Dynamic balance conditions were realized by asking eight volunteers to stand on uniaxial balance board with adjustable geometry and to carry out 60 s long balancing trials. Four different balance board geometry were used, each associated with different difficulty level. Balancing trials were repeated five times weekly (learning period) in order to test improvement of balancing skill. The measurement was repeated eight weeks after the learning period in order to check the persistence of the balancing skill (confirmation session). Oscillations of ankle angle and hip angle were monitored by OptiTrack motion capture system and four stabilometry parameters were used to characterize improvement in balancing performance, namely, Standard Deviation (STD), Largest Amplitude (LA), Normalized Path Length (NPL) and Mean Power Frequency (MPF). STD and NPL show similar tendency to the preliminary expectations, therefore they can be considered as good measures to describe balancing performance. Results show that subjects used ankle strategy for the less difficult balance board configurations, while for the more difficult tasks, hip strategy was also involved. Changes in STD and NPL during the learning period showed that the improvement and the persistence in balancing skill is more significant for more difficult balancing tasks.

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Establishing metrics and control laws for the learning process: ball and beam balancing

Cited by 13 publications

References 48 publications

Response to Perturbation During Quiet Standing Matches Delayed State Feedback With Precisely Tuned Control Gains

Response to Perturbation During Quiet Standing Matches Delayed State Feedback With Precisely Tuned Control Gains

Rolling balance board of adjustable geometry as a tool to assess balancing skill and to estimate reaction time delay

Parametric Study of Changes in Human Balancing Skill by Repeated Balancing Trials on Rolling Balance Board

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