Literature DB >> 22513724

Balancing on tightropes and slacklines.

P Paoletti1, L Mahadevan.   

Abstract

Balancing on a tightrope or a slackline is an example of a neuromechanical task where the whole body both drives and responds to the dynamics of the external environment, often on multiple timescales. Motivated by a range of neurophysiological observations, here we formulate a minimal model for this system and use optimal control theory to design a strategy for maintaining an upright position. Our analysis of the open and closed-loop dynamics shows the existence of an optimal rope sag where balancing requires minimal effort, consistent with qualitative observations and suggestive of strategies for optimizing balancing performance while standing and walking. Our consideration of the effects of nonlinearities, potential parameter coupling and delays on the overall performance shows that although these factors change the results quantitatively, the existence of an optimal strategy persists.

Entities:  

Mesh:

Year:  2012        PMID: 22513724      PMCID: PMC3405749          DOI: 10.1098/rsif.2012.0077

Source DB:  PubMed          Journal:  J R Soc Interface        ISSN: 1742-5662            Impact factor:   4.118


  23 in total

1.  On-off intermittency in a human balancing task.

Authors:  Juan L Cabrera; John G Milton
Journal:  Phys Rev Lett       Date:  2002-09-20       Impact factor: 9.161

2.  Sensorimotor integration in human postural control.

Authors:  R J Peterka
Journal:  J Neurophysiol       Date:  2002-09       Impact factor: 2.714

3.  Controlling human upright posture: velocity information is more accurate than position or acceleration.

Authors:  John Jeka; Tim Kiemel; Robert Creath; Fay Horak; Robert Peterka
Journal:  J Neurophysiol       Date:  2004-05-12       Impact factor: 2.714

4.  Balancing on a narrow ridge: biomechanics and control.

Authors:  E Otten
Journal:  Philos Trans R Soc Lond B Biol Sci       Date:  1999-05-29       Impact factor: 6.237

5.  Assessment of postural control in patients with Parkinson's disease: sway ratio analysis.

Authors:  Janusz W Błaszczyk; Renata Orawiec
Journal:  Hum Mov Sci       Date:  2010-08-30       Impact factor: 2.161

6.  Human stance control beyond steady state response and inverted pendulum simplification.

Authors:  G Schweigart; T Mergner
Journal:  Exp Brain Res       Date:  2007-11-20       Impact factor: 1.972

7.  Dynamic regulation of sensorimotor integration in human postural control.

Authors:  Robert J Peterka; Patrick J Loughlin
Journal:  J Neurophysiol       Date:  2003-09-17       Impact factor: 2.714

8.  A balance control model of quiet upright stance based on an optimal control strategy.

Authors:  Xingda Qu; Maury A Nussbaum; Michael L Madigan
Journal:  J Biomech       Date:  2007-07-12       Impact factor: 2.712

9.  Sensory adaptation in human balance control: lessons for biomimetic robotic bipeds.

Authors:  Arash Mahboobin; Patrick J Loughlin; Mark S Redfern; Stuart O Anderson; Christopher G Atkeson; Jessica K Hodgins
Journal:  Neural Netw       Date:  2008-05-14

10.  Transition from persistent to anti-persistent correlations in postural sway indicates velocity-based control.

Authors:  Didier Delignières; Kjerstin Torre; Pierre-Louis Bernard
Journal:  PLoS Comput Biol       Date:  2011-02-24       Impact factor: 4.475
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  13 in total

1.  Gravito-inertial ambiguity resolved through head stabilization.

Authors:  Ildar Farkhatdinov; Hannah Michalska; Alain Berthoz; Vincent Hayward
Journal:  Proc Math Phys Eng Sci       Date:  2019-03-27       Impact factor: 2.704

2.  Acceleration feedback improves balancing against reflex delay.

Authors:  Tamás Insperger; John Milton; Gábor Stépán
Journal:  J R Soc Interface       Date:  2013-02       Impact factor: 4.118

3.  Control at stability's edge minimizes energetic costs: expert stick balancing.

Authors:  John Milton; Ryan Meyer; Max Zhvanetsky; Sarah Ridge; Tamás Insperger
Journal:  J R Soc Interface       Date:  2016-06       Impact factor: 4.118

4.  Changes in balance coordination and transfer to an unlearned balance task after slackline training: a self-organizing map analysis.

Authors:  Ben Serrien; Erich Hohenauer; Ron Clijsen; Wolfgang Taube; Jean-Pierre Baeyens; Ursula Küng
Journal:  Exp Brain Res       Date:  2017-08-22       Impact factor: 1.972

5.  Virtual stick balancing: skill development in Newtonian and Aristotelian dynamics.

Authors:  Balazs A Kovacs; Tamas Insperger
Journal:  J R Soc Interface       Date:  2022-03-02       Impact factor: 4.118

6.  Slacklining and stroke: A rehabilitation case study considering balance and lower limb weakness.

Authors:  Charles P Gabel; Natalie Rando; Markus Melloh
Journal:  World J Orthop       Date:  2016-08-18

7.  Saturation limits the contribution of acceleration feedback to balancing against reaction delay.

Authors:  Li Zhang; Gabor Stepan; Tamas Insperger
Journal:  J R Soc Interface       Date:  2018-01       Impact factor: 4.118

8.  EEG dynamics and neural generators of psychological flow during one tightrope performance.

Authors:  A Leroy; G Cheron
Journal:  Sci Rep       Date:  2020-07-24       Impact factor: 4.379

Review 9.  Slacklining: A narrative review on the origins, neuromechanical models and therapeutic use.

Authors:  Charles Philip Gabel; Bernard Guy; Hamid Reza Mokhtarinia; Markus Melloh
Journal:  World J Orthop       Date:  2021-06-18

10.  Vestibular loss and balance training cause similar changes in human cerebral white matter fractional anisotropy.

Authors:  Nadine Hummel; Katharina Hüfner; Thomas Stephan; Jennifer Linn; Olympia Kremmyda; Thomas Brandt; Virginia L Flanagin
Journal:  PLoS One       Date:  2014-04-28       Impact factor: 3.240
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