University of Cambridge > Talks.cam > Isaac Newton Institute Seminar Series > An Introduction to the Mechanics of the Lasso

An Introduction to the Mechanics of the Lasso

Add to your list(s) Download to your calendar using vCal

  • UserNeil Ribe (CNRS (Centre national de la recherche scientifique); Universit√© Paris-Sud 11 )
  • ClockThursday 30 November 2017, 16:00-16:30
  • HouseSeminar Room 1, Newton Institute.

If you have a question about this talk, please contact info@newton.ac.uk.

GFSW04 - Form in art, toys and games

Co-authors: Pierre-Thomas Brun (Dept. of Chemical Engineering, Princeton University, Princeton, NJ USA ), Basile Audoly (Laboratoire LMS , Ecole Polytechnique, Palaiseau, France)

Trick roping evolved from humble origins as a cattle-catching tool into a sport that delights audiences with its complex patterns or ‘tricks’. Its fundamental tool is the lasso, formed by passing one end of a rope through a small loop (the honda) at the other end. Here, we study the mechanics of the simplest rope trick, the Flat Loop, in which the rope is driven by the steady circular motion of the roper’s hand in a horizontal plane. We first consider the case of a fixed (non-sliding) honda. Noting that the rope’s shape is steady in the reference frame rotating with the hand, we analyse a string model in which line tension is balanced by the centrifugal force and the rope’s weight. We use numerical continuation to classify the steadily rotating solutions in a bifurcation diagram and analyse their stability. In addition to Flat Loops, we find planar ‘coat-hanger’ solutions, and whirling modes in which the loop collapses onto itself. Ne xt, we treat the more general case of a honda that can slide due to a finite coefficient of friction of the rope on itself. Using matched asymptotic expansions, we resolve the shape of the rope in the boundary layer near the honda where the rope’s bending stiffness cannot be neglected. We use this solution to derive a macroscopic criterion for the sliding of the honda in terms of the microscopic Coulomb static friction criterion. Our predictions agree well with rapid- camera observations of a professional trick roper and with laboratory experiments using a ‘robo-cowboy’.

This talk is part of the Isaac Newton Institute Seminar Series series.

Tell a friend about this talk:

This talk is included in these lists:

Note that ex-directory lists are not shown.

 

© 2006-2017 Talks.cam, University of Cambridge. Contact Us | Help and Documentation | Privacy and Publicity