Constant solutions to the Lagrange equations of motion

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SUMMARY

The discussion focuses on demonstrating that a particle moving on the surface of an inverted cone can exhibit constant values for the radial distance \( r \) and angular velocity \( \dot{\phi} \) as solutions to the Lagrange equations of motion. The equations of motion are derived from the Lagrangian, and it is established that setting \( \ddot{r} = 0 \) leads to uniform circular motion, confirming that the system can maintain constant \( r \) and \( \dot{\phi} \) indefinitely under the right initial conditions. The key takeaway is that while the equations allow for constant solutions, they do not inherently lead to them without appropriate initial conditions.

PREREQUISITES
  • Understanding of Lagrangian mechanics and the Lagrange equations of motion
  • Familiarity with concepts of uniform circular motion
  • Knowledge of differentiation in calculus
  • Basic principles of classical mechanics related to motion on curved surfaces
NEXT STEPS
  • Study the derivation of the Lagrangian for systems with constraints
  • Explore the implications of initial conditions on motion in Lagrangian mechanics
  • Learn about the stability of orbits in conservative systems
  • Investigate the role of friction and other forces in modifying motion on surfaces
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Students of physics, particularly those studying classical mechanics, as well as educators and researchers interested in Lagrangian dynamics and motion on curved surfaces.

bobred
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Homework Statement


A particle moves on the surface of an inverted cone. The Lagrangian is given by

t%29%5Cdot%7Br%7D%5E%7B2%7D+r%5E%7B2%7D%5Cdot%7B%5Cphi%7D%5E%7B2%7D%20%5Cright%29-mg%5Calpha%20r.png


Show that there is a solution of the equations of motion where
png.latex?r.png
and
png.latex?%5Cdot%7B%5Cphi%7D.png
take constant values
png.latex?r_0.png
and
png.latex?%5COmega.png
respectively

Homework Equations


The equations of motion
png.latex?r.png
and
png.latex?%5Cphi.png
are

tex?%5Cddot%7Br%7D+%5Calpha%5E%7B2%7D%5Cddot%7Br%7D-r%5Cdot%7B%5Cphi%7D%5E%7B2%7D+g%5Calpha%20=0.png
(1)

png.latex?r%5E2%5Cdot%7B%5Cphi%7D=K.png
(2)

So
png.latex?%5Cdot%7B%5Cphi%7D.png
can be eliminated from equation (1)

The Attempt at a Solution


Would I go about this by setting
png.latex?%5Cddot%7Br%7D.png
equal to a constant,
png.latex?r_0.png
, and similarly for
png.latex?%5Cdot%7B%5Cphi%7D.png
?
 
Last edited by a moderator:
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bobred said:
Would I go about this by setting
png.png
equal to a constant,
png.png
, and similarly for
png.png
?

It is not \ddot{r}, \dot{\phi} that you were asked to show provide a solution, but {r}, \dot{\phi}. These requirements define uniform circular motion. The question is thus asking you to use the equations to check that uniform circular motion is a solution.
 
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MarcusAgrippa said:
It is not \ddot{r}, \dot{\phi} that you were asked to show provide a solution, but {r}, \dot{\phi}. These requirements define uniform circular motion. The question is thus asking you to use the equations to check that uniform circular motion is a solution.

If ##r(t) = r_0## (a constant), what is ##\ddot{r}(t)##?
 
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What do you get when you differentiate a constant?
 
Differentiating a constant is zero.
I was thinking about the equations in isolation to each other and not as part of a system. So

v=r \dot{\phi}=r_0 \Omega

I just need to show that the equations of motion lead to this.
 
Last edited:
bobred said:
Differentiating a constant is zero.
I was thinking about the equations in isolation to each other and not as part of a system. So

v=r \dot{\phi}=r_0 \Omega

I just need to show that the equations of motion lead to this.

No: they do not "lead to" this; they merely allow this.

There is a big difference, since (due to the lack of friction) a solution with non-constant ##r## and ##\dot{\phi}## never settles down to a limiting orbit of constant ##r## and ##\dot{\phi}##. However, if you start off with the correct initial conditions, your orbit maintains constant ##r## and ##\dot{\phi}## forever. Essentially, that is what you are being asked to verify.
 
So setting the acceleration \ddot{r}=0 leaves a constant r and \dot{\phi} which allows the uniform motion.
 

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