DETERMINDING the axis of rotation

Click For Summary

Discussion Overview

The discussion revolves around determining the axis of rotation for a lever or body subjected to external forces. Participants explore theoretical approaches and mathematical formulations related to the dynamics of rotation, considering factors such as the application of forces and the moment of inertia.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • One participant describes a scenario with a lever fixed at one end and a perpendicular force applied at the other end, questioning how to determine the axis of rotation without prior knowledge.
  • Another participant suggests that knowing the locations and directions of the forces allows for the use of dynamics to find the center of rotation.
  • A follow-up question seeks clarification on how to determine the center of rotation given the forces applied.
  • One participant proposes a method involving the calculation of torques, stating that the center of rotation can be found where the torques are equal, while noting assumptions about opposing forces and ignoring moment of inertia.
  • Another participant expresses confusion regarding the calculation and the implications of ignoring moment of inertia, prompting further inquiry about its consideration.
  • A later post reiterates the initial question about locating the axis of rotation without relying on intuition.
  • One participant explains that the motion of a rigid body can be analyzed by separating translation and rotation, suggesting a method to compute the center of mass and the orientation over time.

Areas of Agreement / Disagreement

Participants express differing views on the methods for determining the axis of rotation, with no consensus reached on the best approach or the implications of moment of inertia in the calculations.

Contextual Notes

Some participants make assumptions about the forces being applied and the conditions under which calculations are made, such as ignoring moment of inertia or considering opposing forces, which may affect the validity of their proposed methods.

Mad_Eye
Messages
69
Reaction score
0
say i have a lever, fixed to an axis in its right end.
now a perpendicular force is exert on the lever, from its left end.
the lever will obviously rotate relatively to the fixed axis.
(the force will rotate with it, and will always be perpendicular to the lever. so the lever has a fixed rotational acceleration)

we know the axis of rotation will be the right end, because we have experience in life.

but if we DIDN'T know that, and only know what forces are exerted on the lever, how could we know where will be the axis of rotation?

another example is,
a body is on a frictionless floor. two forces are exerted on it, where will be the axis of rotation?

picture:
http://img573.imageshack.us/i/pamd.jpg/
 
Physics news on Phys.org
You'd have to know where the forces are applied on the beam and you could use dynamics to find where the center of rotation of the beam is.

If you wanted to know where the beam is relative to the ground, that's a different matter. You'd have to either pick a point of interest on the ground and solve it by relative position or connect it to a point on the ground and you'll find that the instant center of the mechanism is at the point where the two points have the same tangential velocity.
 
yes yes i know

if you know where the forces are applied, what direction they have, and everything you need..

how can you determined the center of rotation?
 
It really depends on whether you're considering the moment of inertia of the beam. If you're not, then you can use this:

If your forces are located at specific locations on the beam (e.g. if the left side is x=0, then F1 would be located at like x1=L/6 and F2 would be located x2=L/3), then you find the place where the two torques are equal (F1(x1-x)+F2(x2-x) = 0, where x is the position of the center of rotation). Solve for the position and that would be the center of rotation.

Of course, I'm making certain assumptions, like the forces are in opposing directions and no moment of inertia.
 
timthereaper said:
It really depends on whether you're considering the moment of inertia of the beam. If you're not, then you can use this:

If your forces are located at specific locations on the beam (e.g. if the left side is x=0, then F1 would be located at like x1=L/6 and F2 would be located x2=L/3), then you find the place where the two torques are equal (F1(x1-x)+F2(x2-x) = 0, where x is the position of the center of rotation). Solve for the position and that would be the center of rotation.

Of course, I'm making certain assumptions, like the forces are in opposing directions and no moment of inertia.

okay thanks a lot..

a few questions though,
i don't see how this calculation is true... the body SHOULD have torque which is not necessary zero...
and i don't understand what's the meaning of ignoring the moment of inertia...
anyway..
what if you are considering the moment of inertia
 
someone?
 
Bump, I've got essentially the same question.. Given a body and all the forces acting upon it, apart from resorting to physical intuition, how are we to locate its axis of rotation?
 
markem said:
Given a body and all the forces acting upon it, apart from resorting to physical intuition, how are we to locate its axis of rotation?

The motion of rigid body can be split into translation of the center of mass (CM) and rotation around the CM and these can be computed independently. You integrate the sum of all forces and get the CM position as a function of time, and you integrate the sum of all torques relative to the CM and get the orientation as a function of time (easy in 2D case, tricky in 3D). See http://en.wikipedia.org/wiki/Rigid_body_dynamics

Points on the axis of rotation in some coordinate system are those instantaneously at rest (by definition). At those points the motion due to rotation around CM is precisely compensated by the translation motion of the CM. Basically you solve \vec{w} \times (\vec{r}-\vec{r_0})+\vec{v_0}=0 for \vec{r}, where \vec{r_0}(t), \vec{v_0}(t), \vec{w}(t) are coordinates and velocity of the CM and angular velocity around CM.
 

Similar threads

Undergrad Is angular momentum perpendicular to fixed axis of rotation constant?
  • · Replies 1 ·
Replies
1
Views
1K
Undergrad Conservation of Angular Momentum vs a gyro at the North Pole
  • · Replies 16 ·
Replies
16
Views
1K
Undergrad Non-Constant Angular Acceleration
  • · Replies 6 ·
Replies
6
Views
3K
Undergrad Energy of spinning objects as axis of rotation moves
  • · Replies 1 ·
Replies
1
Views
1K
Graduate Can a gyroscope lift a fulcrum (and itself), hinged to the floor?
  • · Replies 8 ·
Replies
8
Views
3K
High School Lever balancing physics (video game design)
  • · Replies 18 ·
Replies
18
Views
3K
Undergrad Finding the Axis of Rotation with Given CoG and Force Point
  • · Replies 32 ·
2
Replies
32
Views
3K
Graduate Proper Multi-Axis Rotational Analysis Method
  • · Replies 7 ·
Replies
7
Views
2K
Undergrad Confused about the axis of rotation in rotational motion w/o slipping
  • · Replies 10 ·
Replies
10
Views
4K
Undergrad A coordinate representing rotation about a variable axis and ##T##
  • · Replies 22 ·
Replies
22
Views
1K