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Spinning Top from Wikimedia Commons: Image by User:Lacen
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Excerpt
The rapidly spinning Symmetric Top exhibiting Precession under the force of gravity (near-earth) is a classic Physics problem.
We assume that we have a symmetric top that can easily rotate about an axis containing its center of mass at a high angular velocityω . If the top tilts at all from the vertical, so that its center of mass does not lie directly above the top's point of contact with the surface it's resting on, there will be a torque (single-axis) exerted on the top, which will act to change its angular momentum about a single axis. What will happen?
Solution
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System:
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The Spinning Top is a with a large amount of .
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due to and normal force from the surface the top is spinning on.
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Model:
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Approach:
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Diagrammatic Representation
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If the top is perfectly upright, with its center of mass directly over the point of contact with the surface it's spinning on, then the torque (single-axis) about the point of contact is zero. The force due to gravity (near-earth) pulls directly downward, and the vector r between the point of contact and the center of mass points directly upward, so r X F = 0 .
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If the top tilts from the perfectly vertical orientation by an angle θ , then there will be a non-zero torque (single-axis).
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Mathematical Representation
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The top is spinning about its axis with angular velocityω The moment of inertia about its axis of rotation is I . For the case where the top has its axis perfectly vertical, the angular momentum is given by:
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\begin{large}\[ \vec{L} = I \vec{\omega} \]\end{large}
The direction associated with both the angular velocity and the angular momentum is directly upwards.
If the axis of the top is tipped from the vertical by an angle θ , then the situation is different. The angular velocity and the angular momentum both point along this angle θ . We define the vector r that runs from the point of contact (between the top and the surface it's spinning on) and the center of mass of the top. The force of gravity (near-earth), Fg , pulls on the center of mass, and this exerts a torque (single-axis) on the top. The torque, τ , is given by the cross product between r and Fg :
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|Spinning Top
from Wikimedia Commons: Image by User:Lacen|
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{excerpt}The rapidly spinning Symmetric Top exhibiting Precession under the force of [Gravity] is a classic Physics problem.{excerpt}
We assume that we have a symmetric top that can easily rotate about an axis containing its [center of mass] at a high [angular velocity] ω . If the top tilts at all from the vertical, so that its center of mass does not lie directly above the top's point of contact with the surface it's resting on, there will be a [torque (one-dimensional)] exerted on the top, which will act to change its [angular momentum (one-dimensional)]. What will happen?
h4. Solution
{toggle-cloak:id=sys} *System:* {cloak:id=sys}The Spinning Top is a [rigid body] with a large amount of [angular momentum (one-dimensional)].{cloak}
{toggle-cloak:id=int} *Interactions:* {cloak:id=int}[torque(one-dimensional) due to [gravity] and normal force from the surface the top is spinning on.{cloak}
{toggle-cloak:id=mod} *Model:* {cloak:id=mod} [Angular Momentum and External Torque].{cloak}
{toggle-cloak:id=app} *Approach:*
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{toggle-cloak:id=diag} {color:red} *Diagrammatic Representation* {color}
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First, consider the *Y* support for the pendulum:
!Lissajous Figure 1.PNG!
The pendulum effectively has length *L{~}2{~}* when swinging in the horizontal plane in and out of the page, but length *L{~}1{~}* along the horizontal direction _in_ the plane of the page.
!Lissajous Pendulum 2.PNG!
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{toggle-cloak:id=math} {color:red} *Mathematical Representation* {color}
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We ignore the distribution of tensions in the upper cables, and simply view the pendulum as a simple pendulum along either the plane of the drawing or perpendicular to it. In the plane perpendicular to the drawing (where the mass oscillates toward and away from the reader) the pendulum length is *L{~}2{~}* and the angular frequency of oscillation is given by the formula for the Simple Pendulum (see [Simple Harmonic Motion].
{latex}\begin{large}\[ \omega_vec{2\tau} = \sqrt{\frac{g}{Lvec{r} \times \vec{F_{\rm 2}g}} \]\end{large}{latex}
Along the plane lying in the page, where the mass moves left and right, the pendulum length is the shorter *L{~}1{~}* and the angular frequency is
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where
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\begin{large}\[ F_{\rm g} = mg \]\end{large}
and, as the gravitational force, points straight downwards.
The direction associated with this torque is horizontal and perpendicular to the angular momentum vector L. As a result, the torque, which causes a change in the angular momentum vector, does not cause a change in the magnitude of the angular momentum, but only in its direction. The angular momentum vector remains tipped at the angle θ with respect to the vertical, but it begins to rotate around the vertical axis in a counter-clockwise direction with an angular velocityΩ . This motion is called precession.
This new rotational motion ought to contribute to the angular momentum of the system. in most cases of interest and practical importance, however, the small addition to the angular momentum this causes is negligible compared to the angular momentum of the top rotating at angular velocity ω , and so it is usually ignored in the gyroscopic approximation, which holds that
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\begin{large}\[ L =I \omega \]\end{large}
as long as
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\begin{large}\[ \Omega \ll \omega_{1} = \sqrt{\frac{g}{L_{\rm 1}}} \]\end{large}{latex}
the ratio of frequencies is thus:
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In that case,the change in angular momentum only affects the horizontal portion:
\begin{large} \[ \Omega = \frac{rmg}{Lomega_{1}}= \frac{\sqrt{\frac{g}{L_{2}}}}{\sqrt{\frac{g}{L_{1}}}} = \sqrt{\frac{L_{1rmg}}{L_{2}}}{I\omega} \]\end{large}{latex}
in order to have a ratio of 1:2, one thus needs pendulum lengths of ratio 1:4. In order to get a ratio of 3:4 (as in the figure at the top of the page), the lengths must be in the ration 9:16.
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