Gyroscope Precession - Cause? - From Feynman

In summary: So to sum it up, Feynman talks about precession of a wheel and how the centripetal force and torque due to gravity are needed to make it go around the precession axis. He talks about how the torque due to gravity and the centripetal force balance each other and how the centripetal force is needed for a curve, but is not needed for a top section of a wheel.
  • #1
Pradhan34
5
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I ran a search for gyroscopes looking for a definitive solution to the "What causes Precession?" and found no good clear answers. I think the Feynman lectures come close to the solution and followed that thought process, all the pieces point to the solution, I had to put my theory to the test on this forum. Please have some patience while reading this cause its long.
Feynman, From Lectures on Physics Volume 1 – “Rotation In Space”,talking about precession, quote “...When the wheel is precessing, the particles that are going around the wheel are not really moving in a plane because the wheel is precessing...the particles which are crossing through the precession axis are moving in curved paths, and this requires application of a lateral force. This is supplied by our pushing on the axle, which then communicates the force to the rim through the spokes... What about the particles that are going back on the other side...there must be a force in the opposite direction on that side. The net force we apply is zero.” The Visualization is given in first image from left attached below.

(This discussion is of precession of a bicyle wheel)

This quote was rather ambiguous and I resolved to see if 2D drawing of the precessing wheel did more justice. I drew it in Solidworks 2D drawing (Picture attached below –second from left below), and voila, a point precessing and also moving on the wheel does not move in a circle – but on a curve(each point(total 3) has it’s respective circle drawn – green, red, black – the black circle is the trace of the center of mass of the wheel, thus the point’s shadow lies on the center of mass at that point). To move along a circle an object needs centripetal force and a linear momentum (Without the linear momentum it isn’t going to move). But for a curve we need a centripetal force and a torque – the torque given by the coriolis force. When the wheel moves along the curve there must be a velocity, radial, moving the wheel element towards the center resulting in a coriolis force perpendicular to the radial velocity and being perpendicular provides the coriolis force a moment arm equal to the radius of the circle.

How does this result fit? In a demonstration of precession, we hold the string, spin up the wheel and release it. Nowhere do we give it the linear momentum it needs to go around the precession axis. The coriolis force provides just this torque, to push the wheel into the circular motion. While the centripetal force and its moment arm – the radius of the wheel (NOT THE PRECESSION RADIUS) - balances the torque due to gravity. Thus the torque due to gravity furnishes the centripetal force just as friction between car wheels and the road provide centripetal force to make a turn.

Now come the pitfalls,
This works really well for the top section. But reading the Feynman quote above –“ What about the particles that are going back on the other side...there must be a force in the opposite direction on that side. The net force we apply is zero.” So far we, think the torque due to gravity is a torque. But actually is a couple (the string tension and mg form a couple turning it clockwise ). So there must be a centripetal force 180 degrees to the one on the top. I can’t see it. I was hoping by placing this on the forum someone might figure it out.
If someone has a good apparatus, maybe you can do some rough calculations.

The coriolis force, the torque giving it linear momentum...fits too well to discard, I think i’m just not seeing it.

Then again I could be farting my *** off, twisting facts. So let me know, And thank you for reading this far. I could explain the coriolis force part in more detail if someone requires.
 

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  • #2
I'll try a quick explanation, without following your whole though process. Let's say you have a disc facing up and spinning clockwise. Imagine the face of a clock hovering over the disc. You exert torque and try to push the disk down at 3 o clock and up at 9 o clock. All the rotating particles on the left side acquire a speed component upwards from that force and all the particles on right acquire a speed component downwards. The most speed the have acquired when they reach 6 a clock and 12 o clock. The particles at 12 o clock move up and the ones at 6 o clock move down although you are pressing down on 3 an pulling up on 9.
 
  • #3
0xDEADBEEF said:
The most speed the have acquired when they reach 6 a clock and 12 o clock. .

This part i didn't get. The Most speed? if the disc is rotating clockwise with a angular velocity w. the velocity is constant for a particle rotating on the circumference of the circle. v=rw: r=radius=constant

0xDEADBEEF said:
The particles at 12 o clock move up and the ones at 6 o clock move down although you are pressing down on 3 an pulling up on 9.

Are we considering a gyroscope effect here? if we are then using the vectors for precession, we get: 12 o clock will move down (or rather turn down) and 6 o clock will move up.
 
  • #4
Pradhan34 said:
This part i didn't get. The Most speed? if the disc is rotating clockwise with a angular velocity w. the velocity is constant for a particle rotating on the circumference of the circle. v=rw: r=radius=constant
But the disk is precessing, so there is an out of plane component for the speed that we are talking about.

Are we considering a gyroscope effect here? if we are then using the vectors for precession, we get: 12 o clock will move down (or rather turn down) and 6 o clock will move up.

No it won't. 6 o clock will move down and 12 o clock will move up. With vectors it is the same. The angular momentum vector points down, according to the right hand rule (fingers in direction of spin, thumb in direction of vector) The torque vector points from 6 o clock to 12 o clock (same rule). Hence by vector addition the tip of the angular momentum vector will be pushed towards the 12 and the spinning axis follows.
 
  • #5
Pradhan34 said:
I ran a search for gyroscopes looking for a definitive solution to the "What causes Precession?"

I attach an image to illustrate the physics of gyroscopic precession. The image is from the http://www.cleonis.nl/physics/phys256/gyroscope_physics.php" [Broken] page on my website.

In order to have some reference I will have the gyroscope wheel spinning along a horizontal axis, just like in the well known demonstration of the spinning bicycle wheel.

Defining the following names:
Roll - spinning of the gyroscope wheel
Pitching - turn along a horizontal axis, perpendicular to the roll
Swiveling - turn along a vertical axis.

attachment.php?attachmentid=24771&d=1270068885.png


First start the gyroscope wheel spinning fast. Then add some swivel.
Think of the gyroscope wheel as moving through four quadrants. In two of the quadrants the wheel's mass is moving towards the swivel axis, in the other two quadrants the wheel's mass is moving away from the swivel axis.
In the quadrants where the wheel's mass moves towards the swivel axis a force is required to reduce the velocity of rotating around the swivel axis. If that force isn't present the mass in that quadrant will tend to move in the direction of the green arrows in the image.
In the quadrants where the wheel's mass moves away from the swivel axis a force is required to increase the velocity of rotating around the swivel axis. If that force isn't present the mass in that quadrant will tend to move in the direction of the green arrows in the image.
The inertial effects in the four quadrants combined give rise to a tendency to pitch.

Summerizing:
If a gyroscope wheel is spinning fast (rolling) and some swivel is added, then the gyroscope wheel will tend to pitch.
(Also, note the counterpart: if the wheel is spinning, and some pitching motion is added, the wheel will respond with some swiveling motion.)
In the case of the well known suspended spinning bicycle wheel: note that its precessing motion gives rise to a tendency to pitch up. Gravity is tugging at the wheel, but the tendency to pitch up nullifies the gravitational influence.

The full story is in the http://www.cleonis.nl/physics/phys256/gyroscope_physics.php" [Broken] article on my website.

Cleonis
http://www.cleonis.nl
 

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1. What is a gyroscope and how does it work?

A gyroscope is a device that consists of a spinning wheel or disc that is mounted on an axis, allowing it to freely rotate in any direction. It works based on the principle of angular momentum and gyroscopic precession, which keeps the axis of the spinning wheel aligned in the same direction regardless of the movement of the base it is mounted on.

2. What causes precession in a gyroscope?

The precession of a gyroscope is caused by a force applied perpendicular to the axis of rotation. This force is known as torque and it creates a change in the direction of the angular momentum, causing the gyroscope to precess or rotate around its axis.

3. How does Feynman explain the cause of gyroscope precession?

In his lectures, Feynman explains that the cause of gyroscope precession lies in the conservation of angular momentum. When a torque is applied to a gyroscope, it causes a change in the direction of the angular momentum, but the magnitude remains constant, resulting in the gyroscope precessing around its axis.

4. Can the direction of precession be controlled?

Yes, the direction of precession can be controlled by changing the direction of the applied torque. This is why gyroscopes are used in navigation and stability systems, as the direction of precession can be manipulated to keep the gyroscope's axis aligned in a specific direction.

5. Are there real-world applications of gyroscope precession?

Yes, there are many real-world applications of gyroscope precession, including navigation systems in airplanes and ships, stabilizers in cameras and drones, and gyroscopic sensors in smartphones and gaming controllers. Gyroscopes are also used in space exploration to maintain the orientation of spacecraft and satellites in zero-gravity environments.

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