Some Questions regarding Rotational Mechanics

In summary, angular displacement is not a vector quantity because its result depends on the order in which the operations are performed, while angular velocity behaves like a vector quantity because in the limit of infinitesimally small rotations, its addition is commutative. However, technically, angular velocity is not a true vector quantity as it does not behave like a vector under improper transformations.
  • #1
Caesar_Rahil
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Can somebody explain to me clearly what is MOMENT OF INERTIA, what is TORQUE, what is ANGULAR MOMENTUM. If you ever comparing those with linear motion quantities, then please explain a little in detail what is the similarity between moment of inertia and mass, as I'm not getting it.


Also, I would also request you to answer this question.(it might help):

What will happen if I am far out in space in a region without (or negligible) graviatational forces and try to spin a sphere.
-Would it spin for ever? (unless I do something)
-If it would, then each particle will undergo circular motion, which means that a constant centrifugal force is being applied towards the centre. If so, then who is applying it?
-Wouldn't that violate Newton's Second Law?
-Would it spin for sometime and then stop (refer Q.1)

Any attempt of explanation is appreciated.
 
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  • #2
Caesar_Rahil said:
Can somebody explain to me clearly what is MOMENT OF INERTIA, what is TORQUE, what is ANGULAR MOMENTUM. If you ever comparing those with linear motion quantities, then please explain a little in detail what is the similarity between moment of inertia and mass, as I'm not getting it.
This sounds like a job for your textbook! Or you can try reading these: http://hyperphysics.phy-astr.gsu.edu/Hbase/circ.html#rotcon"


Also, I would also request you to answer this question.(it might help):

What will happen if I am far out in space in a region without (or negligible) graviatational forces and try to spin a sphere.
-Would it spin for ever? (unless I do something)
-If it would, then each particle will undergo circular motion, which means that a constant centrifugal force is being applied towards the centre. If so, then who is applying it?
-Wouldn't that violate Newton's Second Law?
-Would it spin for sometime and then stop (refer Q.1)
Why don't you take a crack at answering these questions and someone can spot where (or if) you're going wrong. What do you think?
 
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  • #3
OK let me give it a try.
-Since no external torque acts on it, it implies that it has no angular acceleration which further implies that it's angular speed would never decrease which even further implies that it should spin forever.
-The constant centrifugal force is applied by Electromagnetic attractions between the atoms (I call them bonds) which is always balanced by the opposite end.
-It actually spins forever due to Newton's Second law of rotation. Whenever we apply force on a spinning object it is (mysteriously) taken that all forces act on it's centre of mass (in this case the centre of the sphere). Don't ask me, Newton proved that we can indeed do this.
-Refer Q.1

If we apply a force which is not pointing to the axis of rotation, it produces a Torque and it would cause it to spin faster or slower.

***So, How was it****
(At least tell whether my concepts are correct)

**any attempt of explanation is appreciated**
 
  • #4
Caesar_Rahil said:
OK let me give it a try.
-Since no external torque acts on it, it implies that it has no angular acceleration which further implies that it's angular speed would never decrease which even further implies that it should spin forever.
Sounds good to me.
-The constant centrifugal force is applied by Electromagnetic attractions between the atoms (I call them bonds) which is always balanced by the opposite end.
Looking at things from an inertial reference frame, I'd say that each particle is centripetally accelerated and thus experiences a centripetal (not centrifugal) force. That force is provided by the attraction between the particles as you describe. This force isn't "balanced" since the particles are accelerating. There's certainly no violation of any of Newton's laws.
-It actually spins forever due to Newton's Second law of rotation.
You can think of it spinning forever as a statement of Newton's First law applied to rotation--since there's no torque acting.
Whenever we apply force on a spinning object it is (mysteriously) taken that all forces act on it's centre of mass (in this case the centre of the sphere). Don't ask me, Newton proved that we can indeed do this.
The net force, regardless of where the forces are applied, determines the translational acceleration of an object. But the rotational acceleration certainly does depends on where those forces are applied.
 
  • #5
Here's my second question:
Is angular displacement ([tex]\theta[/tex]) a vector quantity?

If yes then why doesn't it follow laws of vectors. And what is the direction of this vector.

if no then why is angular velocity ([tex]\omega[/tex]) a vector?
 
  • #6
You can certainly ascribe three orthogonal components to describe any rotation. This is one interpretation of Euler's rotation theorem. However, angular displacement is not a vector quantity because the result of a sequence of angular displacements depends on the order in which the operations are performed. You can see that this is so by applying various rotation sequences to a book. The book will end up in one orientation if you first roll it by ninety degrees and then pitch it by ninety degrees. It will end up in a completely different orientation if you do the pitch first and roll second. To qualify as a vector, addition must be commutative (i.e. a+b=b+a), and angular displacements do not do that.

Suppose we describe a rotation as a roll,pitch,yaw sequence. Call this triple "a". Now do the same for another rotation, and call this sequence "b". As the rotations "a" and "b" become small, the difference in orientation between "a" followed "b" versus "b" followed by "a" becomes very, very small. In other words, in the limit of infinitesimally small rotations, "addition" of rotations is commutative. This is why we can view angular velocity as a vector quantity. Differentiating the non-commutative Euler sequences that describe a rotation paradoxically yields a commutative quantity.

Technically, angular velocity is not a vector quantity. It does behave like a vector in the sense that angular velocities can be added like vectors. However, angular velocity does not behave like a vector upon reflection. Things that behave like vectors under proper transformations but not under improper transformations are called http://mathworld.wolfram.com/Pseudovector.html" [Broken].
 
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  • #7
Thanks for all your efforts.
Before I congratulate you for your wonderful efforts, I would like to add one final question.

Let's suppose, we have a frictionless surface. On that a block with inclined plane of some mass say 'M' and length 'L' with inclination '[tex]\theta[/tex]' is kept. On it a sphere of mass 'm' and radius 'r' is kept andit rolls down the plane without slipping. The inclined plane has friction coefficient '[tex]\mu[/tex]'. There is going to be only one kind of friction and that is static friction. Am I correct?
Will the block move (or accelerate) as the ball goes down?

(Don't tell me to try that)

***Any attempts of explanation are appreciated***
 
  • #8
Caesar_Rahil said:
Let's suppose, we have a frictionless surface. On that a block with inclined plane of some mass say 'M' and length 'L' with inclination '[tex]\theta[/tex]' is kept. On it a sphere of mass 'm' and radius 'r' is kept andit rolls down the plane without slipping. The inclined plane has friction coefficient '[tex]\mu[/tex]'. There is going to be only one kind of friction and that is static friction. Am I correct?
You are correct.

Will the block move (or accelerate) as the ball goes down?
I'm afraid I will tell you to try it. :wink: Hint: What forces act on the block?
 
  • #9
first funny side: unfortunately in my 2nd, 3rd and 4th sem mechanics viva, i got the same teacher and the stupid person asked me all three times the same question, what do you mean by moment of inertia, angular momentum, their physical significance and analogy to mass and momentum. and everytime i explained so much, but still he would say, i lack my concepts.
anyways does the inclined block experience some reaction due to the sphere?? (in horizontal dir)
 
  • #10
Well according to me, the block should move behind, and the sphere shouldcome straight down if frictional force is less than gsin[tex]\theta[/tex].
 
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  • #11
How can the sphere come straight down if the block moves to one side? (Consider conservation of momentum.)

Also: The sphere will roll down, not slide down. (Assuming the angle isn't too steep.)
 
  • #12
Then what will the motion of the sphere be like??
 
  • #13
just read good refrence book like d.c.pandey mechanics-2
 

1. What is rotational motion?

Rotational motion is the movement of an object around an axis or fixed point. It is also known as circular motion.

2. What is rotational inertia?

Rotational inertia, also known as moment of inertia, is the measure of an object's resistance to change in its rotational motion. It is dependent on an object's mass and how the mass is distributed around its axis of rotation.

3. How is torque related to rotational motion?

Torque is a measure of the force that causes an object to rotate around an axis. It is directly proportional to an object's rotational acceleration and is dependent on the force applied and the distance from the axis of rotation.

4. What is the difference between angular velocity and linear velocity?

Angular velocity is the rate of change of an object's angular displacement, while linear velocity is the rate of change of an object's linear displacement. Angular velocity is measured in radians per second, while linear velocity is measured in meters per second.

5. How does the moment of inertia affect an object's rotational motion?

The moment of inertia affects an object's rotational motion by determining how easy or difficult it is to change the object's rotational speed. Objects with a larger moment of inertia require more torque to accelerate or decelerate, while objects with a smaller moment of inertia can change their rotational speed more easily.

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