Angular Momentum of a Particle Confusion

AI Thread Summary
Angular momentum for a particle is defined as the cross product of the position vector and momentum vector (L = r × p), while for a rigid body, it is expressed as L = Iω, where I is the moment of inertia and ω is the angular velocity. The pulley is indeed treated as a rigid body, and its angular momentum can be calculated using either method, depending on the context. For rigid bodies, the angular momentum can be derived by summing the contributions of individual particles, considering their uniform angular frequency. It's essential to use the correct values for position and velocity, particularly the tangential velocity, when applying these equations.
Speedking96
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Homework Statement



I was reading the textbook section on angular momentum, and I'm having some difficulty grasping angular momentum.

Here is a question:

upload_2014-12-12_22-9-24.png


In the book, it says that the angular momentum L is equal to vector r cross vector p for a particle. But, for a rigid body, the equation is L = Iw.

In this case, why isn't the pulley treated as a rigid object. Does this mean that you can take the cross product to find the angular momentum in any case?

If someone could please clarify this. Thank you.
 

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L=r×p ::this equation means rotational
Angular momentum is the. Moment of linear momentum.
L=Iw:: this is analogous to p=MV.but
Thing to be remembered is I can be found for rigid body only. If body is non rigid we have to find L of each particle at any
Instance and add. So this equation is used generally for rigid bodies only. That doesn't imply u can't use the first equation for rigid bodies. only you should be carefull about taking correct value of r .
 
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Speedking96 said:
In this case, why isn't the pulley treated as a rigid object. Does this mean that you can take the cross product to find the angular momentum in any case?

If someone could please clarify this. Thank you.
The pulley is treated as a rigid body. What is the angular momentum for a ring? How is the angular velocity of the pulley related to the linear velocity of its rim?
 
For an assembly of particles ##\vec L = \Sigma {\vec r_i \times \vec p_i} = \Sigma {m_i \vec r_i \times \vec v_i}##. For a rigid body rotating with vector ##\vec \omega##, ##\vec v_i= \vec \omega \times \vec r_i ##, so ##\vec L = \Sigma {m_i \vec r_i \times (\vec \omega \times \vec r_i)}##. If ##\vec s_i## is the component of ##\vec r_i## orthogonal to ##\omega##, this reduces to ##\vec L = \Sigma {m_i (\vec s_i^2) \vec \omega} = \vec \omega\Sigma {m_i (\vec s_i^2)} = \vec \omega I##
 
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ehild said:
The pulley is treated as a rigid body. What is the angular momentum for a ring? How is the angular velocity of the pulley related to the linear velocity of its rim?
When pulley is treated as rigid body and if you know linear velocity if any point ,then divide that velocity with perpendicular distance from axis of rotation and you'll get angular velocity.
 
@vishnu: I asked the OP, as I wanted him to answer his own question. Do not answer instead of him.
 
ehild said:
@vishnu: I asked the OP, as I wanted him to answer his own question. Do not answer instead of him.
Ooops
 
ehild said:
The pulley is treated as a rigid body. What is the angular momentum for a ring? How is the angular velocity of the pulley related to the linear velocity of its rim?

The angular momentum for a ring is MR2.

Since a ring is a rigid body, it's angular momentum is I = lw = (MR2)(w) = (MR2)(v/r) = mvr

Ok, I see.

So from what I can understand from the posts above, you can use r x p for a particle, or for a sum of particles, but for a rigid body, you must use I = Iw.

And, when the velocity used in the calculations must be the tangential velocity.

Is this correct?
 
Speedking96 said:
So from what I can understand from the posts above, you can use r x p for a particle, or for a sum of particles, but for a rigid body, you must use I = Iw.

And, when the velocity used in the calculations must be the tangential velocity.

Is this correct?
Yes, L=Iw. And you get it by summing (integrating) the contribution rxp of all particles of that rigid body, using the fact that the angular frequency is the same for all of them.
 
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Thank you.
 
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