How Do You Calculate the Instantaneous Linear Speed of a T-Shaped Pendulum?

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To calculate the instantaneous linear speed of a T-shaped pendulum, the assembly consists of two identical uniform bars pivoted at their connection point. The potential energy lost as the center of mass falls is calculated as 2mgh, where h is the height fallen. The moment of inertia for each bar is determined, with the horizontal bar's moment of inertia being md^2/12 and the vertical bar's being md^2/3. The kinetic energy at position B is expressed as the sum of the kinetic energies of both bars, leading to the equation 2mg(d/2). The discussion highlights the importance of accurately determining the height and moments of inertia to solve for the velocity.
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1. A T-shaped assembly is made of two identical uniform bars of length d and mass m each. One end of one of the bars is rigidly connected to the midpoint of the other. The assembly is pivoted at the connection point and held in position A. After it is released, the assembly swings down in the vertical plane. Neglect all resistive forces.

Find the instantaneous linear speed of the bottom point of the assembly as it passes through position B
2. I tryed to use energy equation to find the velocity, but moment of inertia is unknown
2mg(d/2)=1/2(2m)v_{cm}^2+1/2I_{cm}\omega^2 so I can't figure out how to continue
 
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The assembly is in the first position.
The length of each bar is L

Im guessing the assembly centre of mass is ( L / 4 ) above the pivot point.
( i considered each bar as a point mass at its individual centre of mass, then assumed the combined centre of mass at a point halfway inbetween )

The distance the combined centre of mass falls is ( L / 4 ) * 2
(call this distance h )
So, the potential energy lost = m * g * h
 
dean barry said:
The assembly is in the first position.
The length of each bar is L

Im guessing the assembly centre of mass is ( L / 4 ) above the pivot point.
( i considered each bar as a point mass at its individual centre of mass, then assumed the combined centre of mass at a point halfway inbetween )

The distance the combined centre of mass falls is ( L / 4 ) * 2
(call this distance h )
So, the potential energy lost = m * g * h

I agree, that height lost is h=L/2, but the potential energy is 2mgh, because of the combined mass. But this is what I have written in the equation of my question. This leads me nowhere. I have 1 equation 2 unknowns..
 
myko said:
1. A T-shaped assembly is made of two identical uniform bars of length and mass each.

That sentence seems incomplete. Have you missed out something?
You will certainly need the length of the bars to answer the question.
I would consider the KE of each bar separately. If each has mass m, length L, what are their moments of inertia about O?
 
haruspex said:
That sentence seems incomplete. Have you missed out something?
You will certainly need the length of the bars to answer the question.
I would consider the KE of each bar separately. If each has mass m, length L, what are their moments of inertia about O?
I added some letters that where missed, sry.
The momento of inertia of horizontal bar is I=md^2/12 and vertival bar I=md^2/3
so combined kinethik energy at position B is:
K=((1/2)md^2/12+(1/2)md^2/3)\omega^2=2mg(d/2)
is this correct?
 

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