- #1
binbagsss
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Ok, so the system consists of two massive spheres, m1 and m2, of radii a and b respectively, connected by a massless rod of length R, as seen in the diagram attached.
The question is to calculate the moment of inertia tensor.
Sol:
Set the origin at the centre of mass . So that we are in the principal axis frame we chose I3 to be along the line connecting the masses.
=> M1=M2R/(M1+M2)]k and M2=-M1R/(M1+M2)]k
Now I have some questions on the next part of my book's solution...
It says, we are to find the moment of inetia tensor for a sphere and apply the displaced axes theorem. So we do this and it comes out as I3(sphere a) = 2/5Mi/r^2, where r is the radius of the sphere.
=> I3=2/5(M1a^2+M2b^2)*
And by symmetry we can see that I1=I2, and we apply the displaced axes theorem.
(Theorem: If we know the moment of inertia tensor using the center of mass as the origin (Icm), and we wish to know the moment of inertia of a tensor about the origin displaced by a, a constant vector, it is given by: Ia=Icm+M(a^2δαβ -aαaβ)
It then deduces that: I1=I2=2/5(M1a^2)+M1(M2R/(M1+M2))^2+2/5(M2a^2)+M2(M1R/(M1+M2))^2
My questions:
1) I3=I3(sphere a) + I3(sphere b) from * ; just wondering what the justification is, as 2/5Mi/r^2 is I for a sphere through it's centre of mass, which is any possible axes passing through the centre of axe, I believe, due to the symmetry of the body. So justifying why we can simply add these two, is because I3 passes through the centre of BOTH bodies.
2) I'm not really understanding the application of the displaced axes theorem. I believe it is being applied to I3. And I don't really understand the part of the theorem ' If we know the moment of inertia tensor using the center of mass as the origin and wish to know the moment of inertia of a tensor about the origin displaced by a, a constant vector, it is given by..'. As applied to I1/I2 from I3 because , as daft as it sounds, don't I1,I2,I3 share the same origin - the centre of mass, as defined in the beginning.
So perhaps I am going wrong in the way that we need to apply this theorem to the spheres in turn, starting with an arbitrary axis through the centre of the sphere (anything due to the symmetry) and ending with I2/I3?
Many many thanks to anyone who can shed some light on this, greatly appreciated :) !
The question is to calculate the moment of inertia tensor.
Sol:
Set the origin at the centre of mass . So that we are in the principal axis frame we chose I3 to be along the line connecting the masses.
=> M1=M2R/(M1+M2)]k and M2=-M1R/(M1+M2)]k
Now I have some questions on the next part of my book's solution...
It says, we are to find the moment of inetia tensor for a sphere and apply the displaced axes theorem. So we do this and it comes out as I3(sphere a) = 2/5Mi/r^2, where r is the radius of the sphere.
=> I3=2/5(M1a^2+M2b^2)*
And by symmetry we can see that I1=I2, and we apply the displaced axes theorem.
(Theorem: If we know the moment of inertia tensor using the center of mass as the origin (Icm), and we wish to know the moment of inertia of a tensor about the origin displaced by a, a constant vector, it is given by: Ia=Icm+M(a^2δαβ -aαaβ)
It then deduces that: I1=I2=2/5(M1a^2)+M1(M2R/(M1+M2))^2+2/5(M2a^2)+M2(M1R/(M1+M2))^2
My questions:
1) I3=I3(sphere a) + I3(sphere b) from * ; just wondering what the justification is, as 2/5Mi/r^2 is I for a sphere through it's centre of mass, which is any possible axes passing through the centre of axe, I believe, due to the symmetry of the body. So justifying why we can simply add these two, is because I3 passes through the centre of BOTH bodies.
2) I'm not really understanding the application of the displaced axes theorem. I believe it is being applied to I3. And I don't really understand the part of the theorem ' If we know the moment of inertia tensor using the center of mass as the origin and wish to know the moment of inertia of a tensor about the origin displaced by a, a constant vector, it is given by..'. As applied to I1/I2 from I3 because , as daft as it sounds, don't I1,I2,I3 share the same origin - the centre of mass, as defined in the beginning.
So perhaps I am going wrong in the way that we need to apply this theorem to the spheres in turn, starting with an arbitrary axis through the centre of the sphere (anything due to the symmetry) and ending with I2/I3?
Many many thanks to anyone who can shed some light on this, greatly appreciated :) !