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MOMENT EQUATIONS

USEFUL FORMS OF THE MOMENT EQUATIONS
The sum of moments about a point P can be written as:
(1) Mp = Mp + rpc × (ΣF)
where F) = mac = (d)/(dt)(mv) = (d)/(dt)(P), and ΣMp = (dHc)/(dt). That is, the sum of the forces equal the rate of change of linear momentum and the sum of the moments equal the rate of change of angular momentum.
(2) ΣMp = (dHc)/(dt) + rpc × (dP)/(dt)
(3) ΣMp = Hċ + rpc × mac
In general:
(4) ΣMp = (Icxzα − Icyzω2) i + (Icyzα − Icxzω2) j + Iczzαk + rpc × mac
If the body is symmtric so that so that the products of inertia equal to zero, or Icxz = Icyz = 0, the result is
(5) ΣMp = Iczzαk + rpc × mac for multiple equations
If the point of interest P lies in the plane of the mass center C:
(6) ΣMp = Iczzαk + rpc × mac, results in a scalar equation
MASS-CENTER FORM OF THE MOMENT EQUATIONS
Sum of the moments about an arbitrary fixed point, labeled O, is given by:
(7) ΣMo = ΣR × ma
Also the definition of moment of the moment of momentum about a fixed point in space is:
(8) Ho = ΣRi × mvi
If the time derivative of angular momentum is taken, the result is:
(9) (dHo)/(dt) = ΣRi × mai(Ridoes not change with the time for a rigid body)
Combining the above expressions yields:
(10) ΣMo = (dHo)/(dt)
If O is the mass center, the following expression can be used:
(11) ΣMc = (dHc)/(dt)
For the mass center of a body (planar)
(12) Hc = rcc × mvc + Icxzωi + Icyzωj + Iczzωk
So the sum of the moments about the mass center can be written as:
(13) ΣMc = (d)/(dt)[Icxzωi + Icyzωj + Iczzωk]
For a fixed set of axes, the time derivatives of these quantities are constantly computed, which is not always a good policy. A better way would be to have the frame of reference move with the body so that, Icxz and Icyz are constant.
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