With respect to the following vectors: P = 9.73i - 7.36j + 1.02k; Q = - 1.77i - 3.68j + 1.43k 4. Calculate the k'th component of the cross product of vectors P and Q 5. What is the magnitude of vectors P? 6. What is the magnitude of vector Q? 7. Determine the magnitude of the angle between vectors P and Q in degrees. 8. What is the magnitude of the projection of vector P on vector Q? 9. What is the magnitude of the projection of vector Q on vector P?. 10. What is the x-component of the unit vector joining vectors P and Q? 11. What is the y-component of the unit vector joining vectors P and Q? 12. What is the z-component of the unit vector joining vectors P and Q? 13. Determine the projection of the vector P on the unit vector along PQ.
Rotational Equilibrium And Rotational Dynamics
In physics, the state of balance between the forces and the dynamics of motion is called the equilibrium state. The balance between various forces acting on a system in a rotational motion is called rotational equilibrium or rotational dynamics.
Equilibrium of Forces
The tension created on one body during push or pull is known as force.
With respect to the following vectors: P = 9.73i - 7.36j + 1.02k; Q = - 1.77i - 3.68j + 1.43k
4. Calculate the k'th component of the cross product of vectors P and Q
5. What is the magnitude of vectors P?
6. What is the magnitude of vector Q?
7. Determine the magnitude of the angle between vectors P and Q in degrees.
8. What is the magnitude of the projection of vector P on vector Q?
9. What is the magnitude of the projection of vector Q on vector P?.
10. What is the x-component of the unit vector joining vectors P and Q?
11. What is the y-component of the unit vector joining vectors P and Q?
12. What is the z-component of the unit vector joining vectors P and Q?
13. Determine the projection of the vector P on the unit vector along PQ.
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