Figure 10.31 shows an object of mass M with one axis through its center of mass and a parallel axis through an arbitrary point A . Both axes are perpendicular to the page. The figure shows an arbitrary mass element dm and vectors connecting the center of mass, the point A , and dm . (a) Use the law of cosines (Appendix A) to show that r 2 = r c m 2 + h 2 − 2 h → ⋅ r → c m . (b) Use this result in I = ∫ r 2 dm to calculate the object’s rotational inertia about the axis through A . Each term in your expression for r 2 leads to a separate integral. Identify one as the rotational inertia about the CM, an-other as the quantity Mh 2 , and argue that the third is zero. Your result is a statement of the parallel-axis theorem (Equation 10.17). FIGURE 10.31 Problem 78
Figure 10.31 shows an object of mass M with one axis through its center of mass and a parallel axis through an arbitrary point A . Both axes are perpendicular to the page. The figure shows an arbitrary mass element dm and vectors connecting the center of mass, the point A , and dm . (a) Use the law of cosines (Appendix A) to show that r 2 = r c m 2 + h 2 − 2 h → ⋅ r → c m . (b) Use this result in I = ∫ r 2 dm to calculate the object’s rotational inertia about the axis through A . Each term in your expression for r 2 leads to a separate integral. Identify one as the rotational inertia about the CM, an-other as the quantity Mh 2 , and argue that the third is zero. Your result is a statement of the parallel-axis theorem (Equation 10.17). FIGURE 10.31 Problem 78
Figure 10.31 shows an object of mass M with one axis through its center of mass and a parallel axis through an arbitrary point A.
Both axes are perpendicular to the page. The figure shows an arbitrary mass element dm and vectors connecting the center of mass, the point A, and dm. (a) Use the law of cosines (Appendix A) to show that
r
2
=
r
c
m
2
+
h
2
−
2
h
→
⋅
r
→
c
m
. (b) Use this result in I = ∫r2dm to calculate the object’s rotational inertia about the axis through A. Each term in your expression for r2 leads to a separate integral. Identify one as the rotational inertia about the CM, an-other as the quantity Mh2, and argue that the third is zero. Your result is a statement of the parallel-axis theorem (Equation 10.17).
suggest a reason ultrasound cleaning is better than cleaning by hand?
Checkpoint 4
The figure shows four orientations of an electric di-
pole in an external electric field. Rank the orienta-
tions according to (a) the magnitude of the torque
on the dipole and (b) the potential energy of the di-
pole, greatest first.
(1)
(2)
E
(4)
What is integrated science.
What is fractional distillation
What is simple distillation
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.