Take an equilateral triangular sheet of side, and remove the "middle" triangle (1/4 of the area). Then remove the "middle" triangle from each of the remaining three triangles, and so on, forever. Let the final object have mass. The moment of inertia of final object about axis passing through 'O' and perpendicular to plane of object is ml²/x. Then the value of x is Take an equilateral triangular sheet of side, and remove the "middle" triangle (1/4 of the area). Then remove the "middle" triangle from eachof the remaining three triangles, and so on, forever. Let the final object have mass. The moment of inertia of final object about axis passingthrough 'O' and perpendicular to plane of object is m/². Then the value of x' is

Here, the scaling arguments and parallel-axis theorem will be used to compute the moment of inertia.…

Take an equilateral triangular sheet of side and remove the "middle" triangle (1/4 of the area). Then remove the "middle" triangle from - The moment of inertia of final object about axis pa of the remaining three triangles, and so on, forever. Let the final object have mass through 'O' and perpendicular to plane of object is m/². Then the value of x' is Â

Take an equilateral triangular sheet of side and remove the "middle" triangle (1/4 of the area). Then remove the "middle" triangle from - The moment of inertia of final object about axis pa of the remaining three triangles, and so on, forever. Let the final object have mass through 'O' and perpendicular to plane of object is m/². Then the value of x' is Â

Classical Dynamics of Particles and Systems

5th Edition

ISBN:9780534408961

Author:Stephen T. Thornton, Jerry B. Marion

Publisher:Stephen T. Thornton, Jerry B. Marion

Chapter11: Dynamics Of Rigid Bodies

Section: Chapter Questions

Problem 11.31P

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