Essential University Physics: Volume 1 (4th Edition)

Published by Pearson
ISBN 10: 0-134-98855-8
ISBN 13: 978-0-13498-855-9

Chapter 13 - Exercises and Problems - Page 248: 77



Work Step by Step

We use the equation for the period to find: $T = \sqrt{\frac{I}{mgx}}$ $T = \sqrt{\frac{m(x^2+\frac{1}{2}R^2)}{mgx}}$ $T = \sqrt{\frac{(x^2+\frac{1}{2}R^2)}{gx}}$ We take the derivative of the inside of the radical and set it equal to zero to find: $T = \sqrt{\frac{(x+\frac{R^2}{2x})}{g}}$ $0=\frac{1}{g}(1+\frac{-2R^2}{4x^2})$ $0=(1+\frac{-2R^2}{4x^2})$ $-1=(\frac{-2R^2}{4x^2})$ $x =\sqrt{\frac{R^2}{2}}$ Using the first derivative test, we obtain that the minimum will occur at: $x=\frac{1}{\sqrt2}$
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