Explanation Write the integral expression. I = ∫ 0 R R ⋅ d R R 2 + x 2 Here, R is the radius of disc and x is the distance to any point on the axial line from the center of disc. Use the substitution method to solve the integral. Use the substitution given below. R 2 + x 2 = u (I) Differentiate the expression with respect to x . 2 R d R = d u R d R = 1 2 d u (II) On applying the substitution method, limits of integration will also be changed to new integral. Substitute 0 for x in equation (I) to find the new lower limit. R 2 + 0 = u R 2 = u So the lower limit corresponding to x = 0 is u = R 2

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ISBN: 9781337684668

Author: Katz

Publisher: VST

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Chapter 26, Problem 81PQ

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Prove that ∫0RR⋅dRR2+x2=(R2+x2)−x.

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Chapter 26, Problem 80PQ

Chapter 27.1, Problem 27.1CE

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Chapter 26 Solutions

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Prove that ∫ 0 R R ⋅ d R R 2 + x 2 = ( R 2 + x 2 ) − x .

Solution Summary: The author analyzes the substitution method to solve the integral. R is the radius of disc and x the distance to any point on the axial line.

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Prove that ∫0RR⋅dRR2+x2=(R2+x2)−x.

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Chapter 26 Solutions