A one-dimensional system of two bodies of mass m₁ and m2 and three springs with Hooke's law constants k₁, k2, and k3 is fixed between two walls as shown in the figure. The displacements of the two bodies from their equilibrium positions are î₁ and £2, as shown in the figure. m 1 Foooooooooooo k₂ X₁ M k₁ a) Write down the total force acting on each of the two bodies. (Note it is not necessary to determine the equilibrium positions relative to the walls.) b) Write down the equations of motion for the two bodies. c) Hereafter assume m₁ = m, m₂ = 2m and k₁= k2 = k3 = k. Show the equations of motion in the matrix form is where M and G are 2 × 2 matrices with - Mx + Gx = 0 m (TO 2) 0 X2 and G = m2 2k - k -k 2k k3

A one-dimensional system of two bodies of mass m₁ and m2 and three springs with Hooke's law constants k₁, k2, and k3 is fixed between two walls as shown in the figure. The displacements of the two bodies from their equilibrium positions are î₁ and £2, as shown in the figure. m 1 Foooooooooooo k₂ X₁ M k₁ a) Write down the total force acting on each of the two bodies. (Note it is not necessary to determine the equilibrium positions relative to the walls.) b) Write down the equations of motion for the two bodies. c) Hereafter assume m₁ = m, m₂ = 2m and k₁= k2 = k3 = k. Show the equations of motion in the matrix form is where M and G are 2 × 2 matrices with - Mx + Gx = 0 m (TO 2) 0 X2 and G = m2 2k - k -k 2k k3

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Description: A one-dimensional system of two bodies of mass m₁ and m2 and three springs withHooke's law constants k₁, k2, and k3 is fixed between two walls as shown in the figure.The displacements of the two bodies from their equilibrium positions are î₁ and £2,

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter5: Newton's Laws Of Motion

Section: Chapter Questions

Problem 44PQ: A student working on a school project modeled a trampoline as a spring obeying Hookes law and...

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