4) Consider the system below. Write the equation of motion and calculate the response assumingthat the system is initially at rest for the values k₁ 100[N/m], k2= 100[N/m], k3 = 200[N/m],100[N/m], k5 = 50[N/m], k6: 50[N/m], and m = = [10kg]. Solve the equation of motionk4=as a differential equation=F(t)=80 cos (20t)K5ΚιwwwK3ΚΑmwwwK6K2

4) Consider the system below. Write the equation of motion and calculate the response assuming that the system is initially at rest for the values k₁ = 100[N/m], k2 = 100[N/m], k3 = 200[N/m], k4 = 100[N/m], k5 = 50[N/m], k6 = 50[N/m], and m = [10kg]. Solve the equation of motion as a differential equation |F(t). = 80 cos (20t) K5 Κι ми KA K3 ww www www K2 M www K6

4) Consider the system below. Write the equation of motion and calculate the response assuming that the system is initially at rest for the values k₁ = 100[N/m], k2 = 100[N/m], k3 = 200[N/m], k4 = 100[N/m], k5 = 50[N/m], k6 = 50[N/m], and m = [10kg]. Solve the equation of motion as a differential equation |F(t). = 80 cos (20t) K5 Κι ми KA K3 ww www www K2 M www K6

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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Concept explainers

Free undamped vibrations

Whenever an object/system displaces in either side of its equilibrium position with the help of an external/internal means, then the object/system moves regularly or randomly on both sides of its equilibrium position. This motion is called vibration. Generally, there are three types of vibration: longitudinal vibration, transverse vibration, and torsional vibration.

Question

4) Consider the system below. Write the equation of motion and calculate the response assuming
that the system is initially at rest for the values k₁ 100[N/m], k2= 100[N/m], k3 = 200[N/m],
100[N/m], k5 = 50[N/m], k6: 50[N/m], and m = = [10kg]. Solve the equation of motion
k4
=
as a differential equation
=
F(t)
=
80 cos (20t)
K5
Κι
www
K3
ΚΑ
m
www
K6
K2

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