NOTE PLEASE SHOW CODE FOR OCTAVE OR MATLABF(t) = 300N Compute the response of the system in Figure P2.97 for the case that the damping is linearviscous, the spring is a nonlinear soft spring of the formk(x) = kx - k₁x³and the system is subject to a harmonic excitation of 300 N at a frequency equal to the naturalfrequency (w = wn) and initial conditions of xp = 0.01 m and vo= 0.1 m/s. The system has a massof 100 kg, a damping coefficient of 15 kg/s, and a linear stiffness coefficient of 2000 N/m. Thevalue of k1 is taken to be 100 N/m³. Compute the solution and compare it to the hard springsolution (k(x) = kx + k₁x³).►x (1)mFigure P2.97F(t)

Answered: Compute the response of the system in…

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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6. The electro-mechanical system shown below consists of an electric motor with input voltage V which drives inertia I in the mechanical system (see torque T). Find the governing differential equations of motion for this electro-mechanical system in terms of the input voltage to the motor and output displacement y. Electrical System puthiy C V V₁ R bac (0) T bac T Motor - Motor Input Voltage - Motor Back EMF = Kbac ( - Motor Angular Velocity - Motor Output Torque = K₂ i Kbacs K₁ - Motor Constants Mechanical System M T Frictionless Support
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