Please do not copy For the system below, find the transfer function from fi to x (driving point receptance) and fromfi to i, (driving point accelerance). What is the acceleration response of mass m, if m; = 2 kg, m2= 4 kg, k = 40 N/m, k =100 N/m, and ka = 200 N/m, filt) = 20 cos(3t) N and falt) = 0?For the same system, now determine the acceleration response of mass m2 if fi(t) = 20 cos(3t) Nand fa(t) = 10 cos(81).

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For the system below, find the transfer function from fi to x: (driving point receptance) and from f. to ž (driving point accelerance). What is the acceleration response of mass m; if mị = 2 kg, m2 = 4 kg, k = 40 N/m, k =100 N/m, and k = 200 N/m, filt) = 20 cos(31) N and fa(t) = 0? m, ww For the same system, now determine the acceleration response of mass m2 if fi(t) = 20 cos(3t) N %3D and fa(t) = 10 cos(81).

For the system below, find the transfer function from fi to x: (driving point receptance) and from f. to ž (driving point accelerance). What is the acceleration response of mass m; if mị = 2 kg, m2 = 4 kg, k = 40 N/m, k =100 N/m, and k = 200 N/m, filt) = 20 cos(31) N and fa(t) = 0? m, ww For the same system, now determine the acceleration response of mass m2 if fi(t) = 20 cos(3t) N %3D and fa(t) = 10 cos(81).

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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