e 3 ll 42% 16:33A block-spring system has amaximum restoring force Fmax = 0.1%3DN. If the amplitude of the motion is A= 0.01 m and the mass of the block ism = 100 g then the angular frequencyw is equal to20 rad/s5 rad/s10 rad/s2.5 rad/s1.25 rad/sA traveling wave on a taut string witha tension force T, is given by the wavefunction: y(x,t) = 0.05sin(2rtx-100Tt),where x and y are in meters and t is inseconds. If the linear mass density ofthe string is given by u = 0.01 kg/m, e ll 42% A 16:33docs.google.com/forms59A musical note on a piano has afrequency of 31 Hz. If the tension inthe 2-m string is 308 N, and one-halfwavelength occupies the string, whatis the mass of the wire?0.031 kg0.040 kg0.047 kg0.019 kg0.024 kgA simple pendulum is set into motionat two different times with differentinitial conditions. The first time: thebob is in its equilibrium position and

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A block-spring system has a maximum restoring force Fmax = 0.1 N. If the amplitude of the motion is A = 0.01 m and the mass of the block is m = 100 g then the angular frequency w is equal to 20 rad/s O 5 rad/s O 10 rad/s O 2.5 rad/s O 1.25 rad/s

A block-spring system has a maximum restoring force Fmax = 0.1 N. If the amplitude of the motion is A = 0.01 m and the mass of the block is m = 100 g then the angular frequency w is equal to 20 rad/s O 5 rad/s O 10 rad/s O 2.5 rad/s O 1.25 rad/s

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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