Two SHMs are represented by the equations `y1=0.1sin 100 pit+(pi//3)]` and `y2=0.1 cos pit` . The phase difference of the velocity of particle 1 with respect to the velocity of particle 2 at is :

Two simple harmonic are represented by the equation y_(1)=0.1 sin (100pi+(pi)/3) and y_(2)=0.1 cos pit . The phase difference of the velocity of particle 1 with respect to the velocity of particle 2 is.

Two SHM's are represented by y = a sin (omegat - kx) and y = b cos (omegat - kx) . The phase difference between the two is :

Two SHW are represented by the equations x_1 = 20 sin [5pit +pi/4] and x_2 = 10 (sin5pit+sqrt(3) cos 5 pit] . The ratio of the amplitudes of the two motions is

Two SHM are represcnted by equations y_(1)=6cos(6pit+(pi)/(6)),y_(2)=3(sqrt(3)sin3pit+cos3pit)

Two simple harmonic motion are represented by equations y_(1) = 4 sin (10 t + phi) rArr y_(2) = 5 cos 10t What is the phase difference between their velocities ?

If two SHMs are represented by equations y_(1) = 5 sin (2pi t + pi//6) and y_(2) = 5 [sin (3pi) + sqrt3 cos (3pi t)] . Find the ratio of their amplitudes.

Two waves are represented by: y_(1)=4sin404 pit and y_(2)=3sin400 pit . Then :

If two SHMs are represented by equations y_1 = 4 sin[3 pi t + ( pi /3)], y_2 = 4 [sin(3 pi t) + sqrt 3 cos (3 pi t)], then the ratio of their amplitudes is

A wave is represented by the equation y=0.1 sin (100pit-kx) If wave velocity is 100 m s^(-1) , its wave number is equal to