The amplitude of the vibrating particle due to superposition of two `SHMs`,
`y_(1)=sin (omega t+(pi)/(3)) and y_(2)=sin omega t` is :

The resultant ampiltude of a vibrating particle by the superposition of the two waves y_(1) = a sin ( omega t + (pi)/(3)) and y_(2) = a sin omega t is :

The resultant amplitude of a vibrating particle by the superposition of the two waves y_(1)=asin[omegat+(pi)/(3)] and y_(2)=asinomegat is

The equations of two SH M's are X_(1) = 4 sin (omega t + pi//2) . X_(2) = 3 sin(omega t + pi)

The amplitide of a particle due to superposition of following S.H.Ms. Along the same line is {:(X_(1)=2 sin 50 pi t,,X_(2)=10 sin(50 pi t +37^(@))),(X_(3)=-4 sin 50 pi t,,X_(4)=-12 cos 50 pi t):}

The ratio of amplitudes of following SHM is x_(1) = A sin omega t and x_(2) = A sin omega t + A cos omega t

The resultant amplitude due to superposition of three simple harmonic motions x_(1) = 3sin omega t , x_(2) = 5sin (omega t + 37^(@)) and x_(3) = - 15cos omega t is

Wave equations of two particles are given by y_(1)=a sin (omega t -kx), y_(2)=a sin (kx + omega t) , then

What is the amplitude of the S.H.M. obtained by combining the motions. x_(1)=4 "sin" omega t cm, " " x_(2)=4 "sin"(omega t + (pi)/(3)) cm

If two independent waves are y_(1)=a_(1)sin omega_(1) and y_(2)=a_(2) sin omega_(2)t then

Two wave are represented by equation y_(1) = a sin omega t and y_(2) = a cos omega t the first wave :-