The wave progresses along the x-axis with time t. The instantaneous displacement from the mean position is given by y = a sin `[(omegat-kx)+theta]`. Then the dimensions are

y = A sin(omega t- kx) Cm this equation find out the dimension of omega ?

In case of a simple harmonic motion, if the velocity is plotted along the X-axis and the displacement (from the equilibrium position) is plotted along the Y-axis, the resultant curve happens to be an ellipse with the ratio ("major axis (along X)")/("minor axis (along Y)")=20pi What is the frequency of the simple harmonic motion?

In case of a simple harmonic motion, if the velocity is plotted along the X-axis and the displacement (from the equilibrium position) is plotted along the Y-axis, the resultant curve happens to be an ellipse with the ratio: ("major axis(along X)")/("minor axis(alongY)")=20pi What is the frequency of the simple harmonic motion?

An EM wave is propagating in a medium with a velocity vec v = v hati . The instantanous oscillating electric field of this EM wave is along + y axis , then the direction of oscillating magnetic field of the EM wave will be along

The equation of progressive wave is y = A sin (kx - omega t) . What is the maximum velocity?

An EM wave is propagating in a medium with a velocity vecv=vhati . The instantaneous oscillating electric field of this EM wave is along +y axis. Then the direction of oscillating magnetic field of the EM wave will be along

The potential energy of a spring pendulum, with a mass m connected to it, is given by V=1/2kx^(2) (where x = displacement from the position of equilibrium and k = a constant). How does the applied force on the mass vary with displacement?