Statement I : A standing wave pattern is formed in a string . The power transfer through a point ( other than node and antinode) is zero always.
Statement II : At antinode is perpendicular to this velocity .

S_(1) : A standing wave pattern if formed in a string. The power transfer through a point (other than node and antinode) is zero always S_(2) : if the equation of transverse wave is y= sin 2pi[t/0.04-x/40] , where distance is in cm. time in second, then the wavelength will be 40 cm. S_(3) : if the length of the vibrating string is kept constant, then frequency of the string will be directly proportional to sqrt(T)

Statement I : In standing waves on a string , the medium particles , i.e., different striung elements remain at rest . Statement II : In standing waves all the medium particles attain maximum velocity twice in one cycle.

A standing wave pattern is formed on a string.One of the waves is given by equation y_(1)=a cos(omega t-kx+(pi)/(3)) ,then the equation of the other wave such that x=0 a node is formed is-

Figure shows the standing waves pattern in a string at t = 0. Find out the equation of the standing wave where the amplitude of antinode is 2A.

Statement-I : When velocity of a particle is zero then acceleration of particle is zero. Statement-II : Acceleration is equal to rate of change of velocity.

Statement I : The transverse wave is traveling along a string in the positive x-axis is shown. Points (A & P_1 ) moving downward and point (C & P_2) moving upward. Statement II : In a wave propagating in positive x direction, the points with +ve slope move downward and vice versa.

When a string is vibrating in a standing wave pattern , the power transmitted across an antinode , compared to the power transmitted across a node , is