Graph show three waves that are separately send along a string that is stretched under a certain tension along `x-`axis. If `omega_(1).omega_(2)` and `omega_(3)` are their angular frequencies respectively then :

Graph shows three waves that are separately sent along a string that is stretched under a certain tension along x-axis. If omega_(1),omega_(2) and omega_(3) are their angular frequencies, respectively, then:

Graph shows three waves that are separately sent along a string that is stretched under a certain tension along x-axis. If omega_(1),omega_(2) and omega_(3) are their angular frequencies, respectively, then:

Calculate the velocity of a transverse wave along a string of length 2 m and mass 0.06 kg under a tension of 500 N .

The stationary wave y = 2a sinkx cos omega t in a stretched string is the result of superposition of y_(1)=a sin(kx-omegat) and

Show that the angle made by the string with the vertical in a conical pendulum is given by costheta=(g)/(Lomega^(2)) , where L is the string and omega is the angular speed.

A block of weight W is supported by three strings as shown in figure. Which of the following relations is true for tension in the string ? (Here, T_(1), T_(2) and T_(3) are the tension in the strings A,B and C respectively)

Two strings of same material are stretched to the same tension . If their radii are in the ratio 1:2 , then respective wave velocities in them will be in ratio

Two discs of moments of inertia I_(1) and I_(2) about their respective axes (normal to the disc and passing through the centre), and rotating with angular speed omega_(1) and omega_(2) are brought into contact face to face with their axes of rotation coincident . What is the angular speed of the two-disc system ?

Two radio stations broadcast their programmes at the same amplitude A , and at slightly different frequencies omega_(1) and omega_(2) respectively , where omega_(2) - omega_(1) = 10^(3) Hz . A detector receives the signals from the two stations simultaneously . It can emit signals only of intensity ge 2 A^(2) . (i). Find the time intervals between successive maxima of the intensity of the signal received by the detector . ii. Find the time for which the detector remains idle in each cycle of the intensity of the signal .

Two radio stations broadcast their programmes at the same amplitude A and at slightly different frequencies omega_(1) and omega_(2) respectively, where omega_(1) - omega_(2) = 10^(3) Hz . A detector receives the signals from the two stations simultaneously, it can only detect signals of intensity ge 2A^(2) . (i) Find the time interval between successive maxima of the intensity of the signal received by the detector. (ii) Find the time for which the detector remains idle in each cycle of the intensity of the signal.