A transverse wave of equation
`y= 2sin (0.01x + 30 t) `moves on a stretched string from one end to another end.In the equation of wave.x and y are in cm and t in second.The time taken by wave to reach from one to another of string of length 45 cm is

A transverse wave of equation y = 2 sin (0.01 x +30 t) moves on a stretched string from one end to another end. In the equation of wave, x and y are in cm and t is in second. The time taken by wave to reach from one end to another end of string is 5 s. The length of string is

A transverse wave given by y = 2 sin (0.01 x + 30t) moves on a strected string from one end to another end in 0.5 sec. If x and y are in cm and t is in sec, then the length of the string is

The equation of stationary wave along a stretched string is given by y=5 sin (pix)/(3) cos 40 pi t , where x and y are in cm and t in second. The separation between two adjacent nodes is

The equation of a wave id represented as Y=2sin(Πx - 200Πf) where x and y are in cm and t is in second. The wave velocity is

A transverse wave described by y = 0.5 sin ( x + 40 t) is propagating on a vibrating string of linear density 0.01 kg/m. If x and y are in metre and time is in second, then the tension in the wire is

The equation of a wave travelling on a stretched string is y = 4 sin 2 pi ((t)/(0.02)-(x)/(100)) Here, x and y are in cm and t is in second. The speed of wave is

A transverse wave propagating on the string can be described by the equation y=2sin(10x+300t) where x and y are in metres and t in second.If the vibrating string has linear density of 0.6times10^(-3)g/cm ,then the tension in the string is

A wave along a string has the equation y = 0.02 sin (30 t - 4x) , where x and y are in m and t in second the amplitude of the wave is

A wave is represented by the equation, y = 0.1 sin (60 t + 2x) , where x and y are in metres and t is in seconds. This represents a wave