Equation of travelling wave on a stertched string of linear density `5 g // m` is y=00.3 sin (450 t - 9 x) where distance and time are measured in SI units. The tension in the string is

A transverse wave propagating on a stretched string of linear density 3 xx 10^-4 kg-m^-1 is represented by the equation y=0.2 sin (1.5x+60t) Where x is in metre and t is in second. The tension in the string (in Newton) is

A transverse wave propagating on a stretched string of linear density 3xx10^-4 kg-m^-1 is represented by the equation y=0.2sin(1.5x+60t) Where x is in metre and t is in second. The tension in the string (in Newton) is

The linear density of a vibrating string is 1.3 xx 10^(-4) kg//m A transverse wave is propagating on the string and is described by the equation y= 0.021 sin (x + 30 t) where x and y are measured in meter and t t in second the tension in the string is :-

The linear density of a vibrating string is 1.3 xx 10^(-4) kg//m A transverse wave is propagating on the string and is described by the equation y= 0.021 sin (x + 30 t) where x and y are measured in meter and t t in second the tension in the string is :-

The linear density of a vibrating string is 1.3 xx 10^(-4) kg//m A transverse wave is propagating on the string and is described by the equation y= 0.021 sin (x + 30 t) where x and y are measured in meter and t t in second the tension in the string is :-

The linear density of a vibrating string is 2xx10^(-4) kg/m. A transverse wave is propagating on the string and is described by the equation y=0.021 sin (x + 30 t) where x and y are in metre and t is in second. The tension in the string is