A uniform string of length `L` and mass `M` is fixed at both end while it is subject to a tension `T`. It can vibrate at frequencies `v` given bby the formula (where, `n=1,2,3,………..)`

A string of length 2 m is fixed at both ends. If this string vibrates in its fourth normal mode with a frequency of 500 Hz then the waves wouldf travel on it is with a velocity of

A stretched string of 1 m lengths and mass 5xx10^(-4) having tension of 20 N. if it is plucked at 25 cm from one end, then it will vibrate with frequency

In Melde's experiment, a string of length 0.8 m and mass 1.0 g vibrates in 4 segments when the tension in the string is 0.4 kg-wt. The frequency of the fork is (in perpendicular position)

A 20 cm long string, having a mass of 1.0g , is fixed at both the ends. The tension in the string is 0.5 N . The string is into vibrations using an external vibrator of frequency 100 Hz . Find the separation (in cm) between the successive nodes on the string.

A thin wire of 99 cm is fixed at both ends as shown in figure. The wire is kept under a tension and is divided into three segments of lengths l_(1),l_(2) and l_(3) as shown in figure. When the wire is made to vibrate, the segment vibrate respectively with their fundamental frequencies in the ratio 1:2:3 . Then the lenghts l_(1),l_(2),l_(3) of the segments respectively are (in cm)

At what tension a wire of length 1 m and mass 2 gram will be in resonance with frequency of 350 Hz .

A string of length L is fixed at one end and carries a mass M at the other end . The string makes 2//pi revlutions per second around the vertical axis through the fixed end as shown in the figure, then tension in the string is

A uniform wire under tension , is fixed at its ends. If the ratio of tension in the wire to the square of its length is 360 dyne /cm^2 and fundamental frequency of vibration of wire is 300Hz , find its linear density.

A mass of 5 kg is tied to a string of length 1.0 m and is rotated in vertical circle with a uniform speed of 4m//s . The tension in the string will be 130 N when the mass is at (g= 10 m//s^2 )

A vibrating string of certain length l under a tension T resonates with a mode corresponding to the first overtone (third harmonic) of an air column of length 75cm inside a tube closed at one end. The string also generates 4 beats per second when excited along with a tuning fork of frequency n . Now when the tension of the string is slightly increased the number of beats reduces 2 per second. Assuming the velocity of sound in air to be 340 m//s , the frequency n of the tuning fork in Hz is