Transverse waves are produced in a stretched wire. Both ends of the string are fixed. Let us compare between second overtone mode (in numerator) and fifth harmonic, mode (in denominator).
match the following column-I with column-II

A string fixed at both ends first oscillates in its fundamental mode then in second harmonic mode.Then match the following.

A wire is stretched and fixed at two ends. Transverse stationary waves are formed in it. It oscillates in its third overtone mode. The equation of stationary wave is y= A sin kx cos omegat Choose the correct options.

Assertion: A wire is stretched and then fixed at two ends. It oscillates in its second overtone mode. There are total four nodes and three antinodes. Reason: In second overtone mode, length of wire should be l=(3lambda)/2 , where lambda is wavelength.

Consider a uniform wire of length l . Cross-sectional area A, Young's modulus of the material of the wave is Y. Some information related to the wire is given in column-1 and dependence of the result is given in column-2. Then match the approprite choice between the columns and match the list given in options {:("Column-I"" ""Column-II"),("(A) Let us suspend wire vertically from a"" ""(p) Young'sModulus" ),("rigud support and attach a mass m at"),("its lower end. If the mass is slightly pulled"),("down and released, it executes S.H.M"),("of a time period which will depend on"),("(B) Work done in stretching the wire up to length"" ""(q) elongation (x)"),(l+x "will depend on"),("(C) If the given is fixed between two rigid"" ""(r) length (l)"),("supports and its temperature is decreased"),("thermal stress that develops in the wire"),("will depend on"),("(D) If the wire is pulled at its ends equal and"" ""(s) area of cross-section (A) "),("opposite forces of magnitude F so that it"),("undergoes an elongation x, according to"),("Hook's law, F=kx, where k is the force"),("constant.Force constant (k) of the wire"),("will depend on"):}

A stretched wire is oscillating in third overtone mode. Equation of transverse stationary wave produced in this wire is y= A sin (6pix)sin(20pit) Here, x is in metres. Find the length of the wire.

A string of length 50 cm and mass 12.5 g is fixed at both ends. A pipe closed at one end has a length 85 cm . When the string vibrates in its second overtone and the air column in the pipe in its first. Overtone, they produce a beats frquency of 6 Hz . It is also observed that decreasing teh tension in the string decreaes beats frequency. Neglect the end correction in the pipe and velocity of sound in air is 340 m//s . then the tension in the string is

A bob is attached to a string of length l whose other end is fixed and is given horizontal velocity at the lowest point of the circle so that the bob moves in a vertical plane. Match the velocity given at the lowest point of circle in column I with tension and velocity at the highest point of the circle corresponding to velocity of column I of column II

(a) Distinguish between transverse wave and longitudinal wave. Give one example of each type. (b) A stretched string of length I and under a tension T, emits a note of fundamental frequency n. The tension is now reduced to T/2 and the vibrating length changed so that the frequency of the second harmonic is equal to n. Find out the new length of the string in terms of its original length.

A standing wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . Now answer the following question: In which of the following modes the emf induced in AB is always zero?

A stsnding wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . Now answer the following question: In which of the following modes the emf induced in AB is always zero?