A string 1 has the length, twice the radius,two the tension and twice the density of another string The relation between the fundamental frequecy 1 and 2 is

String B has twice the length , twice the diameter twice the tension and twice the density of string A. Then the overtone of B that will be in unison will A is

A string A has double the length, double the tension, double the diameter and double the density as another string B . Their fundamental frequencies of vibration are n_(A) and n_(B) respectively. The ratio n_(A)//n_(B) is equal to

The linear density of a stretched string is increased by 1%. Then the change in fundamental frequency of string is

An open organ pipe of length 1m contains a gas whose density is twice the density of atmosphere at STP. Find the difference between fundamental and second harmonic frequencies if speed of sound in atmosphere is 300 m/s.

For a constant vibrating length, density of the material and tension in the string the fundamental frequency of the vibrating stringis

A musical instrument is made using four different metal strings, 1, 2, 3 and 4 with mass per unit length mu,2mu,3mu and 4mu respectively. The instrument is played by vibrating the strings by varying the free length in between the range L_0 and 2L_0 . It is found that in string-1 (mu) at free length L_0 and tension T_0 the fundamental mode frequency is f_0 . List-I gives the above four strings while list-II lists the magnitude of some quantity. If the tension in each string is T_0 , the correct match for the highest fundamental frequency in f_0 units will be -

The length , radius , tension and density of string A are twice the same parameters of string B . Find the ratio of fundamental frequency of B to the fundamental frequency of A .

A string is fixed at both ends. The tension in the string and density of the string are accurately known but the length and the radius of cross section of the string are known with some errorl If maximum errors made in the measurements of length and radius are 1% and 0.5% respectively them what is the maximum possible percentage error in the calculation of fundamental frequencyof the that string ?

In question 3 of the same exercise, the radius of the sphere is a . The length of the string is also a . Find tension in the string.

A string fixed at both ends has consecutive standing wave modes for which the distances between adjacent nodes are 18 cm and 16 cm, respectively. (a) What is the minimum possible length of the string? (b) If the tension is 10 N and the linear mass density is 4 g/m, what is the fundamental frequency?