If the depression d at the end of a loaded bar is given by `d = (Mg l^3)/(3 yi)` where M is the mass , `l ` is the length and y is the young's modulus, then i has the dimensional formula

The frequency (n) of vibration of a string is given as n = (1)/( 2 l) sqrt((T)/(m)) , where T is tension and l is the length of vibrating string , then the dimensional formula for m is

The frequency of vibration of string is given by v=p/(2l)[F/m]^(1//2) . Here p is number of segments in the string and l is the length. The dimensional formula for m will be

Suppose, the torque acting on a body, is given by tau = KL+(MI)/(omega) Where L = angular momentum, I = moment of inertia & omega = angular speed What is the dimensional formula for K & M?

By the method of dimensions, test the accuracy of the equation : delta = (mgl^3)/(4bd^3Y) where delta is depression in the middle of a bar of length I, breadth b, depth d, when it is loaded in the middle with mass m. Y is Young's modulus of material of the bar.

A horizontal rod is supported at both ends and loaded at the middle. If L and Y are length and Young's modulus repectively, then depression at the middle is directly proportional to

A point mass m is suspended at the end of a massless wire of length l and cross section. If Y is the Young's modulus for the wire, obtain the frequency of oscillation for the simple harmonic motion along the vertical line.

A thin rod of negligible mass and area of cross section S is suspended vertically from one end. Length of the rod is L_(0) at T^(@)C . A mass m is attached to the lower end of the rod so that when temperature of the rod is reduced to 0^(@)C its length remains L_(0) Y is the Young’s modulus of the rod and alpha is coefficient of linear expansion of rod. Value of m is :

A wire of length L and area of cross-section A, is stretched by a load. The elongation produced in the wire is I. If Y is the Young's modulus of the material of the wire, then the force constant of the wire is

Show dimensionally that the expression , T = (MgL)/(pi r^(2)l is dimensionally correct , where T is Young 's modulus of the length of the wire ,Mg is the weight applied in the wire and L is the original length of the wire ,and l is the increase in the length of the wire .

A bar of mass m and length l is hanging from point A as shown in figure.Find the increase in its length due to its own weight. The young's modulus of elasicity of the wire is Y and area of cross-section of the wire is A.