Assuming that the mass m of of the largest stone that can be moved by a flowing river depends upon the velocity v of the water, its density p and the acceleration due to gravity g.Then m is directly proportional to

Assuming that the mass m of the largest stone that can be moved by a flowing river depends upon the velocity v of the water , its density rho , and the acceleration due to gravity g . Then m is directly proportinal to

Assuming that the mass m of the largest stone that can be moved by a flowing river depends upon the velocity upsilon, of water, its density rho and acceleration due to gravity g, then m is directly proportional to

It is given that the mass m of the largest stone that can be moved by the folowing river depends upon the velocity v, density rho and acceleration due gravity g. Using dimensions show that m=(kv^(6)rho)/(g^(3)) .

Assume that the largest stone of mass 'm' that can be moved by a flowing river depends upon the velocity of flow v, the density d & the acceleration due to gravity g. I 'm' varies as the K^(th) power of the velocity of flow, then find the value of K.

The velocity of water wave v may depend on their wavelength lambda , the density of water rho and the acceleration due to gravity g . The method of dimensions gives the relation between these quantities as

Derive an expression for the time period (T) of a simple pendulum which may depend upon the mass (m) of the bob, length (l) of the pendulum and acceleration due to gravity (g).

The period P of a simple pendulum is the time for one complete swing. How does P depend on the mass m of the bob, the length l of the string, and the acceleration due to gravity g?

If pressure P, velocity of light c and acceleration due to gravity g are chosen as fundamental units, then dimensional formula of mass is

If pressure P, velocity of light C and acceleration due to gravity g are chosen as fundamental units, then dimensional formula of mass is

The buoyant force F acting on a body depends on the density of medium rho , volume of body immerese V and acceleration due to gravity g . Establish the relation using method of dimensions.