Suppose a quantilty x can be dimensionally represented in terms of M,L and T, that is `[x], M^aL^bT^c`. The quantity mass

A physical quantity x can dimensionally represented in terms of M, L and T that is x=M^(a) L^(b) T^(c) . The quantity time-

Match the physical quantities given on column I with dimensions expressed in terms of mass (M) length (L) time (T), and charge (Q) given in column II and write the correct answer against the matched quantity in a tabular form in your answer book. {:("Column-I",,"Column-II"),("Angular momentum",,[ML^(2)T^(-2)]),("Latent heat",,[ML^(2)Q^(-2)]),("Torque",,[ML^(2)T^(-1)]),("Capacitance",,[ML^(3)T^(-1)Q^(-2)]),("Inductance",,[M^(-1)L^(-2)T^(2)Q^(2)]),("Resistivity",,[L^(2)T^(-2)]):}

If the dimension of a physical quantity are given by M^a L^b T^c, then the physical quantity will be

Suppose a rocket with an intial mass M_(0) eject a mass Deltam in the form of gases in time Deltat , then the mass of the rocket after time t is :-

The dimension of magnetic field in M, L, T and C (Coulomb) is given as :

Dimension of a physical quantity is M^(a)L^(b)T^(c) , then it is ......

A physical quantity is given by X=[M^(a)L^(b)T^(c)] . The percentage error in measurement of M,L and T are alpha, beta, gamma respectively. Then the maximum % error in the quantity X is

You have learnt that a travelling wave in one dimension is represented by a function y= f(x, t) where x and t must appear in the combination x-v t or x + v t , i.e., y= f (x +- v t) . Is the converse true? Examine if the following functions for y can possibly represent a travelling wave: (a) (x-vt)^(2) (b) log [(x + vt)//x_(0)] (c ) 1//(x + vt)

You have learnt that a travelling wave in one dimension is represented by a function y =f (x,t) where x and t must appear in the combination x - vt or x + or v + vt, i.e. y = f ( x pm vt). Is the converse ture ? Examine if the following functions for y can possibly represent a travelling wave: (a) (x-vt)^(2) (b) log [ ((x + v _(t)))/(x _(0))] (c ) (1)/((x + vt))

If the dimensions of a physical quantity are given by M^(x) L^(y) T^(z) , then physical quantity may be