The relation between time t and displacement x is `t = alpha x^2 + beta x,` where `alpha and beta` are constants. The retardation is

The temperature (T) of one mole of an ideal gas varies with its volume (V) as T= - alpha V^(3) + beta V^(2) , where alpha and beta are positive constants. The maximum pressure of gas during this process is

The displacement x of a particle varies with time t as x = ae^(-alpha t) + be^(beta t) . Where a,b, alpha and beta positive constant. The velocity of the particle will.

The displacement x of a particle varies with time t as x = ae^(-alpha t) + be^(beta t) . Where a,b, alpha and beta positive constant. The velocity of the particle will.

Energy due to position of a particle is given by, U=(alpha sqrty)/(y+beta) , where alpha and beta are constants, y is distance. The dimensions of (alpha xx beta) are

The magnitude of radius vector of a point varies with time as r = beta t ( 1- alpha t) where alpha and beta are positive constant. The distance travelled by this body over a closed path must be

The displacement of a particle in a medium due to a wave travelling in the x- direction through the medium is given by y = A sin(alphat - betax) , where t = time, and alpha and beta are constants:

Relation between displacement x and time t is x=2-5t+6t^(2) , the initial acceleration will be :-

Two waves travelling in a medium in the x-direction are represented by y_(1) = A sin (alpha t - beta x) and y_(2) = A cos (beta x + alpha t - (pi)/(4)) , where y_(1) and y_(2) are the displacements of the particles of the medium t is time and alpha and beta constants. The two have different :-

The force of interaction between two atoms is given by F= alpha beta exp(-(x^2)/(alphakt)) , where x is the distance ,k is the Boltzmann constant and T is temperature and alpha " and " beta are two constans. The dimension of beta is :

Find the equation whose roots are (alpha)/(beta) and (beta)/(alpha) , where alpha and beta are the roots of the equation x^(2)+2x+3=0 .