The volume V of a liquid crossing through a tube is related to the area of cross-section A, velocity v and time t as `V alpha A^a v^b t^c` which of the following is correct ( given `a != 1` )

If a solid cylinder of area of cross-section A is moving with velocity V in medium of density p then power loss of cylinder is

If velocity v varies with time t as v=2t^(2) , then the plot between v and t^(2) will be given as :

If velocity v varies with time t as v=2t^(2) , then the plot between v and t^(2) will be given as :

The value of drift speeds at cross section (1) and (2) are V_(1) and V_(2) respectively in the conductor shown below in the shape of a truncated cone . Which of the following is correct ?

The mass of the liquid flowing per second per unit area of cross-section of the tube is proportional to (pressure difference across the ends)^(n) and (average velocity of the liquid)^(m) . Which of the following relations between m and n is correct?

Current 'I' flowing through a metallic wire of area of cross-section 'a' is given by the equation I = "naev"_(d) . What is the meaning of the symbols 'n' and ' v_(d) '?

A plot of P vs T for a given mass of gas at constant volume is a straight line . P vs T at constant volumes V_(1) and V_(2) for an ideal gas are shown below : Which of the following is correct ?

The velocity v of a particle moving along x - axis varies with ist position (x) as v=alpha sqrtx , where alpha is a constant. Which of the following graph represents the variation of its acceleration (a) with time (t)?

In the figure, an ideal liquid flows through the tube, which is of uniform cross section. The liquid has velocities v_(A) and v_(B) , and pressures P_(A) and P_(B) at the points A and B , respectively. Then

A liquid flows through a horizontal tube. The velocities of the liquid in the two sections, which have areas of cross section A_(1) and A_(2) are v_(1) and v_(2) respectively. The difference in the levels of the liquid in the two vertical tubes is h . Then