Let`vec(V) =v_(x)hat(i)+v_(y)hat(j)+v_(z)hat(k)`, then `int_(t_(1))^(t_(2)) V_(y)` represents: (for the duration `t_(1) to t_(2))`

The quantity int_(t_(1))^(t_(2)) vec(V) dt represents:

If vec(E)=2x^(2) hat(i)-3y^(2) hat(j) , then V (x, y, z)

If vec(E)=2y hat(i)+2x hat(j) , then find V (x, y, z)

For any arbitrary motion in space, which of the following relations are true? (a) v_("average") = (1//2)(v(t_(1)) + v(t_(2))) (b) v_("average") = [r(t_(2))-r(t_(1)]//(t_(2)-t_(1)) (c) v(t) = v(0) + at (d) a_("average") = [v(t_(2))-v(t_(1))]//(t_(2)-t_(1)) The average stands for average of the quantity over time interval t_(1) to t_(2)

An electron of charge -e , mass m, enters a uniform magnetic field vec(B)= B hat(i) with an initial velocity vec(v) = v_(x) hat(i) + v_(y) hat(j) . What is the velocity of the electron after a time interval of t seconds?

A particle moves in XY plane such that its position, velocity and acceleration are given by vec(r)=xhat(i)+yhat(j), " "vec(v)=v_(x)hat(i)+v_(y)hat(j), " "vec(a)=a_(x)hat(i)+a_(y)hat(j) Which of the following condition is correct if the particle is speeding down?

Let r_(1)(t)=3t hat(i)+4t^(2)hat(j) and r_(2)(t)=4t^(2) hat(i)+3t^(2)hat(j) represent the positions of particles 1 and 2, respectiely, as function of time t, r_(1)(t) and r_(2)(t) are in metre and t in second. The relative speed of the two particle at the instant t = 1s, will be