In the circuit shown, charge `q` varies with time `'t'` as `q=t^(3)-t^(2)+4t`, where `q` is in coulombs and time `'t'` is in second. Find `V_(AB)(V_(A)-V_(B))` in volts at time `t=1` sec

In the circuit shown in figure q varies with time t as q=(16t^(2)) . Here q is in coulomb and t in second. Find V_(ab)=(V_(a)-V_(b)) at t=3s

In the circuit shown in figure q varies with time t as q=(16t^(2)) . Here q is in coulomb and t in second. Find V_(ab) "at" t=5s

In the figure shown q is in coulomb and t in second. At time t=1 s

The velocity v of a body moving along a straight line varies with time t as v=2t^(2)e^(-t) , where v is in m/s and t is in second. The acceleration of body is zero at t =

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 :

If v=(t^(2)-4t+10^(5)) m/s where t is in second. Find acceleration at t=1 sec.

In the figure shown V_(ab) at t=1 is

Suppose the emf of the battery, the circuit shown varies with time t so the current is given by i(t)=3+5t , where i is in amperes & t is in seconds. Take R=4Omega, L=6H & find an expression for the battery emf as function of time.

In the circuit shown in figure, circuit is closed at time t=0 . At time t=ln(2) second