The charge flown through a circuit in the time interval between `t and t+dt` is givne by `edq=e^(-t/tau)dt,` where `tau` is a constnt. Find the total charge flown through the circuit betweent `t=0 to t=tau`.

The current in a discharging LR circuit is given by I = i_0 (t/tau) where tau is the time constant of the circuit. Calculate the rms current for the period t = 0 to t = tau .

The charge flowing through a resistance R varies with time t as Q= at-bt^2 , where a and b are positive constants. The total heat produced in R is

The current through an element is shown in the figure. Determine the total charge that pass through the element at t = 0s

The current through an element is shown in the figure. Determine the total charge that pass through the element at t = 5s

The current through an element is shown in the figure. Determine the total charge that pass through the element at t = 2s

Evaluate where A and omega are constants. int^t_0 A sin omega dt

Let I be the purchase value of an equipment and V(t) be the value after it has been used for t years. The value V(t) depreciates at a rate given by differential equation (d V(t)/(dt)=-k(T-t) , where k"">""0 is a constant and T is the total life in years of the equipment. Then the scrap value V(T) of the equipment is : (1) T^2-1/k (2) I-(k T^2)/2 (3) I-(k(T-t)^2)/2 (4) e^(-k T)

The velocity of a particle is given by the equation, v = 2t^(2) + 5 cms^(-1) . Find the average acceleration during the time interval between t_(1) = 2s and t_(2) = 4s .

A particle moving along x-axis has accelaration f, at time t , given by f=f_0(1− t/ T ​ ) where f_0 and T are constants . The particle at t=0 has zero velocity . In the time interval between t=0 and the instant when f=0, the particle's velocity (nu_x) is:

The current through an element is shown in the figure. Determine the total charge that pass through the element at a) t= 0s, b) t = 2s, c) t = 5s