If the rms current in a 50 Hz AC circuit is 5 A , the value of the current $1 / 300 \mathrm{~s}$ after its value becomes zero is
An alternating current generator has an internal resistance $R_g$ and an internal reactance $X_g$. It is used to supply power to a passive load consisting of a resistance $R_g$ and a reactance $X_L$. For maximum power to be delivered from the generator to the load, the value of $X_L$ is equal to
When a voltage measuring device is connected to $A C$ mains, the meter shows the steady input voltage of 220 V . This means
To reduce the resonant frequency in an $L-C-R$ series circuit with a generator
Which of the following combinations should be selected for better tuning of an $L-C-R$ circuit used for communication?
An inductor of reactance $1 \Omega$ and a resistor of $2 \Omega$ are connected in series to the terminals of a 6 V (rms) AC source. The power dissipated in the circuit is
The output of a step-down transformer is measured to be 24 V when connected to a 12 W light bulb. The value of the peak current is
As the frequency of an AC circuit increases, the current first increases and then decreases. What combination of circuit elements is most likely to comprise the circuit?
In an alternating current circuit consisting of elements in series, the current increases on increasing the frequency of supply. Which of the following elements are likely to constitute the circuit?
Electrical energy is transmitted over large distances at high alternating voltages. Which of the following statements is (are) correct?
For a $L-C-R$ circuit, the power transferred from the driving source to the driven oscillator is $P=I^2 Z \cos \phi$.
When an $A C$ voltage of 220 V is applied to the capacitor $C$
The line that draws power supply to your house from street has
If a L-C circuit is considered analogous to a harmonically oscillating springblock system, which energy of the L-C circuit would be analogous to potential energy and which one analogous to kinetic energy?
Draw the effective equivalent circuit of the circuit shown in figure, at very high frequencies and find the effective impedance.
Study the circuits (a) and (b) shown in figure and answer the following questions.
(a) Under which conditions would the rms currents in the two circuits be the same?
(b) Can the rms current in circuit (b) be larger than that in (a)?
Can the instantaneous power output of an AC source ever be negative? Can the average power output be negative?
In series $L C R$ circuit, the plot of $I_{\max }$ versus $\omega$ is shown in figure. Find the bandwidth and mark in the figure.
The alternating current in a circuit is described by the graph shown in figure. Show rms current in this graph.
How does the sign of the phase angle $\phi$, by which the supply voltage leads the current in an L-C-R series circuit, change as the supply frequency is gradually increased from very low to very high values.
A device ' $X$ ' is connected to an AC source. The variation of voltage, current and power in one complete cycle is shown in figure.
(a) Which curve shows power consumption over a full cycle?
(b) What is the average power consumption over a cycle?
(c) Identify the device $X$.
Both alternating current and direct current are measured in amperes. But how is the ampere defined for an alternating current?
A coil of 0.01 H inductance and $1 \Omega$ resistance is connected to 200 V , $50 \mathrm{~Hz} A \mathrm{C}$ supply. Find the impedance of the circuit and time lag between maximum alternating voltage and current.
A 60 W load is connected to the secondary of a transformer whose primary draws line voltage. If a current of 0.54 A flows in the load, what is the current in the primary coil? Comment on the type of tansformer being used.
Explain why the reactance provided by a capacitor to an alternating current decreases with increasing frequency.
Explain why the reactance offered by an inductor increases with increasing frequency of an alternating voltage.
7 An electrical device draws 2 kW power from AC mains (voltage 223 V $(\mathrm{rms})=\sqrt{50000} \mathrm{~V}$ ). The current differs (lags) in phase by $\phi\left(\tan \phi=\frac{-3}{4}\right)$ as compared to voltage. Find (a) $R$, (b) $X_C-X_L$ and (c) $I_M$. Another device has twice the values for $R, X_C$ and $X_L$. How are the answers affected?
1 MW power is to be delivered from a power station to a town 10 km away. One uses a pair of Cu wires of radius 0.5 cm for this purpose. Calculate the fraction of ohmic losses to power transmitted if
(i) power is transmitted at 220 V . Comment on the feasibility of doing this.
(ii) a step-up transformer is used to boost the voltage to 11000 V , power transmitted, then a step-down transformer is used to bring voltage to 220 V.
$$\left(\rho_{\mathrm{cu}}=1.7 \times 10^{-8} \text { SI unit }\right)$$
Consider the $L-C-R$ circuit shown in figure. Find the net current $i$ and the phase of $i$. Show that $i=\frac{V}{Z}$. Find the impedance $Z$ for this circuit.
For a $L-C-R$ circuit driven at frequency $\omega$, the equation reads
$$L \frac{d i}{d t}+R i+\frac{q}{C}=V_i=V_m \sin \omega t$$
(a) Multiply the equation by $i$ and simplify where possible.
(b) Interpret each term physically.
(c) Cast the equation in the form of a conservation of energy statement.
(d) Intergrate the equation over one cycle to find that the phase difference between $V$ and $i$ must be acute.
In the $L-C-R$ circuit, shown in figure the $A C$ driving voltage is $V=V_m$ $\sin \omega t$.
(a) Write down the equation of motion for $q(t)$.
(b) At $t=t_0$, the voltage source stops and $R$ is short circuited. Now write down how much energy is stored in each of $L$ and $C$.
(c) Describe subsequent motion of charges.
