MCQ Questions for Class 12 Medical Physics Alternating Current Quiz 1

Which one of the following represents capacitive reatance versus angular frequency graph?

The frequency at which $$1\ H$$ inductor will have a reactance of $$2500\ \Omega$$ is:

0%
$$418\ Hz$$
0%
$$378\ Hz$$
0%
$$398\ Hz$$
0%
$$406\ Hz$$

A series AC circuit has a resistance of $$4\Omega $$ and a reactance of $$3\Omega$$. The impedance of the circuit is

0%
$$5\,\Omega$$
0%
$$7\,\Omega$$
0%
$$12/7\,\Omega$$
0%
$$7/12\,\Omega$$

The ratio of peak value and r.m.s value of an alternating current is

0%
$$ 1 $$
0%
$$ \dfrac{1}{2} $$
0%
$$ \sqrt{2} $$
0%
$$ \dfrac{1}{\sqrt{2}} $$

In a circuit $$LC = 10^{-3}H, C = 10^{-3} F$$. Find angular frequency.

0%
$$1000 \,rad/sec$$
0%
$$100 \,rad/sec$$
0%
$$10 \,rad/sec$$
0%
$$10^{-3} \,rad/sec$$

Alternating current is flowing in inductance $$L$$ and resistance $$R$$. The frequency of source is $$\omega/2\pi$$ Which of the following statement in correct:

0%
For low frequency the limiting value of impedance is $$L$$.
0%
For high frequency the limiting value of impedance is $$\omega L$$.
0%
For high frequency the limiting value of impedance is $$R$$.
0%
For low frequency the limiting value of impedance is $$\omega L$$.

The power factor of L-R circuit is :

0%
$$\dfrac{R}{\omega L}$$
0%
$$\dfrac{R}{(\omega L)^2+R^2}$$
0%
$$\omega LR$$
0%
$$\sqrt{\omega LR}$$

Current in the circuit is wattless, if

0%
Inductance in the circuit is zero
0%
Resistance in the circuit is zero
0%
Current is alternating
0%
Resistance and inductance both are zero

An inductance of $$2H$$ , capacitance of $$8\mu F$$ and resistance of $$10K\Omega$$ are connected in series to an AC source of $$100V$$ with adjustable frequency. The angular frequency at which current in the circuit is maximum is :

0%
$$50 \ rad/s$$
0%
$$100 \ rad/s$$
0%
$$125 \pi \ rad/s$$
0%
$$250 \ rad/s$$

If $${W_1}and\;{W_2}$$ are half power frequencies of series LCR circuit, Then the reasonant frequency of the circuit is-

0%
$$\sqrt {{W_1}\;{W_2}} $$
0%
$$\frac{{{W_1} + {W_2}}}{2}$$
0%
$$\sqrt {\frac{{{W_1} + {W_2}}}{2}} $$
0%
$$\frac{{{W_1} -{W_2}}}{2}$$

In an a.c. circuit consisting of resistance $$R$$ and inductance $$L$$, the voltage across $$R$$ is $$60$$ volt and that across $$L $$ is $$80$$ Volt.The total Voltage across the combination is

0%
$$140 V$$
0%
$$20 V$$
0%
$$100 V$$
0%
$$70 V$$

In a series LCR circuit, the voltage across R is 100 volts and R = 1 $$k\Omega$$ with C = $$2\mu F$$. The resonant frequency $$\omega$$ is 200 rad/s. At resonance the voltage across L is-

0%
$$2.5 \times 10^{-2}V$$
0%
$$40 V$$
0%
$$250 V$$
0%
$$4 \times 10^{-3}V$$

The instantaneous value of emf and current in an A.C. circuit are; $$E=1.414sin\left ( 100\pi t-\frac{\pi }{4} \right )$$ , $$I=0.707sin(100\pi t)$$ . The admittance of the circuit will be _______ mho.

0%
$$\dfrac{1}{\sqrt{2}}$$
0%
$$\sqrt{2}$$
0%
$$\dfrac{1}{2}$$
0%
$$2$$

The instantaneous value of emf and current in an A.C. circuit are $$E=1.414$$sin( $$100\pi t-\frac{\pi }{4} $$) , $$ I=0.707$$ sin($$100\pi t$$) . The resistance of the circuit is

0%
$$2\Omega $$
0%
$$\sqrt{2}\Omega $$
0%
$$\frac{1}{\sqrt{2}}\Omega$$
0%
$$\frac{1}{2}\Omega$$

$$A$$ series $$R-C$$ circuit is connected to $$AC$$ voltage source. $$C$$onsider two cases; ($$A$$) when $$C$$ is without a dielectric medium and (B) when $$C$$ is filled with dielectric of constant $$4$$. The current $$I_{R}$$ through the resistor and voltage $$V_{C}$$ across the capacitor are compared in the two cases. Which of the following $$is/are$$ true?

0%
$$I_{R}^{A}>I_{R}^{B}$$
0%
$$I_{R}^{A} < I_{R}^{B}$$
0%
$$V_{c}^{A}>V_{c}^{B}$$
0%
$$V_{C}^{A} < V_{R}^{C}$$

The instantaneous value of emf and current in an A.C. circuit are; $$E=1.414sin\left ( 100\pi t-\frac{\pi }{4} \right )$$ , $$I=0.707sin(100\pi t)$$ . The impedance of the circuit will be

0%
$$1\Omega $$
0%
$$2\Omega $$
0%
$$\sqrt{2}\Omega $$
0%
$$\dfrac{1}{2}\Omega $$

The capacitive reactance of 50 $$\mu$$F capacitance at a frequency of $$2 \times 10^{3}$$Hz will be ____ $$\Omega $$

0%
$$\frac{2}{\pi }$$
0%
$$\frac{3}{\pi }$$
0%
$$\frac{4}{\pi }$$
0%
$$\frac{5}{\pi }$$

The phase angle between current and voltage in a purely inductive circuit is :

0%
$$zero$$
0%
$$\pi $$
0%
$$\pi $$/4
0%
$$\pi $$/2

In an LCR circuit, capacitance is changed from C to 2C. For the resonant frequency to remain unchanged, the inductance should be changed from L to :

0%
4L
0%
2L
0%
L/2
0%
L/4

When the rms voltages $$V_L, V_C$$ and $$V_R$$ are measured respectively across the inductor L, the capacitor C and the resistor R in a series LCR circuit connected to an AC source, it is found that the ratio $$V_L : V_C : V_R=1 : 2 : 3$$. If the rms voltage of the AC source is 100 V, then $$V_R$$ is close to :

0%
50 V
0%
70 V
0%
90 V
0%
100 V

In a series resonant $$LCR$$ circuit, the voltage across $$R$$ is $$100\ volts$$ and $$R = 1k\ \Omega $$ with $$C=2\ \mu F$$. The resonant frequency is $$200\ rad/s$$. At resonance the voltage across $$L$$ is

0%
$$4$$ x $$10^{-3}\ V$$
0%
$$2.5$$ x $$10^{-2}\ V$$
0%
$$40\ V$$
0%
$$250\ V$$

In an LCR circuit as shown below both switches are open initially. Now switch $$S_{1}$$ is closed, $$S_{2}$$ kept open. ( $$q$$ is charge on the capacitor and $$\tau=RC$$ is capacitive time constant). Which of the following statement is correct?

0%
At $$ t=\tau,\ q=CV/2$$
0%
At $$ t=2\tau,\ q=CV(1-e^{-2})$$
0%
At $$ t=\frac{T}{2},\ q=CV(1-e^{-1})$$
0%
Work done by the battery is half of the energy dissipated in the resistor.

In a series LCR circuit $$\mathrm{R}=200\ Omega$$ and the voltage and the frequency of the main supply is $$220$$ $$V$$ and $$50$$ $$Hz$$ respectively. On taking out the capacitance from the circuit the current lags behind the voltage by $$30^0$$. On taking out the inductor from the circuit the current leads the voltage by $$30^0$$. The power dissipated in the LCR circuit is

0%
$$305$$ $$\mathrm{W}$$
0%
$$210$$ $$\mathrm{W}$$
0%
$$Zero \mathrm{W}$$
0%
$$242$$ $$\mathrm{W}$$

An arc lamp requires a direct current of 10A at 80V to function. If it is connected to a 220V (rms), 50 Hz AC supply, the series inductor needed for it to work is close to:

0%
80H
0%
0.08H
0%
0.044H
0%
0.065H

In an a.c. circuit, the instantaneous e.m.f. and current are given by $$e=100 \sin 30t$$, $$i=20\sin\left(30t -\displaystyle\frac{\pi}{4}\right)$$. In one cycle of a.c., the average power consumed by the circuit and the wattles current are, respectively.

0%
$$\displaystyle\frac{50}{\sqrt{2}}, 0$$
0%
$$50, 0$$
0%
$$50, 10$$
0%
$$\displaystyle\frac{1000}{\sqrt{2}}, 10$$

In an LCR series a.c. circuit, the voltage across each of the components. L, C and R is 50 V. The voltage across the LC combination will be;

0%
$$50\ \text{V}$$
0%
$$50\sqrt{2}\mathrm{v}$$
0%
$$100\ \text{V}$$
0%
$$0\mathrm{V}$$ (zero)

In the given circuit, the AC source has $$\omega =100 rad/s$$. Considering the inductor and capacitor to be ideal, the correct choice(s) is(are) :

0%
The current through the circuit, $$I$$ is 0.3 A.
0%
The current through the circuit, $$I$$ is $$0.3\sqrt{2}$$ A.
0%
The voltage across $$ 100\Omega$$ resistor $$=10\sqrt{2}$$ V.
0%
The voltage across $$ 50\Omega$$ resistor $$=10$$ V.

In the circuit shown, $$L = 1 \mu H, C = 1 \mu F$$ and $$R = 1 k\Omega$$. They are connected in series with an a.c. source $$V = V_0 \sin \omega t$$ as shown. Which of the following options is/are correct?

0%
At $$\omega >> 10^6 rad. s^{-1}$$, the circuit behaves like a capacitor
0%
At $$\omega \sim 0$$ the current flowing through the circuit becomes nearly zero
0%
The current will be in phase with the voltage if $$\omega = 10^4rad. s^{-1}$$
0%
The frequency at which the current will be in phase with the voltage is independent of $$R $$

A series LR circuit is connected to a voltage source with $$V\left( t \right) ={ V }_{ 0 }\sin { \Omega t } $$. After very large time, current $$I\left( t \right) $$ behaves as $$\left( { t }_{ 0 }\gg \frac { L }{ R } \right) $$

$$A$$ series $$R-C$$ combination is connected to an $$AC$$ voltage of angular frequency $$(\omega =500radian/s$$. lf the impedance of the $$R-C$$ circuit is $$R\sqrt{1.25}$$, the time constant (in millisecond) of the circuit is

0%
1
0%
2
0%
3
0%
4

A $$40 \mu F$$ capacitor is connected to a $$200 V,\ 50 Hz \ ac$$ supply. The rms value of the current
in the circuit is, nearly :

0%
$$2.05 A$$
0%
$$2.5 A$$
0%
$$25.1 A$$
0%
$$1.7 A$$

A series R-C circuit is connected to an alternating voltage source. Consider two situation:
(a) When capacitor is filled
(b) When capacitor is mica filled
Current through resister is i and voltage across capacitor is V then :

0%
$$V_a=V_b$$
0%
$$V_a < V_b$$
0%
$$V_a>V_b$$
0%
$$i_a = i_b$$

An inductor $$20$$ mH, a capacitor $$100$$ $$\mu$$F and a resistor $$50$$ $$\Omega$$ are connected in series across a source of emf, V$$=10$$ $$\sin 314$$t. The power loss in the circuit is?

0%
$$2.74$$ W
0%
$$0.79$$ W
0%
$$1.13$$ W
0%
$$0.43$$ W

0%
Both Assertion and Reason are correct and Reason is the correct explanation for Assertion
0%
Both Assertion and Reason are correct but Reason is not the correct explanation for Assertion
0%
Assertion is correct but Reason is incorrect
0%
Both Assertion and Reason are incorrect

A condenser of $$250\mu F$$ is connected in parallel to a cell of inductance $$0.16$$ mH, while its effective resistance is while its. Determine the resonant frequency.

0%
$$9\times 10^4$$Hz
0%
$$16\times 10^7$$ Hz
0%
$$8\times 10^5$$ Hz
0%
$$9\times 10^3$$ Hz

Reciprocal of Impedance is:

0%
Susceptance
0%
Conductance
0%
Admittance
0%
Transconductance

A $$10\ \mu F$$ capacitor is connected across a $$200\ V$$, $$ 50 \ Hz$$ A.C. supply. The peak current through the circuit is :

0%
$$0.6\ A$$
0%
$$0.6\sqrt{2}A$$
0%
$$(0.06\sqrt{2})A$$
0%
$$0.6{\pi}\ A$$

If resonant frequency is $$f$$ and capacitance become $$4$$ times, then resonant frequency will be :

0%
$$\dfrac {f}{2}$$
0%
$$2f$$
0%
$$f$$
0%
$$\dfrac {f}{4}$$

In a circuit, the frequency is $$f=\dfrac{1000}{2\pi }$$Hz and the inductance is 2 henry, then the reactance will be

0%
200$$\Omega $$
0%
200$$ \mu$$ $$\Omega $$
0%
2000$$\Omega $$
0%
2000$$ \mu$$ $$\Omega $$

The instantaneous value of emf and current in an A.C. circuit are: $$E=1.414sin\left ( 100\pi t-\frac{\pi }{4} \right )$$, $$I=0.707sin(100\pi t)$$ .The reactance of the circuit
will be

0%
$$\sqrt{2}$$ $$\frac{1}{2}\Omega$$
0%
2$$\Omega$$
0%
$$\frac{1}{2}\Omega$$
0%
$$\frac{1}{\sqrt{2}}\Omega$$

The instantaneous value of emf and current in an
A.C. circuit are; $$E=1.414sin\left ( 100\pi t-\dfrac{\pi }{4} \right )$$ ,
$$I=0.707sin(100\pi t)$$ . RMS value of current will be

0%
1A
0%
$$\dfrac{1}{\sqrt{2}}A$$
0%
$$\sqrt{2}A$$
0%
$$\dfrac{1}{2}A$$

The instantaneous value of emf and current in an A.C. circuit are; $$E=1.414sin\left ( 100\pi t-\dfrac{\pi }{4} \right )$$ , $$I=0.707sin(100\pi t)$$. The RMS value of emf will be

0%
$$2\sqrt{2}V$$
0%
$$1 V$$
0%
$$\dfrac{1}{2}V$$
0%
$$\dfrac{1}{2\sqrt{2}}V$$

In an AC circuit containing only capacitance, the current :

0%
leads the voltage by 180
0%
lags the voltage by 90
0%
leads the voltage by 90
0%
remains in phase with the voltage

An inductive coil has a resistance of 100 $$\Omega $$ . When an AC signal of frequency 1000 Hz is applied to the coil, the voltage leads the current by $$45^{o}$$. The inductance of the coil is

0%
$$\dfrac{1}{100\pi }$$H
0%
$$\dfrac{1}{20\pi }$$H
0%
$$\dfrac{1}{40\pi }$$H
0%
$$\dfrac{1}{60\pi }$$H

If the phase difference between Alternating Voltage and Alternating Current is $$\frac{\pi }{6}$$ and the resistance in the circuit is $$\sqrt{300}\Omega $$ , then the impedance of the circuit will be

0%
25$$\Omega $$
0%
50$$\Omega $$
0%
20$$\Omega $$
0%
100$$\Omega $$

The inductance of a resistanceless coil is 0.5 henry. In the coil, the value of alternating current is 0.2 A, whose frequency is 50 Hz. The reactance of circuit is

0%
15.7$$\Omega $$
0%
157$$\Omega $$
0%
1.57$$\Omega $$
0%
757$$\Omega $$

The capacitive reactance at 1600Hz is 81 $$\Omega $$ .When the frequency is doubled then the capacitive reactance will be:

0%
40.5$$\Omega $$
0%
81$$\Omega $$
0%
162$$\Omega $$
0%
zero

In an LCR circuit, current is I $$=$$ 10sin100$$\pi$$ t from an A.C. source. The value of average voltage at the ends of the resistance R $$=$$ 10$$\Omega $$ will be

0%
25V
0%
$$\dfrac{25}{\sqrt{2}}V$$
0%
zero V
0%
1V

In an A.C. circuit the potential difference across an inductance and resistance joined in series are respectively 16V and 20V. The total potential difference across the circuit is

0%
20.0V
0%
25.6V
0%
31.9V
0%
53.5V

A coil is used in a circuit in which an A.C. of frequency 50Hz is flowing. The self-inductance of the coil, in order to produce an impedance of 100 $$\Omega $$ , will be ___ H

0%
$$ \pi$$
0%
$$\frac{1}{\pi }$$
0%
$$ \pi ^{2}$$
0%
$$\frac{1}{\pi^{2} }$$

CBSE Questions for Class 12 Medical Physics Alternating Current Quiz 1 - MCQExams.com

0:0:1

Practice Class 12 Medical Physics Quiz Questions and Answers

CBSE Questions for Class 12 Medical Physics Alternating Current Quiz 1 - MCQExams.com

0:0:1

Practice Class 12 Medical Physics Quiz Questions and Answers

Support mcqexams.com by disabling your adblocker.