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Physics-

General

Easy

Question

In the circuit shown in the figure, the ac source gives a voltage V=20cos(2000t). Neglecting source resistance, the voltmeter and ammeter reading will be

0 V,0.47 A
1.68 V,0.47 A
0 V,1.4 A
5.6 V,1.4 A

The correct answer is: 5.6 V,1.4 A

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The resonance point in $X subscript L end subscript minus f$ and $X subscript C end subscript minus f$ curves is

The resonance point in $X subscript L end subscript minus f$ and $X subscript C end subscript minus f$ curves is

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A constant voltage at different frequencies is applied across a capacitance $C$ as shown in the figure. Which of the following graphs

Correctly depicts the variation of current with frequency ?

A constant voltage at different frequencies is applied across a capacitance $C$ as shown in the figure. Which of the following graphs

Correctly depicts the variation of current with frequency ?

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A box P and a coil Q are connected in series with an ac source of variable frequency. The rms value of emf of source is constant at 10 V. Box P contains a capacitance of $1 mu F$ in series with a resistance of $32 capital omega$ . Coil Q has a self-inductance $4.9 m H$ and a resistance of $68 capital omega$ in series. The frequency is adjusted so that the maximum current flows in P and Q.

voltage across $Q$ is.

A box P and a coil Q are connected in series with an ac source of variable frequency. The rms value of emf of source is constant at 10 V. Box P contains a capacitance of $1 mu F$ in series with a resistance of $32 capital omega$ . Coil Q has a self-inductance $4.9 m H$ and a resistance of $68 capital omega$ in series. The frequency is adjusted so that the maximum current flows in P and Q.

voltage across $Q$ is.

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A box P and a coil Q are connected in series with an ac source of variable frequency. The rms value of emf of source is constant at 10 V. Box P contains a capacitance of $1 mu F$ in series with a resistance of $32 capital omega$ . Coil Q has a self-inductance $4.9 m H$ and a resistance of $68 capital omega$ in series. The frequency is adjusted so that the maximum current flows in P and Q.

Maximum current through circuit is.

A box P and a coil Q are connected in series with an ac source of variable frequency. The rms value of emf of source is constant at 10 V. Box P contains a capacitance of $1 mu F$ in series with a resistance of $32 capital omega$ . Coil Q has a self-inductance $4.9 m H$ and a resistance of $68 capital omega$ in series. The frequency is adjusted so that the maximum current flows in P and Q.

Maximum current through circuit is.

physics-General

A box P and a coil Q are connected in series with an ac source of variable frequency. The rms value of emf of source is constant at 10 V. Box P contains a capacitance of $1 mu F$ in series with a resistance of $32 capital omega$ . Coil Q has a self-inductance $4.9 m H$ and a resistance of $68 capital omega$ in series. The frequency is adjusted so that the maximum current flows in P and Q.

Impedance of p at this frequency is.

A box P and a coil Q are connected in series with an ac source of variable frequency. The rms value of emf of source is constant at 10 V. Box P contains a capacitance of $1 mu F$ in series with a resistance of $32 capital omega$ . Coil Q has a self-inductance $4.9 m H$ and a resistance of $68 capital omega$ in series. The frequency is adjusted so that the maximum current flows in P and Q.

Impedance of p at this frequency is.

physics-General

We know that the amplitude of oscillating system becomes maximum, when the applied frequency is equal to the intrinsic frequency of system. And this concept can be applied even in electrical a.c circuits containing $L comma C$ and $R.$ It is being such that when the frequency of broad casting station becomes equal to frequency of radio circuit, then the impedance (equivalent resistance) of circuit becomes minimum and maximum current flows in the circuit with the result the radio station is tuned its impedance is given by
$Z equals square root of R to the power of 2 end exponent plus open parentheses W L minus fraction numerator 1 over denominator W C end fraction close parentheses to the power of 2 end exponent end root$ and $I subscript 0 end subscript equals fraction numerator V subscript 0 end subscript over denominator Z end fraction$

Now in the given circuit as shown, at a certain moment of the values of voltages and current are given When power loss through resistor is 50 watt, then angular frequency of applied a.c voltage is

We know that the amplitude of oscillating system becomes maximum, when the applied frequency is equal to the intrinsic frequency of system. And this concept can be applied even in electrical a.c circuits containing $L comma C$ and $R.$ It is being such that when the frequency of broad casting station becomes equal to frequency of radio circuit, then the impedance (equivalent resistance) of circuit becomes minimum and maximum current flows in the circuit with the result the radio station is tuned its impedance is given by
$Z equals square root of R to the power of 2 end exponent plus open parentheses W L minus fraction numerator 1 over denominator W C end fraction close parentheses to the power of 2 end exponent end root$ and $I subscript 0 end subscript equals fraction numerator V subscript 0 end subscript over denominator Z end fraction$

Now in the given circuit as shown, at a certain moment of the values of voltages and current are given When power loss through resistor is 50 watt, then angular frequency of applied a.c voltage is

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We know that the amplitude of oscillating system becomes maximum, when the applied frequency is equal to the intrinsic frequency of system. And this concept can be applied even in electrical a.c circuits containing $L comma C$ and $R.$ It is being such that when the frequency of broad casting station becomes equal to frequency of radio circuit, then the impedance (equivalent resistance) of circuit becomes minimum and maximum current flows in the circuit with the result the radio station is tuned its impedance is given by
$Z equals square root of R to the power of 2 end exponent plus open parentheses W L minus fraction numerator 1 over denominator W C end fraction close parentheses to the power of 2 end exponent end root$ and $I subscript 0 end subscript equals fraction numerator V subscript 0 end subscript over denominator Z end fraction$

Now in the given circuit as shown, at a certain moment of the values of voltages and current are given The current in the circuit is

We know that the amplitude of oscillating system becomes maximum, when the applied frequency is equal to the intrinsic frequency of system. And this concept can be applied even in electrical a.c circuits containing $L comma C$ and $R.$ It is being such that when the frequency of broad casting station becomes equal to frequency of radio circuit, then the impedance (equivalent resistance) of circuit becomes minimum and maximum current flows in the circuit with the result the radio station is tuned its impedance is given by
$Z equals square root of R to the power of 2 end exponent plus open parentheses W L minus fraction numerator 1 over denominator W C end fraction close parentheses to the power of 2 end exponent end root$ and $I subscript 0 end subscript equals fraction numerator V subscript 0 end subscript over denominator Z end fraction$

Now in the given circuit as shown, at a certain moment of the values of voltages and current are given The current in the circuit is

physics-General

We know that the amplitude of oscillating system becomes maximum, when the applied frequency is equal to the intrinsic frequency of system. And this concept can be applied even in electrical a.c circuits containing L,C and R. It is being such that when the frequency of broad casting station becomes equal to frequency of radio circuit, then the impedance (equivalent resistance) of circuit becomes minimum and maximum current flows in the circuit with the result the radio station is tuned its impedance is given by
$Z equals square root of R to the power of 2 end exponent plus open parentheses W L minus fraction numerator 1 over denominator W C end fraction close parentheses to the power of 2 end exponent end root$ and $I subscript 0 end subscript equals fraction numerator V subscript 0 end subscript over denominator Z end fraction$

Now in the given circuit as shown, at a certain moment of the values of voltages and current are given The value of applied peak voltage is

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$Z equals square root of R to the power of 2 end exponent plus open parentheses W L minus fraction numerator 1 over denominator W C end fraction close parentheses to the power of 2 end exponent end root$ and $I subscript 0 end subscript equals fraction numerator V subscript 0 end subscript over denominator Z end fraction$

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