274656 When you walk through a metal detector carrying a metal object in your pocket, it raises an alarm. This phenomenon works on

274653 Which one of the following curves represents the variation of impedance $\left( Z \right)$ with frequency $f$ in
series LCR circuit?

1

2

3

4

274663 In the given circuit, the current drawn from the source is

274657 The impedance in a circuit containing a resistance of $1\text{ }\!\!\Omega\!\!\text{ }$ and an inductance of $0.1\text{H}$ in series, for $\text{AC}$ of $50\text{Hz}$, is

274640 A sinusoidal voltage $V\left( t \right)=210\text{sin}3000t$ volt is applied to a series LCR circuit in which $L=10\text{mH},C=25\mu \text{F}$ and $R=100\text{ }\!\!\Omega\!\!\text{ }$. The phase difference $\left( \text{ }\!\!\Phi\!\!\text{ } \right)$ between the applied voltage and resultant current will be :

274656 When you walk through a metal detector carrying a metal object in your pocket, it raises an alarm. This phenomenon works on

274653 Which one of the following curves represents the variation of impedance $\left( Z \right)$ with frequency $f$ in
series LCR circuit?

1

2

3

4

274663 In the given circuit, the current drawn from the source is

274657 The impedance in a circuit containing a resistance of $1\text{ }\!\!\Omega\!\!\text{ }$ and an inductance of $0.1\text{H}$ in series, for $\text{AC}$ of $50\text{Hz}$, is

274640 A sinusoidal voltage $V\left( t \right)=210\text{sin}3000t$ volt is applied to a series LCR circuit in which $L=10\text{mH},C=25\mu \text{F}$ and $R=100\text{ }\!\!\Omega\!\!\text{ }$. The phase difference $\left( \text{ }\!\!\Phi\!\!\text{ } \right)$ between the applied voltage and resultant current will be :

274656 When you walk through a metal detector carrying a metal object in your pocket, it raises an alarm. This phenomenon works on

274653 Which one of the following curves represents the variation of impedance $\left( Z \right)$ with frequency $f$ in
series LCR circuit?

1

2

3

4

274663 In the given circuit, the current drawn from the source is

274657 The impedance in a circuit containing a resistance of $1\text{ }\!\!\Omega\!\!\text{ }$ and an inductance of $0.1\text{H}$ in series, for $\text{AC}$ of $50\text{Hz}$, is

274640 A sinusoidal voltage $V\left( t \right)=210\text{sin}3000t$ volt is applied to a series LCR circuit in which $L=10\text{mH},C=25\mu \text{F}$ and $R=100\text{ }\!\!\Omega\!\!\text{ }$. The phase difference $\left( \text{ }\!\!\Phi\!\!\text{ } \right)$ between the applied voltage and resultant current will be :

274656 When you walk through a metal detector carrying a metal object in your pocket, it raises an alarm. This phenomenon works on

274653 Which one of the following curves represents the variation of impedance $\left( Z \right)$ with frequency $f$ in
series LCR circuit?

1

2

3

4

274663 In the given circuit, the current drawn from the source is

274657 The impedance in a circuit containing a resistance of $1\text{ }\!\!\Omega\!\!\text{ }$ and an inductance of $0.1\text{H}$ in series, for $\text{AC}$ of $50\text{Hz}$, is

274640 A sinusoidal voltage $V\left( t \right)=210\text{sin}3000t$ volt is applied to a series LCR circuit in which $L=10\text{mH},C=25\mu \text{F}$ and $R=100\text{ }\!\!\Omega\!\!\text{ }$. The phase difference $\left( \text{ }\!\!\Phi\!\!\text{ } \right)$ between the applied voltage and resultant current will be :

274656 When you walk through a metal detector carrying a metal object in your pocket, it raises an alarm. This phenomenon works on

274653 Which one of the following curves represents the variation of impedance $\left( Z \right)$ with frequency $f$ in
series LCR circuit?

1

2

3

4

274663 In the given circuit, the current drawn from the source is

274657 The impedance in a circuit containing a resistance of $1\text{ }\!\!\Omega\!\!\text{ }$ and an inductance of $0.1\text{H}$ in series, for $\text{AC}$ of $50\text{Hz}$, is

274640 A sinusoidal voltage $V\left( t \right)=210\text{sin}3000t$ volt is applied to a series LCR circuit in which $L=10\text{mH},C=25\mu \text{F}$ and $R=100\text{ }\!\!\Omega\!\!\text{ }$. The phase difference $\left( \text{ }\!\!\Phi\!\!\text{ } \right)$ between the applied voltage and resultant current will be :