154799 A rectangular wire loop with length a and width $b$ lies in the xy-plane as shown. Within the loop, there is a time dependent magnetic field given by $\mathbf{B}=c[(x \cos \omega t) \hat{i}+(y \sin \omega t) \hat{k}]$
Here, $c$ and $\omega$ are constants. The magnitude of emf induced in the loop as a function of time is

154800 Two circular loops $L_{1}$ and $L_{2}$ of wire carrying equal and opposite currents are placed parallel to each other with a common axis. The radius of loop $L_{1}$ is $R_{1}$ and that of $L_{2}$ is $R_{2}$. The distance between the centres of the loops is $\sqrt{3} R_{1}$. The magnetic field at the centre of $L_{2}$ shall be zero, if

154801 A solenoid of radius $R$ has $n$ turns per unit length, then the self-inductance of the solenoid per unit length is

154802 At $600 \mathrm{~Hz}$, an inductor and capacitor have equal reactances, the ratio of the capacitive reactance to the inductive reactance at $60 \mathrm{~Hz}$ will be

154803 A current of $4 \mathrm{~A}$ flows in a coil when connected to a $12 \mathrm{~V}$ d.c. source. If the same coil is connected to a $12 \mathrm{~V},\left(\frac{25}{\pi}\right) \mathrm{Hz}$ a.c source, a current of $2.4 \mathrm{~A}$ flows in the circuit. The inductance of the coil is

154799 A rectangular wire loop with length a and width $b$ lies in the xy-plane as shown. Within the loop, there is a time dependent magnetic field given by $\mathbf{B}=c[(x \cos \omega t) \hat{i}+(y \sin \omega t) \hat{k}]$
Here, $c$ and $\omega$ are constants. The magnitude of emf induced in the loop as a function of time is

154800 Two circular loops $L_{1}$ and $L_{2}$ of wire carrying equal and opposite currents are placed parallel to each other with a common axis. The radius of loop $L_{1}$ is $R_{1}$ and that of $L_{2}$ is $R_{2}$. The distance between the centres of the loops is $\sqrt{3} R_{1}$. The magnetic field at the centre of $L_{2}$ shall be zero, if

154801 A solenoid of radius $R$ has $n$ turns per unit length, then the self-inductance of the solenoid per unit length is

154802 At $600 \mathrm{~Hz}$, an inductor and capacitor have equal reactances, the ratio of the capacitive reactance to the inductive reactance at $60 \mathrm{~Hz}$ will be

154803 A current of $4 \mathrm{~A}$ flows in a coil when connected to a $12 \mathrm{~V}$ d.c. source. If the same coil is connected to a $12 \mathrm{~V},\left(\frac{25}{\pi}\right) \mathrm{Hz}$ a.c source, a current of $2.4 \mathrm{~A}$ flows in the circuit. The inductance of the coil is

154799 A rectangular wire loop with length a and width $b$ lies in the xy-plane as shown. Within the loop, there is a time dependent magnetic field given by $\mathbf{B}=c[(x \cos \omega t) \hat{i}+(y \sin \omega t) \hat{k}]$
Here, $c$ and $\omega$ are constants. The magnitude of emf induced in the loop as a function of time is

154800 Two circular loops $L_{1}$ and $L_{2}$ of wire carrying equal and opposite currents are placed parallel to each other with a common axis. The radius of loop $L_{1}$ is $R_{1}$ and that of $L_{2}$ is $R_{2}$. The distance between the centres of the loops is $\sqrt{3} R_{1}$. The magnetic field at the centre of $L_{2}$ shall be zero, if

154801 A solenoid of radius $R$ has $n$ turns per unit length, then the self-inductance of the solenoid per unit length is

154802 At $600 \mathrm{~Hz}$, an inductor and capacitor have equal reactances, the ratio of the capacitive reactance to the inductive reactance at $60 \mathrm{~Hz}$ will be

154803 A current of $4 \mathrm{~A}$ flows in a coil when connected to a $12 \mathrm{~V}$ d.c. source. If the same coil is connected to a $12 \mathrm{~V},\left(\frac{25}{\pi}\right) \mathrm{Hz}$ a.c source, a current of $2.4 \mathrm{~A}$ flows in the circuit. The inductance of the coil is

154799 A rectangular wire loop with length a and width $b$ lies in the xy-plane as shown. Within the loop, there is a time dependent magnetic field given by $\mathbf{B}=c[(x \cos \omega t) \hat{i}+(y \sin \omega t) \hat{k}]$
Here, $c$ and $\omega$ are constants. The magnitude of emf induced in the loop as a function of time is

154800 Two circular loops $L_{1}$ and $L_{2}$ of wire carrying equal and opposite currents are placed parallel to each other with a common axis. The radius of loop $L_{1}$ is $R_{1}$ and that of $L_{2}$ is $R_{2}$. The distance between the centres of the loops is $\sqrt{3} R_{1}$. The magnetic field at the centre of $L_{2}$ shall be zero, if

154801 A solenoid of radius $R$ has $n$ turns per unit length, then the self-inductance of the solenoid per unit length is

154802 At $600 \mathrm{~Hz}$, an inductor and capacitor have equal reactances, the ratio of the capacitive reactance to the inductive reactance at $60 \mathrm{~Hz}$ will be

154803 A current of $4 \mathrm{~A}$ flows in a coil when connected to a $12 \mathrm{~V}$ d.c. source. If the same coil is connected to a $12 \mathrm{~V},\left(\frac{25}{\pi}\right) \mathrm{Hz}$ a.c source, a current of $2.4 \mathrm{~A}$ flows in the circuit. The inductance of the coil is

154799 A rectangular wire loop with length a and width $b$ lies in the xy-plane as shown. Within the loop, there is a time dependent magnetic field given by $\mathbf{B}=c[(x \cos \omega t) \hat{i}+(y \sin \omega t) \hat{k}]$
Here, $c$ and $\omega$ are constants. The magnitude of emf induced in the loop as a function of time is

154800 Two circular loops $L_{1}$ and $L_{2}$ of wire carrying equal and opposite currents are placed parallel to each other with a common axis. The radius of loop $L_{1}$ is $R_{1}$ and that of $L_{2}$ is $R_{2}$. The distance between the centres of the loops is $\sqrt{3} R_{1}$. The magnetic field at the centre of $L_{2}$ shall be zero, if

154801 A solenoid of radius $R$ has $n$ turns per unit length, then the self-inductance of the solenoid per unit length is

154802 At $600 \mathrm{~Hz}$, an inductor and capacitor have equal reactances, the ratio of the capacitive reactance to the inductive reactance at $60 \mathrm{~Hz}$ will be

154803 A current of $4 \mathrm{~A}$ flows in a coil when connected to a $12 \mathrm{~V}$ d.c. source. If the same coil is connected to a $12 \mathrm{~V},\left(\frac{25}{\pi}\right) \mathrm{Hz}$ a.c source, a current of $2.4 \mathrm{~A}$ flows in the circuit. The inductance of the coil is