A superconducting ring of radius $a$ and inductance $L$ is in a uniform magnetic field $B_0$ and current in the ring is equal to zero. The ring is turned to the position perpendicular to vector $B_0.$ At final situation

A rectangular frame $ABCD$ made of a uniform metal wire has a straight connection between $E$ and $F$ made of same wire as shown in figure. The entire circuit is placed in a steady increasing field directed into the plane of paper. The rate of change of field is $1 T{S}^{-1}.$ The resistance per unit length of wire is $1 {\mathrm{\Omega m}}^{-1}.$ If current in $AD, EF$ and $BC$ be $I_1, I_2$ and $I_3$ respectively, then (given $AEFD$ is a square wires frame of side length $1 \mathrm{m}$ and $BE=FC=0.5 \mathrm{m}$)

A small magnet $\left(x\right)$ of mass $m$ is allowed to fall through a fixed horizontal conducting ring $\left(R\right)$ of mass $m$ placed on horizontal ground. Let $g$ be the acceleration due to gravity. If the acceleration of $x$ is $a$, then

A conductor $PQR$ of length $0.6$ metre and with a resistance $r=1 \mathrm{\Omega }$ moves on two parallel conducting rails $CD$ and $AB$ with a uniform speed $V=4 \mathrm{m} {\mathrm{s}}^{–1}$ normal to a uniform magnetic field of induction $B=5 \mathrm{T}.$ The rails are connected by two resistance as shown in figure. If mechanical power needed for the motion is $3x$ watt, then find out the value of $x.$

Figure shows three conducting rails connected with resistances $R, R$ and $2R.$ (here $R=5 \mathrm{\Omega }$). A wire in form of $\sin$ curve $x=2 \sin \pi y$ is being moved with constant velocity $V=6 \mathrm{m} {\mathrm{s}}^{–1}$ towards $x$-axis. A uniform magnetic field $B=5.0 \mathrm{T}$ is applied perpendicular to the plane of rails and wire. Find out the current(in $\mathrm{A}$) induced in $2R$ resistance. (Here $x \& y$ both are in metres).

A long circular tube of length $10 \mathrm{m}$ and radius $0.3 \mathrm{m}$ carries a current $I$ along its curved surface as shown. A wire-loop of resistance $0.005 \mathrm{ohm}$ and of radius $0.1 \mathrm{m}$ is placed inside the tube with its axis coinciding with the axis of the tube. The current varies as $I=I_0\cos (300 t)$ where $I_0$ is constant. If the magnetic moment of the loop is $N{\mu }_0{I}_0\sin (300 t)$, then $\text{'}N\text{'}$ is

A conducting rod of length $5 \mathrm{m}$ slides in a vertical plane against two insulated perpendicular surfaces as shown. Outward uniform magnetic field $B_0=3$ Tesla exists in the region. If end $A$ of the rod is being pulled with constant speed $V_0=2 \mathrm{m} {\mathrm{s}}^{–1} \hat{i}$, then find the magnitude of induced Emf (in volt) across end $A$ and $B$ of the rod at the instant when the rod makes an angle of $\theta =37°$ with horizontal.

In the system shown, distance between two parallel rails are $10 \mathrm{cm}.$ Two metallic rods having resistance of $10 \mathrm{\Omega }$ and $15 \mathrm{\Omega }$ are pulled with constant speed $4 \mathrm{m} {\mathrm{s}}^{–1}$ and $2 \mathrm{m} {\mathrm{s}}^{–1}$ respectively. A uniform magnetic field of magnitude $0.01 \mathrm{T}$ is applied perpendicular to the plane of the rails. The current in the $5 \mathrm{\Omega }$ resistor is $\frac{k}{55} \mathrm{mA}.$ Value of $k$, is