Two conducting circular loops of radii \(R_1\) and \(R_2\) are placed in the same plane with their centres coinciding. If \(R_1>>R_2\), the mutual inductance \(M\) between them will be directly proportional to:
1. | \(\dfrac{R_1}{R_2}\) | 2. | \(\dfrac{R_2}{R_1}\) |
3. | \(\dfrac{R^2_1}{R_2}\) | 4. | \(\dfrac{R^2_2}{R_1}\) |
A thin semicircular conducting ring of radius \(R\) is falling with its plane vertical in a horizontal magnetic induction \(B\). At the position \(MNQ\), the speed of the ring is \(v\) and the potential difference developed across the ring is:
1. | Zero |
2. | \(B v \pi R^2 / 2\) and \(M\) is at the higher potential |
3. | \(2 R B v\) and \(M\) is at the higher potential |
4. | \(2RBv\) and \(Q\) is at the higher potential |
Consider the situation shown in the figure. The wire AB is sliding on the fixed rails with a constant velocity. If the wire AB is replaced by semicircular wire, the magnitude of the induced current will
1. Increase
2. Remain the same
3. Decrease
4. Increase or decrease depending on whether the semicircle bulges towards the resistance or away from it
A circular loop of radius R carrying current I lies in the x-y plane with its centre at the origin. The total magnetic flux through the x-y plane is
1. Directly proportional to I
2. Directly proportional to R
3. Directly proportional to R2
4. Zero
A small square loop of wire of side l is placed inside a large square loop of wire of side L (L > l). The loop are coplanar and their centre coincide. The mutual inductance of the system is proportional to
1. l / L
2. l2 / L
3. L/l
4. L2/l
A uniform but time-varying magnetic field B(t) exists in a circular region of radius a and is directed into the plane of the paper, as shown. The magnitude of the induced electric field at point P at a distance r from the centre of the circular region
1. Is zero
2. Decreases as
3. Increases as r
4. Decreases as
A coil of wire having finite inductance and resistance has a conducting ring placed coaxially within it. The coil is connected to a battery at time t = 0 so that a time-dependent current I1(t) starts flowing through the coil. If I2(t) is the current induced in the ring and B(t) is the magnetic field at the axis of the coil due to I1(t), then as a function of time (t > 0), the product I2 (t) B(t)
1. Increases with time
2. Decreases with time
3. Does not vary with time
4. Passes through a maximum
Two circular coils can be arranged in any of the three situations shown in the figure. Their mutual inductance will be
1. Maximum in situation (A)
2. Maximum in situation (B)
3. Maximum in situation (C)
4. The same in all situations
As shown in the figure, P and Q are two coaxial conducting loops separated by some distance. When the switch S is closed, a clockwise current IP flows in P (as seen by E) and an induced current flows in Q. The switch remains closed for a long time. When S is opened, a current flows in Q. Then the directions of and (as seen by E) are
1. Respectively clockwise and anticlockwise
2. Both clockwise
3. Both anticlockwise
4. Respectively anticlockwise and clockwise
A conducting wireframe is placed in a magnetic field that is directed into the paper. The magnetic field is increasing at a constant rate. The directions of induced current in wires \(AB\) and \(CD\) are:
1. | \(B\) to \(A\) and \(D\) to \(C\) |
2. | \(A\) to \(B\) and \(C\) to \(D\) |
3. | \(A\) to \(B\) and \(D\) to \(C\) |
4. | \(B\) to \(A\) and \(C\) to \(D\) |