A galvanometer of \(50~\Omega \) resistance has 25 divisions. A current of 4 × 10–4 A gives a deflection of one division. To convert this galvanometer into a voltmeter having a range of 25 V, it should be connected with a resistance of:
1. 2500 Ω as a shunt
2. 2450 Ω as a shunt
3. 2550 Ω in series
4. 2450 Ω in series
The electric charge in uniform motion produces :
(1) An electric field only
(2) A magnetic field only
(3) Both electric and magnetic field
(4) Neither electric nor magnetic field
An infinitely long straight conductor is bent into the shape as shown in the figure.
It carries a current of \(i\) amperes and the radius of the circular loop is \(r\) metres. What will be the magnetic induction at its centre?
1. \(\frac{\mu_{0}}{4 \pi} \frac{2 i}{r} \left( \pi + 1 \right)\)
2. \(\frac{\mu_{0}}{4 \pi} \frac{2 i}{r} \left(\pi - 1 \right)\)
3. zero
4. Infinite
A current \(i\) ampere flows in a circular arc of wire whose radius is \(R,\) which subtend an angle radian at its centre. The magnetic induction \(B\) at the centre is:
1. \(\frac{\mu_0i}{R}\)
2. \(\frac{\mu_0i}{2R}\)
3. \(\frac{2\mu_0i}{R}\)
4. \(\frac{3\mu_0i}{8R}\)
A straight section PQ of a circuit lies along the X-axis from x= to x= and carries a steady current i. The magnetic field due to the section PQ at a point X = + a will be:
1. Proportional to a 2. Proportional to
3. Proportional to 4. Zero
1. | \(3.33\times 10^{-9}\) Tesla |
2. | \(1.11\times 10^{-4}\) Tesla |
3. | \(3\times 10^{-3}\) Tesla |
4. | \(9\times 10^{-2}\) Tesla |
1. | At a distance \(\frac{d}{2}\) from any of the wires in any plane. |
2. | At a distance \(\frac{d}{3}\) from any of the wires in the horizontal plane. |
3. | Anywhere on the circumference of a vertical circle of radius \(d\) and centre halfway between the wires. |
4. | At points halfway between the wires in the horizontal plane. |
A circular coil of radius R carries an electric current. The magnetic field due to the coil at a point on the axis of the coil located at a distance r from the centre of the coil, such that r >> R, varies as
1.
2.
3.
4.
The magnetic induction due to an infinitely long straight wire carrying a current \(i\) at a distance \(r\) from the wire is given by:
1. \( B =\dfrac{\mu_0}{4 \pi} \dfrac{2 i}{r} \)
2. \(B =\dfrac{\mu_0}{4 \pi} \dfrac{r}{2 i} \)
3. \(B =\dfrac{4 \pi}{\mu_0} \dfrac{2 i}{r} \)
4. \(B =\dfrac{4 \pi}{\mu_0} \dfrac{r}{2 i}\)
The magnetic induction at the centre O in the figure shown is:
1. 2.
3. 4.