Zener diode is used for:
1. rectification.
2. stabilisation.
3. amplification.
4. producing oscillations in an oscillator.
\(A\) | \(B\) | \(Y\) |
\(1\) | \(1\) | \(1\) |
\(1\) | \(0\) | \(0\) |
\(0\) | \(1\) | \(0\) |
\(0\) | \(0\) | \(0\) |
1. | The resistivity of a semiconductor increases with an increase in temperature. |
2. | Substances with an energy gap of the order of \(10\) eV are insulators. |
3. | In conductors, the valence and conduction bands may overlap. |
4. | The conductivity of a semiconductor increases with an increase in temperature. |
1. | widens the depletion zone. |
2. | increases the number of donors on the n side. |
3. | increases the potential difference across the depletion zone. |
4. | increases the electric field in the depletion zone. |
If a common emitter circuit is used as an amplifier, its current gain is \(50.\) If input resistance is \(1\) kΩ and input voltage is \(5\) V, then output current will be:
1. \(250\) mA
2. \(30\) mA
3. \(50\) mA
4. \(100\) mA
Of the diodes shown in the following diagrams, which one of the diodes is reverse biased?
1. | 2. | ||
3. | 4. |
The truth table for the following network is:
1. |
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2. |
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3. |
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4. | None of the above |
In semiconductors at room temperature:
1. | The valence band is completely filled and the conduction band is partially filled. |
2. | The valence band is completely filled. |
3. | The conduction band is completely empty. |
4. | The valence band is partially empty and the conduction band is partially filled. |
In a p–n junction photocell, the value of the photo electromotive force produced by monochromatic light is proportional to:
1. | the intensity of the light falling on the cell. |
2. | the frequency of the light falling on the cell. |
3. | the voltage applied at the p–n junction. |
4. | the barrier voltage at the p–n junction. |
For the given circuit of the \(\mathrm{p\text-n}\) junction diode, which of the following statements is correct?
1. | In F.B. the voltage across \(R\) is \(V\). |
2. | In R.B. the voltage across \(R\) is \(V\). |
3. | In F.B. the voltage across \(R\) is \(2V\). |
4. | In R.B. the voltage across \(R\) is \(2V\). |