The circuit is equivalent to: 

        

1.  AND gate

2.  NAND gate

3.  NOR gate

4.  OR gate

In the following circuit, the output Y for all possible inputs A and B is expressed by the truth table: 

1. A     B     Y
    0     0     0
    0     1     0
    1     0     0
    1     1     1

2.  A     B     Y
     0     0     1
     0     1     1
     1     0     1
     1     1     0

3.  A     B     Y
     0     0     1
     0     1     0
     1     0     0
     1     1     1

4.  A     B     Y
     0     0     0
     0     1     1
     1     0     1
     1     1     1

In the energy band diagram of a material shown below, the open circles and filled circles denote holes and electrons respectively. The material is a/an: 
      

A transistor-oscillator using a resonant circuit with an inductance \(L\) (of negligible resistance) and a capacitance \(C\) has a frequency \(f\). If \(L\) is doubled and \(C\) is changed to \(4C\), the frequency will be:
1. \(\frac{f}{4}\)
2. \(8f\)
3. \(\frac{f}{2\sqrt{2}}\)
4. \(\frac{f}{2}\)

A transistor is operated in common emitter configuration at constant collector voltage V_c = 1.5 V such that a change in the base current from 100 μA to 150 μA produces a change in the collector current from 5 mA to 10 mA. The current gain (β) is:

1. 67

2. 75

3. 100

4. 50

The photoelectric effect is used by a photocell to convert:

The following figure shows a logic gate circuit with two inputs A and B and the output C. The voltage waveforms of A, B, and C as shown below:

 
 
The logic circuit gate is :

1. AND gate

2. NAND gate

3. NOR gate

4. OR gate

For a p-type semiconductor, which of the following statements is true?

1. Electrons are the majority carriers and pentavalent atoms are the dopants.

2. Electrons are the majority carriers and trivalent atoms are the dopants.

3. Holes are the majority carriers and trivalent atoms are the dopants.

4. Holes are the majority carriers and pentavalent atoms are the dopants.

The ideal diodes ${\mathrm{D}}_1 \mathrm{and} {\mathrm{D}}_2$ are connected in the two branches as shown in the figure.$\left[{\mathrm{R}}_1 = 4\mathrm{\Omega }, {\mathrm{R}}_2 = 5\mathrm{\Omega }, {\mathrm{R}}_3 = 6\mathrm{\Omega }\right]$. Current through the battery is:

1.  2A

2.  1A

3.  3A

4.  4A

Zener diodes with breakdown voltage ranging over 2 V — 200 V are commercially available. The breakdown voltage of a Zener diode:

1. Increases with increasing doping concentration

2. Decreases with increasing doping concentration

3. Does not depend on doping concentration

4. May increase or decrease with increasing doping concentration