Zener diode is useful for voltage regulator.
- 1. Zener Diode PREPARED BY DEBASISH MOHANTA ASSISTANT PROFESSOR DEPARTMENT OF ELECTRICAL ENGINEERING GOVERNMENT COLLEGE OF ENGINEERING, KEONJHAR
- 2. Introduction o When reverse bias voltage on a diode is increased, a critical voltage called breakdown voltage is reached where the reverse current increases sharply. The satisfactory explanation of this breakdown of the junction was first given by American scientist C. Zener. Therefore, the breakdown voltage is sometimes called Zener voltage and the sudden increase in current is known as Zener current. o The breakdown or Zener voltage depends upon the amount of doping. If the diode is heavily doped, the depletion layer will be thin and consequently the breakdown of the junction will occur at low reverse voltage. On the other hand, a lightly doped has a higher breakdown voltage. When an ordinary diode is properly doped so that it has a sharp breakdown voltage, it is called a Zener diode. o A properly doped diode which has a sharp breakdown voltage, is known as a Zener diode.
- 3. Introduction Contd. The following points may be noted about the Zener diode. oA Zener diode is like an ordinary diode except that it is properly doped so as to have a sharp breakdown voltage. oA Zener diode is always reverse connected i.e. it is always reverse biased. oA Zener diode has sharp breakdown voltage, called Zener voltage VZ. oWhen forward biased, its characteristics are just those of ordinary diode. oThe Zener diode is not immediately burn just because it has entered breakdown region. As long as the external circuit connected to the diode limits the diode current less than burn out value, the diode will not burn out.
- 4. Equivalent circuit of Zener diode ON state o When the reverse voltage across a Zener diode is equal to or more than breakdown voltage VZ, the current increases sharply. In this case, the curve is almost vertical. It means the voltage across the Zener diode is constant at VZ even though the current through it changes. Therefore, in the breakdown region, an ideal Zener diode can be represented by a battery of voltage VZ. under such conditions, the Zener diode is said to be in the ON state. Equivalent circuit of Zener for ON state
- 5. Equivalent circuit of Zener diode Contd. OFF state o When the reverse voltage across the Zener diode is less than VZ but greater than 0V, the Zener diode is in the OFF state. Under such conditions, the Zener diode can be represented by an open circuit. Equivalent circuit of Zener for OFF state
- 6. Zener diode as Voltage Stabilizer o A Zener diode can be used as a voltage regulator to provide a constant voltage from a source whose voltage may vary over a sufficient range. The Zener diode of Zener voltage VZ is reverse connected across the load RL across which constant output is obtained. The series resistance R absorbs the output voltage fluctuations so as to maintain constant voltage across the load. It may be noted that the Zener diode will maintain a constant voltage across the load so long as the input voltage does not fall below VZ. o When the circuit is properly designed, the load voltage V0 remain essentially constant equal to VZ even though the input voltage Vi and load resistance RL may vary over a wide range.
- 7. Zener diode as Voltage Stabilizer Contd. o Suppose the input voltage increases. Since the Zener diode is in the breakdown region, the Zener diode is equivalent to a battery VZ. it is clear that output voltage remains constant at VZ. The excess voltage is dropped across the series resistance R. This will cause an increase in value of total current I. the Zener will conduct the increase of current I while the load current remains constant. Hence, the output voltage V0 remains constant irrespective of changes in the input voltage Vi. o Now suppose that input voltage is constant but the load resistance RL decreases. This will cause an increase in load current. The extra current cannot came from the source because drop in R and hence the source current I will not change as the Zener is within its regulating range. The additional load current will come from a decrease in Zener current IZ. consequently the output voltage stays in constant value. Voltage drop across Current through R, Applying ohms law
- 8. Numerical For the circuit shown in figure find i. Output voltage ii.Voltage drop across series resistance iii.Current through Zener diode