applications of diode - clipper and clamper circuits.pdf
- 1. Ch. 4 Common Diode Applications 4.1 Clippers 4.2 Clampers
- 2. 4.1 Clippers Clipper (or Limiter) : A diode circuit used to eliminate some portion of a waveform
- 3. 4.1.1 Series clippers The series clipper has the same circuit operating characteristics as the half-wave rectifier, which provides an output when the diode is forward biased and no output when the diode is reverse biased 1. Negative series clipper for +Vin VL = Vin – 0.7 V 2. Negative series clipper for –Vin VL = 0 V 3. Positive series clipper for +Vin VL = 0 V 4. Negative series clipper for –Vin VL = -Vin + 0.7 V
- 4. 4.1.2 Shunt clippers The shunt clipper provides an output when the diode is reverse biased and no output when the diode is forward biased
- 5. EXAMPLE 4.1 Q. The negative shunt clipper shown in Figure 4.4 has a peak input voltage of +12V. What is the peak load voltage for the circuit? when the input is positive the diode is reverse biased and does not conduct. Therefore, the peak load voltage is found as
- 6. EXAMPLE 4.2 Q. The circuit described in Example 4.1 has a -12Vpk input. Determine the values of VL and VRS for the circuit. The load voltage: The voltage across the series resistor (Rs):
- 7. EXAMPLE 4.3 Q. The positive shunt clipper shown in the figure has the input waveform shown. Determine the value for VL for each of the input alternations When the input is positive, When the input is negative,
- 8. 4.1.3 The role of RS Without RS in the circuit, • The diode is destroyed by excessive forward current. • One or more components in the signal source can be damaged by the excessive current demand of the conducting diode. Rs is included in the shunt clipper as a current-limiting resistor.
- 9. EXAMPLE 4.4 Q. Determine the peak load voltage for the circuit shown in the figure. Assume that the diode is reverse biased. The peak load voltage is given by if L in S L V V R R
- 10. 4.1.4 Biased Clippers • A biased clipper uses a dc biasing source to set the limit on the output voltage. • The additional bias voltage allows the circuit to clip the input waveforms at certain values other than VF of 0.7 V +VB (V) -VB (V) Positive-biased clipper clips its input signal at VB + 0.7 V. Negative-biased clipper clips its input signal at –VB – 0.7 V.
- 11. 4.1.4 Biased Clippers In practice, a potentiometer (R1) is used to provide an adjustable value of VB. VB,R1 (V) VB,R1 + 0.7 (V)
- 12. Clipper summary
- 13. 4.3 Clampers (DC Restorers, Shifters) A clamper is a circuit designed to shift a waveform either above or below a given reference voltage without distorting the waveform Positive clamper A circuit that shifts an entire input signal above a dc reference voltage. Negative clamper A circuit that shifts an entire input signal below a dc reference voltage.
- 14. 4.3.2 Clamper Operation • The clamper is similar to a shunt clipper connected with a capacitor in series. • Like the capacitive power supply filter, the clamper works on the basis of switching time constants (시상수). <<
- 15. EXAMPLE 4.5 Determine the capacitor charge and discharge times for the circuit represented in the figure. Assume that the forward resistance of the diode is 10 Ω, RL = 10 kΩ, and C1 =1 μF.
- 16. 4.3.2 Clamper Operation (1) When the input goes to its positive peak (+5V), D1 is forward biased. There forms a low-resistance current path for charging C1. Then C1 is rapidly charged to the full value (5V). With the applied voltage dropped across C1, the load voltage has a positive peak value of 0 V.
- 17. 4.3.2 Clamper Operation (2) When the input goes to its negative peak (+5V), D1 is reverse biased. There forms a high-resistance current path for discharging C1. Then C1 is very slowly discharged. Since the input voltage and VC have the same polarity, the load voltage has a peak value of -10 V. Here capacitor plays a role of dc battery for the time being of t = CRL
- 18. 4.3.2 Clamper Operation (3) Using the practical diode model with VF = +0.7 V,
- 19. 4.3.3 Negative Clampers vs Positive Clampers The direction of the diode is opposite with each other. + +
- 20. 4.3.4 Biased Clampers + Vin + 0.7 V + 0.7 V – VB,R1 – Vin – 0.7 V – 0.7 V + VB,R1 A biased clamper allows a waveform to be shifted above (or below) a dc reference other than 0 V. By varying the potentiometer setting of R1, the circuit reference voltage can be varied between approximately 0 V and the value of VB.
- 21. 4.3.4 Biased Clampers + Vin + 0.7 V + 0.7 V + VZ – Vin – 0.7 V – 0.7 V – VZ The zener clamper uses a zener diode to set the circuit dc reference voltage. For example, the dc reference voltage for each zener clamper in Figure 4.4 has a value of VZ ± 0.7 V.