Parallel Clippers : Part1
1.1 Basic Parallel Clipper with Positive Clipping
The Fig. 1 shows the basic parallel clipper circuit in which diode D is connected across the load resistance RL. The resistance R1 is current controlling resistance.
Fig. 1 Basic parallel clipper |
Operation
Assumed ideal diode. During positive half cycle of the input Vi, the diode D becomes forward biased and remains forward biased for the entire half cycle of the input.
Note :
As ideal diode acts as a short circuit when forward biased, the current
I flows entirely through diode D. The drop across short circuit diode
is zero.
As is in parallel with diode no current flows through it and output voltage Vo = 0V as shown in the Fig. 2.
Fig. 2 Operating during positive half cycle |
Note : This condition remains for entire positive half cycle of the input. Thus positive half cycle gets clipped off.
During negative half cycle of input, the diode is reverse biased and
acts as open circuit. The entire current flows through RL as shown in the Fig. 3.
Fig. 3 Operation during negative half cycle |
Hence Vo = (Vi RL )/(RL + R1) using potential divider rule. Thus Vo α Vi and there exists straight line relationship between the input and output voltage.
Note : As Vo α Vi during negative half cycle of the input, proportionate negative half cycle is available at the output.
The waveforms are shown in the Fig. 4.
Transfer characteristics :
The mathematical equations for the transfer characteristics are,
The transfer characteristics are shown in the Fig. 5.
Note : Making R1 <<RL, Vo = Vin can be obtained.
Fig. 4 Waveforms for parallel clipper |
Transfer characteristics :
The mathematical equations for the transfer characteristics are,
The transfer characteristics are shown in the Fig. 5.
Fig. 5 Transfer characteristics of positive parallel clipper |
Note : Making R1 <<RL, Vo = Vin can be obtained.
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