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Voltage Multiplier

Voltage multiplier definition

The voltage multiplier is an electronic circuit that delivers the output voltage whose amplitude (peak value) is two, three, or more times greater than the amplitude (peak value) of the input voltage.

Voltage multiplier is an electronic circuit that delivers the output voltage whose amplitude (peak value) is two, three, or more times greater than the amplitude (peak value) of the input voltage.

The voltage multiplier is an electronic circuit that converts the low AC voltage into high DC voltage.

The voltage multiplier is an AC-to-DC converter, made up of diodes and capacitors that produce a high voltage DC output from a low voltage AC input.

What is voltage multiplier?

Voltage multiplier power supplies have been used for many years. Walton and Cockroft built an 800 kV supply for an ion accelerator in 1932. Since that time the voltage multiplier has been used primarily when high voltages and low currents are required. The use of voltage multiplier circuits reduces the size of the high voltage transformer and, in some cases, makes it possible to eliminate the transformer.

The recent technological developments have made it possible to design a voltage multiplier that efficiently converts the low AC voltage into high DC voltage comparable to that of the more conventional transformer-rectifier-filter-circuit.

The voltage multiplier is made up of capacitors and diodes that are connected in different configurations. Voltage multiplier has different stages. Each stage is made up of one diode and one capacitor. These arrangements of diodes and capacitors make it possible to produce rectified and filtered output voltage whose amplitude (peak value) is larger than the input AC voltage.

Types of voltage multipliers

Voltage multipliers are classified into four types:

Half-wave voltage doubler
Full-wave voltage doubler
Voltage tripler
Voltage quadrupler

Half-wave voltage doubler

As its name suggests, a half-wave voltage doubler is a voltage multiplier circuit whose output voltage amplitude is twice that of the input voltage amplitude. A half-wave voltage doubler drives the voltage to the output during either positive or negative half cycle. The half-wave voltage doubler circuit consists of two diodes, two capacitors, and AC input voltage source.

During positive half cycle:

The circuit diagram of the half-wave voltage doubler is shown in the below figure. During the positive half cycle, diode D₁ is forward biased. So it allows electric current through it. This current will flows to the capacitor C₁ and charges it to the peak value of input voltage I.e. V_m.

However, current does not flow to the capacitor C₂ because the diode D₂is reverse biased. So the diode D₂ blocks the electric current flowing towards the capacitor C₂. Therefore, during the positive half cycle, capacitor C₁ is charged whereas capacitor C₂ is uncharged.

As its name suggests, a half-wave voltage doubler is a voltage multiplier circuit whose output voltage amplitude is twice that of the input voltage amplitude.

During negative half cycle:

During the negative half cycle, diode D₁ is reverse biased. So the diode D₁ will not allow electric current through it. Therefore, during the negative half cycle, the capacitor C₁ will not be charged. However, the charge (V_m) stored in the capacitor C₁ is discharged (released).

On the other hand, the diode D₂ is forward biased during the negative half cycle. So the diode D₂ allows electric current through it. This current will flows to the capacitor C₂ and charges it. The capacitor C₂ charges to a value 2V_m because the input voltage V_m and capacitor C₁ voltage V_m is added to the capacitor C₂. Hence, during the negative half cycle, the capacitor C₂ is charged by both input supply voltage V_m and capacitor C₁ voltage V_m. Therefore, the capacitor C₂ is charged to 2V_m.

If a load is connected to the circuit at the output side, the charge (2V_m) stored in the capacitor C₂ is discharged and flows to the output.

During the next positive half cycle, diode D₁ is forward biased and diode D₂ is reverse biased. So the capacitor C₁ charges to V_m whereas capacitor C₂ will not be charged. However, the charge (2V_m) stored in the capacitor C₂ will be discharged and flows to the output load. Thus, the half-wave voltage doubler drives a voltage of 2V_mto the output load.

The capacitor C₂ gets charged again in the next half cycle.

The voltage (2V_m) obtained at the output side is twice that of the input voltage (V_m).

The capacitors C₁ and C₂ in half wave-voltage doubler charges in alternate half cycles.

The output waveform of the half-wave voltage doubler is almost similar to the half wave rectifier with filter. The only difference is the output voltage amplitude of the half-wave voltage doubler is twice that of the input voltage amplitude but in half wave rectifier with filter, the output voltage amplitude is same as the input voltage amplitude.

The half-wave voltage doubler supplies the voltage to the output load in one cycle (either positive or negative half cycle). In our case, the half-wave voltage doubler supplies the voltage to the output load during positive half cycles. Therefore, the output signal regulation of the half-wave voltage doubler is poor.

Advantages of half-wave voltage doubler

High voltages are produced from the low input voltage source without using the expensive high voltage transformers.

Disadvantages of half-wave voltage doubler

Large ripples (unwanted fluctuations) are present in the output signal.

Full-wave voltage doubler

The full-wave voltage doubler consists of two diodes, two capacitors, and input AC voltage source.

During positive half cycle:

During the positive half cycle of the input AC signal, diode D₁ is forward biased. So the diode D₁ allows electric current through it. This current will flows to the capacitor C₁ and charges it to the peak value of input voltage I.e V_m.

On the other hand, diode D₂ is reverse biased during the positive half cycle. So the diode D₂ does not allow electric current through it. Therefore, the capacitor C₂ is uncharged.

The full-wave voltage doubler consists of two diodes, two capacitors, and input AC voltage source.

During negative half cycle:

During the negative half cycle of the input AC signal, the diode D₂ is forward biased. So the diode D₂ allows electric current through it. This current will flows to the capacitor C₂ and charges it to the peak value of the input voltage I.e. V_m.

On the other hand, diode D₁ is reverse biased during the negative half cycle. So the diode D₁ does not allow electric current through it.

Thus, the capacitor C₁ and capacitor C₂ are charged during alternate half cycles.

The output voltage is taken across the two series connected capacitors C₁ and C₂.

If no load is connected, the output voltage is equal to the sum of capacitor C₁ voltage and capacitor C₂ voltage I.e. C₁ + C₂ = V_m + V_m = 2V_m. When a load is connected to the output terminals, the output voltage V_owill be somewhat less than 2V_m.

The circuit is called full-wave voltage doubler because one of the output capacitors is being charged during each half cycle of the input voltage.

Voltage tripler

The voltage tripler can be obtained by adding one more diode-capacitor stage to the half-wave voltage doubler circuit.

During first positive half cycle:

During the first positive half cycle of the input AC signal, the diode D₁ is forward biased whereas diodes D₂ and D₃ are reverse biased. Hence, the diode D₁ allows electric current through it. This current will flows to the capacitor C₁ and charges it to the peak value of the input voltage I.e. V_m.

The voltage tripler can be obtained by adding one more diode-capacitor stage to the half-wave doubler circuit.

During negative half cycle:

During the negative half cycle, diode D₂ is forward biased whereas diodes D₁ and D₃ are reverse biased. Hence, the diode D₂ allows electric current through it. This current will flows to the capacitor C₂ and charges it. The capacitor C₂is charged to twice the peak voltage of the input signal (2V_m). This is because the charge (V_m) stored in the capacitor C₁ is discharged during the negative half cycle.

Therefore, the capacitor C₁ voltage (V_m) and the input voltage (V_m) is added to the capacitor C₂ I.e Capacitor voltage + input voltage = V_m + V_m = 2V_m. As a result, the capacitor C₂ charges to 2V_m.

During second positive half cycle:

During the second positive half cycle, the diode D₃ is forward biased whereas diodes D₁ and D₂ are reverse biased. Diode D₁ is reverse biased because the voltage at X is negative due to charged voltage V_m, across C₁and diode D₂ is reverse biased because of its orientation. As a result, the voltage (2V_m) across capacitor C₂ is discharged. This charge will flow to the capacitor C₃ and charges it to the same voltage 2V_m.

The capacitors C₁ and C₃ are in series and the output voltage is taken across the two series connected capacitors C₁ and C₃. The voltage across capacitor C₁ is V_m and capacitor C₃ is 2V_m. So the total output voltage is equal to the sum of capacitor C₁ voltage and capacitor C₃ voltage I.e. C₁ + C₃ = V_m + 2V_m = 3V_m.

Therefore, the total output voltage obtained in voltage tripler is 3V_m which is three times more than the applied input voltage.

Voltage quadrupler

The voltage quadrupler can be obtained by adding one more diode-capacitor stage to the voltage tripler circuit.

During first positive half cycle:

During the first positive half cycle of the input AC signal, the diode D₁ is forward biased whereas diodes D₂, D₃ and D4 are reverse biased. Hence, the diode D₁ allows electric current through it. This current will flows to the capacitor C₁ and charges it to the peak value of the input voltage I.e. V_m.

The voltage quadrupler can be obtained by adding one more diode-capacitor stage to the voltage tripler circuit.

During first negative half cycle:

During the first negative half cycle, diode D₂ is forward biased and diodes D₁, D₃ and D₄ are reverse biased. Hence, the diode D₂ allows electric current through it. This current will flows to the capacitor C₂ and charges it. The capacitor C₂is charged to twice the peak voltage of the input signal (2V_m). This is because the charge (V_m) stored in the capacitor C₁ is discharged during the negative half cycle.

During second positive half cycle:

During the second positive half cycle, the diode D₃ is forward biased and diodes D₁, D₂ and D₄ are reverse biased. Diode D₁ is reverse biased because the voltage at X is negative due to charged voltage V_m, across C₁ and, diode D₂ and D₄are reverse biased because of their orientation. As a result, the voltage (2V_m) across capacitor C₂ is discharged. This charge will flow to the capacitor C₃ and charges it to the same voltage 2V_m.

During second negative half cycle:

During the second negative half cycle, diodes D₂ and D₄ are forward biased whereas diodes D₁ and D₃ are reverse biased. As a result, the charge (2V_m) stored in the capacitor C₃ is discharged. This charge will flow to the capacitor C₄ and charges it to the same voltage (2V_m).

The capacitors C₂ and C₄ are in series and the output voltage is taken across the two series connected capacitors C₂ and C₄. The voltage across capacitor C₂ is 2V_m and capacitor C₄ is 2V_m. So the total output voltage is equal to the sum of capacitor C₂ voltage and capacitor C₄ voltage I.e. C₂ + C₄ = 2V_m + 2V_m = 4V_m.

Therefore, the total output voltage obtained in voltage quadrupler is 4V_m which is four times more than the applied input voltage.

Applications of voltage multipliers

Voltage multipliers are used in:

Cathode Ray Tubes (CRTs)
Traveling wave tubes
Laser systems
X-ray systems
LCD backlighting
hv power supplies
Power supplies
Oscilloscopes
Particle accelerators
Ion pumps
Copy machines

Voltage Multiplier