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- Introduction to Diodes
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What
is "Signal Rectification"?
Signal rectification is a process in which you process an AC (Alternating
Current) signal (often sinusoidal) to get a DC signal or a signal with
a DC component.
Why
Rectify Signals
There are many situations in which you want to "rectify" a signal.
Here are some of the most common situations.
In power supplies the
AC supply voltage (60 Hz in the U.S., from the wall plug) is converted
to a constant DC value to power electronic circuits that require a constant
voltage to operate. Examples include the following:
Computers
Television sets
Radios
Stereo Systems
Guitar Amplifiers &
Sound Systems in General
In signal systems, information
coded into the amplitude of a sinusoidal signal must be rectified to extract
the information. Examples include the following:
AM radios
Sensors - like some kinds
of tachometers - which produce a sinusoidal signal where the amplitude
encodes the value of a physical quantity like rotational rate.
Signal rectification is an important concept
and is often used in a variety of systems.
Simple
Signal Rectification
Here is a simple signal rectifier. When the input voltage is positive,
the output voltage is approximately equal to the input.
Using
A Capacitor In A Rectifier - Building A Peak Detector
Here is a circuit.
Here is what happens in this circuit.
When the sinusoidal input
is increasing and the capacitor is uncharged, current flows through the
diode to charge the capacitor. (Remember, current is just charge
flowing, so when current flows through the diode into the capacitor, charge
accumulates in the capacitor.)
At some point in time,
the input voltage begins to decrease. At that point, the diode stops
conducting and the capacitor/resistor combination is effectively cut off
from the rest of the circuit and the capacitor begins to discharge through
the resistor.
As the capacitor discharges,
eventually the input voltage gets to a point where it equals the capacitor
voltage, and the diode begins conducting again, charging the capacitor
in the process.
There are some things to consider. The first point to consider is
just how far the voltage will droop from the peak until it begins to increase
again. Just past the peak the voltage across the capacitor will decrease
for a short while. What happens is that the input voltage (the sine
wave) is decreasing but not decreasing very quickly. (As you get
further from the peak the voltage begins to decrease more quickly.)
When the input voltage is not decreasing very quickly, the charge flowing
out of the capacitor can flow through the resistor, and there will still
be current flowing through the diode. (Some of the current flowing
through the diode comes from charge on the capacitor, and some flows through
the diode.) However, sooner or later, the input voltage gets to the
point where it is decreasing faster than the capacitor voltage can change.
The limit on how fast the capacitor can discharge is determined by the
resistor. For a given voltage, Vout on the capacitor,
the current out of the capacitor is limited to Vout/R.
Since the capacitor current is CVoutd/dt, the rate of
change of capacitor voltage can be computed as dVout/dt
= -Vout/(RC). At that point
There are a few other points to note about this circuit.
The resistor in parallel
with the capacitor may well be the internal resistance of the capacitor.
The simulation above assumes
that the diode is an ideal diode. That's pictured below with the
bold red graph.
We can add a "bias" to the diode model
to get closer to reality. The voltage-current curve for a better
model is shown below. Click the button to see how closely the model
comes to the v-i curve for a "typical" diode.
If we incorporate that model into our simulation,
then the simulation is different.
You can see in the simulation that the output
voltage does not quite follow the input voltage - due to the threshold
voltage in the diode.
