AC capacitor circuits
Capacitors do not behave the same as
resistors. Whereas resistors allow a flow of electrons through them
directly proportional to the voltage drop, capacitors oppose changes
in voltage by drawing or supplying current as they charge or discharge
to the new voltage level. The flow of electrons "through" a capacitor is
directly proportional to the rate of change of voltage across the
capacitor. This opposition to voltage change is another form of
reactance, but one that is precisely opposite to the kind exhibited
by inductors.
Expressed mathematically, the
relationship between the current "through" the capacitor and rate of
voltage change across the capacitor is as such:
The expression de/dt is one from
calculus, meaning the rate of change of instantaneous voltage (e) over
time, in volts per second. The capacitance (C) is in Farads, and the
instantaneous current (i), of course, is in amps. Sometimes you will
find the rate of instantaneous voltage change over time expressed as dv/dt
instead of de/dt: using the lower-case letter "v" instead or "e" to
represent voltage, but it means the exact same thing. To show what
happens with alternating current, let's analyze a simple capacitor
circuit:
If we were to plot the current and
voltage for this very simple circuit, it would look something like this:
Remember, the current through a capacitor
is a reaction against the change in voltage across it. Therefore,
the instantaneous current is zero whenever the instantaneous voltage is
at a peak (zero change, or level slope, on the voltage sine wave), and
the instantaneous current is at a peak wherever the instantaneous
voltage is at maximum change (the points of steepest slope on the
voltage wave, where it crosses the zero line). This results in a voltage
wave that is -90o out of phase with the current wave. Looking
at the graph, the current wave seems to have a "head start" on the
voltage wave; the current "leads" the voltage, and the voltage "lags"
behind the current.
As you might have guessed, the same
unusual power wave that we saw with the simple inductor circuit is
present in the simple capacitor circuit, too:
As with the simple inductor circuit, the
90 degree phase shift between voltage and current results in a power
wave that alternates equally between positive and negative. This means
that a capacitor does not dissipate power as it reacts against changes
in voltage; it merely absorbs and releases power, alternately.
A capacitor's opposition to change in
voltage translates to an opposition to alternating voltage in general,
which is by definition always changing in instantaneous magnitude and
direction. For any given magnitude of AC voltage at a given frequency, a
capacitor of given size will "conduct" a certain magnitude of AC
current. Just as the current through a resistor is a function of the
voltage across the resistor and the resistance offered by the resistor,
the AC current through a capacitor is a function of the AC voltage
across it, and the reactance offered by the capacitor. As with
inductors, the reactance of a capacitor is expressed in ohms and
symbolized by the letter X (or XC to be more specific).
Since capacitors "conduct" current in
proportion to the rate of voltage change, they will pass more current
for faster-changing voltages (as they charge and discharge to the same
voltage peaks in less time), and less current for slower-changing
voltages. What this means is that reactance in ohms for any capacitor is
inversely proportional to the frequency of the alternating
current:
For a 100 uF capacitor:
Frequency (Hertz) Reactance (Ohms)
----------------------------------------
| 60 | 26.5258 |
|--------------------------------------|
| 120 | 13.2629 |
|--------------------------------------|
| 2500 | 0.6366 |
----------------------------------------
Please note that the relationship of
capacitive reactance to frequency is exactly opposite from that of
inductive reactance. Capacitive reactance (in ohms) decreases with
increasing AC frequency. Conversely, inductive reactance (in ohms)
increases with increasing AC frequency. Inductors oppose faster changing
currents by producing greater voltage drops; capacitors oppose faster
changing voltage drops by allowing greater currents.
As with inductors, the reactance
equation's 2πf term may be replaced by the lower-case Greek letter Omega
(ω), which is referred to as the angular velocity of the AC
circuit. Thus, the equation XC = 1/(2πfC) could also be
written as XC = 1/(ωC), with ω cast in units of radians
per second.
Alternating current in a simple
capacitive circuit is equal to the voltage (in volts) divided by the
capacitive reactance (in ohms), just as either alternating or direct
current in a simple resistive circuit is equal to the voltage (in volts)
divided by the resistance (in ohms). The following circuit illustrates
this mathematical relationship by example:
However, we need to keep in mind that
voltage and current are not in phase here. As was shown earlier, the
current has a phase shift of +90o with respect to the
voltage. If we represent these phase angles of voltage and current
mathematically, we can calculate the phase angle of the inductor's
reactive opposition to current.
Mathematically, we say that the phase
angle of a capacitor's opposition to current is -90o, meaning
that a capacitor's opposition to current is a negative imaginary
quantity. This phase angle of reactive opposition to current becomes
critically important in circuit analysis, especially for complex AC
circuits where reactance and resistance interact. It will prove
beneficial to represent any component's opposition to current in
terms of complex numbers, and not just scalar quantities of resistance
and reactance.
- REVIEW:
- Capacitive reactance
is the opposition that a capacitor offers to alternating current due
to its phase-shifted storage and release of energy in its electric
field. Reactance is symbolized by the capital letter "X" and is
measured in ohms just like resistance (R).
- Capacitive reactance can be calculated
using this formula: XC = 1/(2πfC)
- Capacitive reactance decreases
with increasing frequency. In other words, the higher the frequency,
the less it opposes (the more it "conducts") the AC flow of electrons.
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