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Capacitance| |Reactance| |Charging| Timeconstant|Discharging| Uses| CapacitorCoupling
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Also See: Capacitors | Power Supplies
Capacitance
Capacitance (symbol C) is a measure of a capacitor's ability to store charge.A large capacitance means that more charge can be stored. Capacitance is measured in farads, symbol F,but 1F is very large so prefixes (multipliers) are used to show smaller values:
- µ (micro) means 10-6 (millionth), so1000000µF=1F
- n (nano) means 10-9 (thousand-millionth), so1000nF=1µF
- p (pico) means 10-12 (million-millionth), so1000pF=1nF
 unpolarised capacitor |  polarised capacitor |
Rapid Electronics: Capacitors
Charge and Energy Stored
The amount of charge (Q) stored by a capacitor is given by:
Charge, Q=C×V
When they store charge, capacitors are also storing energy (E):
Energy, E = ½QV = ½CV²
Q = charge in coulombs (C)
C = capacitance in farads (F)
V = voltage in volts (V)
E = energy in joules (J)
Capacitors return their stored energy to the circuit
Note that capacitors return their stored energy to the circuit. They do not 'use up' electrical energyby converting it to heat as a resistor does.
The energy stored by a capacitor is much smaller than theenergy stored by a battery so they cannot be used as a source of energy for most purposes.
Capacitive Reactance Xc
Capacitive reactance (Xc) is a measure of a capacitor's opposition to AC (alternating current).Like resistance it is measured in ohms (Ω)but reactance is more complex than resistance because its value depends on the frequency (f)of the electrical signal passing through the capacitor as well as on the capacitance (C).
| Capacitive reactance, Xc = | 1 |
2 fC |
Xc = reactance in ohms (Ω)
f = frequency in hertz (Hz)
C = capacitance in farads (F)
The reactance is large at low frequencies and small at high frequencies.For steady DC which is zero frequency, Xc is infinite (total opposition), hence the rule thatcapacitors pass AC but block DC.
For example a 1µF capacitor has a reactance of3.2kΩ for a 50Hz signal,but when the frequency is higher at 10kHz its reactance is only16Ω.
Capacitive and Inductive Reactance
The symbol Xc is used to distinguish capacitive reactance from inductive reactance XLwhich is a property of inductors.
The distinction is important because XL increases with frequency (the opposite of Xc) andif both XL and Xc are present in a circuit the combined reactance (X) is the difference between them.
For further information please see the page on Impedance.
Capacitors in Series and Parallel
The combined capacitance (C) of capacitors connected in series is given by:
| 1 | = | 1 | + | 1 | + | 1 | + ... |
| C | C1 | C2 | C3 |
The combined capacitance (C) of capacitors connected in parallel is:
C=C1+C2+C3+...
Two or more capacitors are rarely deliberately connected in series in real circuits, butit can be useful to connect capacitors in parallel to obtain a very large capacitance,for example to smooth a power supply.
Note that these equations are the opposite way round forresistors in series and parallel.
Charging a capacitor
The capacitor (C) in the circuit diagram is being charged from a supply voltage (Vs) with the currentpassing through a resistor (R). The voltage across the capacitor (Vc) is initially zero but it increasesas the capacitor charges. The capacitor is fully charged when Vc=Vs.
The charging current (I) is determined by the voltage across the resistor (Vs-Vc):
Charging current, I=(Vs-Vc)/R
At first Vc = 0V so:
Initial current, Io=Vs/R
Vc increases as soon as charge (Q) starts to build up (Vc=Q/C), this reduces the voltage across the resistorand therefore reduces the charging current. This means that the rate of charging becomes progressively slower.
Time constant (RC)
The time constant is a measure of how slowly a capacitor charges with current flowing through a resistor.A large time constant means the capacitor charges slowly. Note that the time constant is a property of thecircuit containing the capacitor and resistor, it is not a property of the capacitor alone.
timeconstant=R×C
time constant is in seconds (s)
R = resistance in ohms (Ω)
C = capacitance in farads (F)
Examples
If R = 47kΩ & C=22µF,then RC=47kΩ×22µF=1.0s.
If R = 33kΩ & C=1µF,then RC=33kΩ×1µF=33ms.
The time constant (RC) is the time taken for the charging (or discharging) current (I) to fall to1/e of its initial value (Io). 'e' is an important number in mathematics(like ).e=2.71828 (to 6 significant figures) so we can roughly say that the time constant is thetime taken for the current to fall to 1/3 of its initial value.
After each time constant the current falls by 1/e (about 1/3).After 5 time constants (5RC) the current has fallen to less than 1% of its initial value and we can reasonablysay that the capacitor is fully charged, but in fact the capacitor takes for ever to charge fully!
The bottom graph shows how the voltage (V)increases as the capacitor charges. At first the voltage changes rapidly because the current is large;but as the current decreases, the charge builds up more slowly and the voltage increases more slowly.
| Time | Voltage | Charge |
| 0RC | 0.0V | 0% |
| 1RC | 5.7V | 63% |
| 2RC | 7.8V | 86% |
| 3RC | 8.6V | 95% |
| 4RC | 8.8V | 98% |
| 5RC | 8.9V | 99% |
Charging a capacitor
time constant=RC
After 5 time constants (5RC) the capacitor is almost fully charged with its voltage almost equal to thesupply voltage. We can reasonably say that the capacitor is fully charged after 5RC, although really chargingcontinues for ever (or until the circuit is changed).
Discharging a capacitor
The top graph shows how the current (I) decreases as the capacitor discharges.The initial current (Io) is determined by the initial voltage across the capacitor (Vo) and resistance (R):
Initial current, Io=Vs/R
Note that the current graphs are the same shape for both charging and discharging a capacitor.This type of graph is an example of exponential decay.
The bottom graph shows how the voltage (V) decreases as the capacitor discharges.
| Time | Voltage | Charge |
| 0RC | 9.0V | 100% |
| 1RC | 3.3V | 37% |
| 2RC | 1.2V | 14% |
| 3RC | 0.4V | 5% |
| 4RC | 0.2V | 2% |
| 5RC | 0.1V | 1% |
Discharging a capacitor
time constant=RC
At first the current is large because the voltage is large, so charge is lost quickly and the voltagedecreases rapidly. As charge is lost the voltage is reduced making the current smaller so the rateof discharging becomes progressively slower.
After 5 time constants (5RC) the voltage across the capacitor is almost zero and we can reasonably say thatthe capacitor is fully discharged, although really discharging continues for ever (or until the circuit is changed).
Uses of Capacitors
Capacitors are used for several purposes:
- Timing - for example with a 555timerIC controlling the charging and discharging.
- Smoothing - for example in a powersupply.
- Coupling - for example between stages of an audiosystem and to connect a loudspeaker.
- Filtering - for example in the tone control of an audiosystem.
- Tuning - for example in a radiosystem.
- Storing energy - for example in a camera flash circuit.
Capacitor Coupling (CR-coupling)
Sections of electronic circuits may be linked with a capacitor because capacitors pass AC(changing) signals but block DC (steady) signals.This is called capacitor coupling or CR-coupling.
It is used between the stages of an audio system to pass on the audio signal (AC) without any steady voltage (DC)which may be present, for example to connect a loudspeaker.It is also used for the 'AC' switch setting on an oscilloscope.
The precise behaviour of a capacitor coupling is determined by its time constant (RC).Note that the resistance (R) may be inside the next circuit section rather than a separate resistor.
For successful capacitor coupling in an audio system the signals must pass throughwith little or no distortion. This is achieved if the time constant (RC) is larger thanthe timeperiod (T) of the lowest frequency audio signalsrequired (typically 20Hz, T=50ms).
- Output when RC >> T
When the time constant is much larger than the time period of the input signalthe capacitor does not have sufficient time to significantly charge or discharge,so the signal passes through with negligible distortion. - Output when RC = T
When the time constant is equal to the time period you can see that the capacitorhas time to partly charge and discharge before the signal changes. As a result there issignificant distortion of the signal as it passes through the CR-coupling. Notice howthe sudden changes of the input signal pass straight through the capacitor to the output. - Output when RC << T
When the time constant is much smaller than the time period the capacitor has timeto fully charge or discharge after each sudden change in the input signal.Effectively only the sudden changes pass through to the output and they appear as 'spikes',alternately positive and negative. This can be useful in a system which must detect whena signal changes suddenly, but ignore slow changes.
Recommended books for more advanced study from Amazon
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Art of Electronics
This excellent book is widely regarded as essential for anyone wishing to seriously study electronics. Although topics are covered inconsiderable depth it is written in a relatively easy, informal style with practical examples. Highly recommended.
Learning the Art of Electronics
A great introduction to circuit design with thorough explanations of how the example circuits work.
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