1. ELECTRONICS TECHNOLOGY CAPACITANCE
2008JULY06
CAPACITANCE
Benchmark Companies Inc
PO Box
Aurora CO 80047
ELECTRONICS TECHNOLOGY CAPACITANCE

2. DEFINED
Capacitance is the measure of how much electrical charge a device can store.
Capacitance is measured in Farads (F)
The device used in electronics for storing this charge is called the capacitor.

3. DEFINED
Non-polarized
Electrolytic
Variable
Schematic Symbols

4. The number you obtain is in picofarads.
CAPACITOR CODE
Determine the value of the capacitor by utilizing this general method
Ceramic Disc
Capacitors have a code
that shows their value
100,000 ρF or
.1uF
The number you obtain is in picofarads.

5. THEORY
The capacitor is made from two metal plates with an insulator type material in the center called a dielectric. When power is applied to the circuit the capacitor will attract electrons to plate A.
Charging
+++
- - -

6. THEORY
The electrons can not pass through the dielectric so the plate starts storing electrons. The electrons on plate B are repelled from plate A and attracted to the power source leaving the plate positively charged. This process lasts until the capacitor has been fully charged.
Charging
+++
- - -

7. THEORY
Discharging
Once the capacitor is charged it may now be used to power a consuming device. There is one limitation. The device can only be powered as long as the charge is in the capacitor. The electrons on plate A will attract to plate B once there is a path for them to flow. Once all the electrons have been neutralized, the capacitor has lost all of its charge.
+++
- - -

8. RATING CAPACITORS Capacitors are rated in Farads and Volts
- One farad is equal to 1amp being charged by an EMF of 1volt per second. The formula is shown below.
C = Capacitance in Farads
I = Current in amps
E=Voltage in volts
t=time in seconds
-Typically capacitors are in Microfarads (µF) or Picofarads (pF).
-The voltage rating is a working rating the capacitor can handle before being damaged.

9. CAPACITORS IN SERIES
The total capacitance in a series circuit adds up inversely just as resisters do in parallel.

10. CAPACITORS IN PARALLEL
The capacitance of capacitors in parallel work like resistors in series. The capacitance of each of the capacitors add up to the total capacitance of the circuit.

11. CAPACITOR TYPES Electrolytic Ceramic Disc Variable Capacitor
Polyester Film
Radial
Lead
Axial
Lead

12. CERAMIC DISC CAPACITORS
Capacitors are named for the material that make up the dielectric.
Ceramic Disc capacitors are rounded in shape and are usually a light brown color. The advantage to the Ceramic Disc capacitor is that it can work at small capacitance and high voltages.

13. ELECTROLYTIC CAPACITORS
Electrolytic Capacitors are capacitors that have their plates polarized. One plate is positive and one negative. It is very dangerous to reverse the polarity of an electrolytic capacitor and should not be done. Electrolytic capacitors can handle very large capacitances for their size.
Electrolytic
Radial
Lead
Axial

14. ELECTROLYTIC CAPACITORS
These capacitors look like tin cans and their leads can be radial or axial. The rating of these devices is easily read on the device itself - no code. The rectangular shape in the lightly shaded area on the capacitor indicates which lead is negative. On the axial capacitor an arrow points to the negative lead.
Electrolytic
Radial
Lead
Axial

15. VARIABLE CAPACITORS Variable Capacitors are used in tuning circuits.
The capacitor can be used as a filter in order to tune in a specific frequency.

16. OTHER CAPACITORS
There are many other types of capacitors. Their names come from the material that makes up the dielectric. The ratings for these capacitors are usually labeled on the device.
Chip
Capacitor
Polypropylene
Film
Mylar
Tantalum
Polyester Film

17. RC TIME CONSTANT
The RC Time Constant in the time it takes, in a series resistor capacitor circuit, for voltage to rise to 63.2% or fall to 36.8% of the peak voltage value of the circuit. When five of these time constants occur, the capacitor will be fully charged. The formula below can be used to predict this value.
t = Time in seconds
R = Resistance in Ohms
C = Capacitance in Farads

18. RC TIME CONSTANT example
With a 1kΩ resistor and a 1μF capacitor placed in series, what is the time constant of the circuit and how long will it take to fully charge the capacitor?
Time Constant Calculation
t =RC
t=1kΩ x 1μF
t =1000Ω x F
t=1ms
Full Charge Time = 1ms x 5
Full Charge Time = 5ms
Capacitor Fully Charged

19. RC TIME CONSTANT GRAPHIC REPRESENTATION
The first cursor proves that at
1ms the voltage is 6.32V
The second cursor is showing that after 5 time constants the capacitor is fully charged.

20. USING A MULTIMETER
Some Multimeters can read the capacitance of capacitors. Place the capacitor in the holes as shown in the figure to the right.
Set dial for the F(Farads) setting then read the screen. Change range if necessary. The capacitor below is .02uF.

21. End of Presentation