Example:
Circuit symbol: 
Function
LEDs
emit light when an electric current passes through them.
Connecting
and soldering
LEDs
must be connected the correct way round, the diagram may be labelled
a or for anode and k or - for cathode
(yes, it really is k, not c, for cathode!). The cathode is the short
lead and there may be a slight flat on the body of round LEDs. If you
can see inside the LED the cathode is the larger electrode (but this
is not an official identification method).
LEDs
can be damaged by heat when soldering, but the risk is small unless
you are very slow. No special precautions are needed for soldering
most LEDs.
Testing
an LED
Never
connect an LED directly to a battery or power supply!
It will be destroyed almost instantly because too much current
will pass through and burn it out.
LEDs
must have a resistor in series to limit the current to a safe value,
for quick testing purposes a 1k resistor is suitable for most LEDs if
your supply voltage is 12V or less. Remember to connect the LED
the correct way round!
Colours
of LEDs
LEDs
are available in red, orange, amber, yellow, green, blue and white.
Blue and white LEDs are much more expensive than the other colours.
The
colour of an LED is determined by the semiconductor material, not by
the colouring of the 'package' (the plastic body). LEDs of all
colours are available in uncoloured packages which may be diffused
(milky) or clear (often described as 'water clear'). The coloured
packages are also available as diffused (the standard type) or
transparent.
Tri-colour
LEDs
The
most popular type of tri-colour LED has a red and a green LED
combined in one package with three leads. They are called tri-colour
because mixed red and green light appears to be yellow and this is
produced when both the red and green LEDs are on.
The
diagram shows the construction of a tri-colour LED. Note the
different lengths of the three leads. The centre lead (k) is the
common cathode for both LEDs, the outer leads (a1 and a2) are the
anodes to the LEDs allowing each one to be lit separately, or both
together to give the third colour.
Bi-colour
LEDs
A
bi-colour LED has two LEDs wired in 'inverse parallel' (one forwards,
one backwards) combined in one package with two leads. Only one of
the LEDs can be lit at one time and they are less useful than the
tri-colour LEDs described above.
Sizes,
Shapes and Viewing angles of LEDs
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|
LED
Clip
|
LEDs are
available in a wide variety of sizes and shapes. The 'standard' LED
has a round cross-section of 5mm diameter and this is probably the
best type for general use, but 3mm round LEDs are also popular.
Round
cross-section LEDs are frequently used and they are very easy to
install on boxes by drilling a hole of the LED diameter, adding a
spot of glue will help to hold the LED if necessary. LED clips are
also available to secure LEDs in holes. Other cross-section shapes
include square, rectangular and triangular.
As
well as a variety of colours, sizes and shapes, LEDs also vary in
their viewing angle. This tells you how much the beam of light
spreads out. Standard LEDs have a viewing angle of 60° but others
have a narrow beam of 30° or less.
Calculating
an LED resistor value
An
LED must have a resistor connected in series to limit the current
through the LED, otherwise it will burn out almost instantly.
The
resistor value, R is given by:
VS
= supply voltage
VL = LED voltage (usually 2V, but 4V
for blue and white LEDs)
I = LED current (e.g. 20mA), this must
be less than the maximum permitted
If
the calculated value is not available choose the nearest standard
resistor value which is greater, so that the current will be a
little less than you chose. In fact you may wish to choose a greater
resistor value to reduce the current (to increase battery life for
example) but this will make the LED less bright.
For
example
If
the supply voltage VS = 9V, and you have a red LED (VL
= 2V), requiring a current I = 20mA = 0.020A,
R = (9V - 2V) /
0.02A = 350, so choose 390 (the nearest standard value which is
greater).
Working
out the LED resistor formula using Ohm's law
Ohm's
law says that the resistance of the resistor, R = V/I, where:
V = voltage across the resistor (= VS - VL
in this case)
I = the current through the resistor
So
R = (VS - VL) / I
Connecting
LEDs in series
If
you wish to have several LEDs on at the same time it may be possible
to connect them in series. This prolongs battery life by lighting
several LEDs with the same current as just one LED.
All
the LEDs connected in series pass the same current so it is
best if they are all the same type. The power supply must have
sufficient voltage to provide about 2V for each LED (4V for blue and
white) plus at least another 2V for the resistor. To work out a value
for the resistor you must add up all the LED voltages and use this
for VL.
Example
calculations:
A red, a yellow and a green LED in series need
a supply voltage of at least 3 × 2V 2V = 8V,
so a 9V battery would be ideal.
VL = 2V 2V
2V = 6V (the three LED voltages added up).
If the supply voltage
VS is 9V and the current I must be 15mA = 0.015A,
Resistor R = (VS - VL) / I = (9 - 6) /
0.015 = 3 / 0.015 = 200,
so choose R = 220 (the nearest standard
value which is greater).
Avoid
connecting LEDs in parallel!
Connecting
several LEDs in parallel with just one resistor shared between them
is generally not a good idea.
If
the LEDs require slightly different voltages only the lowest voltage
LED will light and it may be destroyed by the larger current flowing
through it. Although identical LEDs can be successfully connected in
parallel with one resistor this rarely offers any useful benefit
because resistors are very cheap and the current used is the same as
connecting the LEDs individually. If
LEDs are in parallel each one should have its own resistor.
Reading
a table of technical data for LEDs
Suppliers'
catalogues usually include tables of technical data for components
such as LEDs. These tables contain a good deal of useful information
in a compact form but they can be difficult to understand if you are
not familiar with the abbreviations used.
The
table below shows typical technical data for some 5mm diameter round
LEDs with diffused packages (plastic bodies). Only three columns are
important and these are shown in bold. Please see below for
explanations of the quantities.
|
Type
|
Colour
|
IF
max.
|
VF
typ.
|
VF
max.
|
VR
max.
|
Luminous
intensity
|
Viewing
angle
|
Wavelength
|
|
Standard
|
Red
|
30mA
|
1.7V
|
2.1V
|
5V
|
5mcd
@ 10mA
|
60°
|
660nm
|
|
Standard
|
Bright
red
|
30mA
|
2.0V
|
2.5V
|
5V
|
80mcd
@ 10mA
|
60°
|
625nm
|
|
Standard
|
Yellow
|
30mA
|
2.1V
|
2.5V
|
5V
|
32mcd
@ 10mA
|
60°
|
590nm
|
|
Standard
|
Green
|
25mA
|
2.2V
|
2.5V
|
5V
|
32mcd
@ 10mA
|
60°
|
565nm
|
|
High
intensity
|
Blue
|
30mA
|
4.5V
|
5.5V
|
5V
|
60mcd
@ 20mA
|
50°
|
430nm
|
|
Super
bright
|
Red
|
30mA
|
1.85V
|
2.5V
|
5V
|
500mcd
@ 20mA
|
60°
|
660nm
|
|
Low
current
|
Red
|
30mA
|
1.7V
|
2.0V
|
5V
|
5mcd
@ 2mA
|
60°
|
625nm
|
|
IF
max.
|
Maximum
forward current, forward just means with the LED connected
correctly.
|
|
VF
typ.
|
Typical
forward voltage, VL in the LED resistor calculation.
This is about 2V, except for blue and white LEDs for which it
is about 4V.
|
|
VF
max.
|
Maximum
forward voltage.
|
|
VR
max.
|
Maximum
reverse voltage
You can ignore this for LEDs
connected the correct way round.
|
|
Luminous
intensity
|
Brightness
of the LED at the given current, mcd = millicandela.
|
|
Viewing
angle
|
Standard
LEDs have a viewing angle of 60°, others emit a narrower beam
of about 30°.
|
|
Wavelength
|
The peak
wavelength of the light emitted, this determines the colour of the
LED.
nm = nanometre.
|
Flashing
LEDs
Flashing
LEDs look like ordinary LEDs but they contain an integrated circuit
(IC) as well as the LED itself. The IC flashes the LED at a low
frequency, typically 3Hz (3 flashes per second). They are designed to
be connected directly to a supply, usually 9 - 12V, and no series
resistor is required. Their flash frequency is fixed so their use is
limited and you may prefer to build your own circuit to flash an
ordinary LED, for example our Flashing LED project which
uses a 555 astable circuit.
LED
Displays
LED
displays are packages of many LEDs arranged in a pattern, the most
familiar pattern being the 7-segment displays for showing numbers
(digits 0-9). The pictures below illustrate some of the popular
designs:
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|
|
|
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Bargraph
|
7-segment
|
Starburst
|
Dot
matrix
|
|
|
Pin
connections of LED displays
There
are many types of LED display and a supplier's catalogue should be
consulted for the pin connections. Like many 7-segment displays, this
example is available in two versions: Common Anode (SA) with all the
LED anodes connected together and Common Cathode (SC) with all the
cathodes connected together. Letters a-g refer to the 7 segments, A/C
is the common anode or cathode as appropriate (on 2 pins). Note that
some pins are not present (NP) but their position is still numbered.