Difference between revisions of "LED Lighting"
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| + | ==Types of LED== | ||
| + | LEDs used in diy can fall into 3 types: | ||
| + | - mains LED lamps (typ 1-11w) | ||
| + | - micropower individual die LEDs (typ 40-60mW) | ||
| + | - higher power lighting dice (eg 1-5w) | ||
| + | |||
| + | |||
| + | ===Mains LED lamps=== | ||
| + | [[image:800px-E27_with_38_LCD.jpg|400px]] | ||
| + | |||
| + | These are intended as drop in replacments for other types of mains lightbulbs, and are available in various colours, including white. | ||
| + | |||
| + | Mains LED lamps aren't really equivalent replacements for filament lamps, and typically come with the following properties: | ||
| + | * much lower light output than the filament lamp they replace | ||
| + | * lower power, typ 1-11w | ||
| + | * much lower CRI (light quality) than other domestic lighting | ||
| + | * long life times | ||
| + | * Efficacy around twice that of halogen, but lower than CFL or linear fluorescent | ||
| + | * built in ballasts fry if used on an MSW invertor | ||
| + | * white LEDs degrade significantly in use | ||
| + | * Operating temp is much lower than filament lamps, life expectancy is long, and very low powers are available, making them a good candidate for nightlighting. | ||
| + | |||
| + | |||
| + | ===Individual die LEDs=== | ||
[[image:Row_LEDs2.jpg|400px]] | [[image:Row_LEDs2.jpg|400px]] | ||
Single die '''LEDs''' are miniature very low power solid state light sources sometimes used for low light output applications. They are commonly available in sizes from 2mm upwards. They have niche applications, but are not in a position to take over from other forms of lighting for general lighting service. | Single die '''LEDs''' are miniature very low power solid state light sources sometimes used for low light output applications. They are commonly available in sizes from 2mm upwards. They have niche applications, but are not in a position to take over from other forms of lighting for general lighting service. | ||
| − | [[image: | + | [[image:RGB-LED2.jpg|thumb]] |
| + | * Typ 40-60mW | ||
| + | * Available in a range of colours plus white | ||
| + | * Sizes from 2mm to 10mm diameter, with 5mm most common. | ||
| + | * Only 'ultrabright' LEDs are suitable for micropower lighting | ||
| + | * Good for lighting glass shelves and glass objects | ||
| + | * These require a current limited low voltage dc power supply. Trying to operate them any other way kills them. | ||
| + | |||
| + | Ultrabright coloured LEDs are commonly available in 2mm to 20mm sizes rated 40mW - 80mW for in the region of 20p-30p per LED. These LEDs are typically rated in the region of 2-4v 20mA, and must be supplied by a current controlled low voltage dc supply. Lots of these LEDs would be needed for even very dim room lighting. | ||
| + | |||
| + | Their tiny size, minimal power consumption, cold operation and safe low voltage makes them fittable almost anywhere. Their very low output makes them mostly used for dim but strongly coloured glows and nightlighting. | ||
| + | |||
| + | They may be used with glass shelving to give the glass edges a coloured glow, or to light glass objects. | ||
| + | |||
| + | Bicolour LEDs contain 2 dice of different colours back to back. These may be switched between the 2 colours, or may be faded from one colour to another at will by driving with ac and controlling the current in each half cycle separately. | ||
| + | |||
| − | + | ===Higher power lighting dice=== | |
| + | * typ 1-5w | ||
| + | * come in larger flat packages (than 5mm LEDs) | ||
| + | * Otherwise the same properties as the micropower dice | ||
| Line 12: | Line 55: | ||
* Available in many pure single colours as well as white | * Available in many pure single colours as well as white | ||
| − | * Efficacy of over 40 lpw for the most efficient ones, less for many. | + | * Efficacy of over 40 lpw for the most efficient ones, less for many. Expect around twice the efficacy of halogens. |
| − | * Power per lamp is low | + | * Power per lamp is low due to thermal issues. |
* Quality (CRI) of white light is poor | * Quality (CRI) of white light is poor | ||
* Individual LED dice are tiny enough to feed light into the edges of glass shelves and glass objects. | * Individual LED dice are tiny enough to feed light into the edges of glass shelves and glass objects. | ||
* Colour changing LEDs are available | * Colour changing LEDs are available | ||
* Lamps are expensive per watt | * Lamps are expensive per watt | ||
| + | * LED lights are usually very long lived, with 50,000 hours often quoted. Not all live upto this though. | ||
==LED vs Fluorescent== | ==LED vs Fluorescent== | ||
'''Disadvantages:''' | '''Disadvantages:''' | ||
| − | * | + | * Lighting LEDs haven't reached the efficacies of [[fluorescent]] lighting. |
* The lowest cost lower efficacy LEDs have not reached the efficacies of low cost linear fl or [[CFL]]. | * The lowest cost lower efficacy LEDs have not reached the efficacies of low cost linear fl or [[CFL]]. | ||
| − | * LEDs' upfront cost is much higher for anything beyond | + | * LEDs' upfront cost is much higher for anything beyond tiny light output. |
* LED light quality is poor compared to fluorescent. | * LED light quality is poor compared to fluorescent. | ||
* LEDs are not available in powers comparable to fl lights | * LEDs are not available in powers comparable to fl lights | ||
'''Advantages:''' | '''Advantages:''' | ||
| − | * Some, but far from all, LEDs have much longer lives than fl tubes. | + | * Some, but far from all, LEDs have much longer lives than fl tubes. |
* LEDs are very mechanically robust | * LEDs are very mechanically robust | ||
| − | * LEDs in very low powers are | + | * LEDs in very low powers are extremely small |
* The lowest power LEDs (single die fractional watt) are available in sizes 2mm to 10mm. | * The lowest power LEDs (single die fractional watt) are available in sizes 2mm to 10mm. | ||
| − | Things may change, as LED performance is getting better year by year. But they | + | Things may change, as LED performance is getting better year by year. But they haven't got there yet, despite the hype. |
| Line 40: | Line 84: | ||
LEDs are available producing single monochromatic colours or in white. Colour LEDs are considerably cheaper than whites and suffer less from deterioration. One LED colour deteriorates badly, and is thus unsuitable for lighting, this is pink LEDs. | LEDs are available producing single monochromatic colours or in white. Colour LEDs are considerably cheaper than whites and suffer less from deterioration. One LED colour deteriorates badly, and is thus unsuitable for lighting, this is pink LEDs. | ||
| − | |||
| − | + | ==Ballasts== | |
| + | Mains LED bulbs have their own built in ballast, so this section addresses ballasts used with the much smaller LED dice. | ||
| − | + | Micropower and single die LEDs can not simply be connected to a power supply, they need external current control. (Mains LED lamps don't.) A little basic external electronics is used to do this. | |
| − | + | More or less all micropower LEDs are rated at 20mA max, and this figure should not be exceeded, or lifetime reduces rapidly. | |
| − | + | The most common option is to use parallel series strings, with each series string having its own current limiting resistor. For example: | |
| − | + | 0v ---|>|-----|>|-----|>|---/\/\--- + | |
| − | |||
| − | |||
| − | |||
| − | + | or | |
LED1 LED2 LED3 LED4 R1 | LED1 LED2 LED3 LED4 R1 | ||
| Line 73: | Line 114: | ||
LEDs are constant voltage devices, and will have the same V drop regardless of current. This then leaves the resistor in each string seeing voltage variations that are the same in absolute terms as the supply voltage variation, but much greater in percentage terms. Therefore any supply voltage variation causes several times the percentage of variation in light output. | LEDs are constant voltage devices, and will have the same V drop regardless of current. This then leaves the resistor in each string seeing voltage variations that are the same in absolute terms as the supply voltage variation, but much greater in percentage terms. Therefore any supply voltage variation causes several times the percentage of variation in light output. | ||
| − | For mains | + | For mains power supplies, LEDs adding upto to 2/3 - 3/4 of the supply voltage should be fine. Variation is not usually then noticeable. |
| − | Brightness variation can be avoided entirely | + | Brightness variation can be avoided entirely by using a stabilised supply, but this isn't completely necessary. |
| − | |||
| + | ===LED circuits=== | ||
| − | +-----|>|-----+ | + | |
| − | -----| |-----^^^^----- | + | +-----|>|-----+ |
| + | -----| |-----^^^^----- | ||
+-----|<|-----+ | +-----|<|-----+ | ||
| − | + | LEDs Resistor | |
| − | + | 2 LEDs on an AC supply | |
| Line 96: | Line 138: | ||
| − | +-----|>|-----^^^^----+ The output of each | + | +-----|>|-----^^^^----+ The output of each |
| − | -----| |----- by | + | -----| |----- LED is controlled by |
| − | +-----|<|-----^^^^----+ | + | +-----|<|-----^^^^----+ its own resistor value |
LEDs Resistors | LEDs Resistors | ||
| Line 125: | Line 167: | ||
Colour control with 2 LEDs on a DC supply | Colour control with 2 LEDs on a DC supply | ||
| + | |||
| + | With adjustable colour circuits using a potentiometer, the max current is set by the fixed resistors alone, and the pot value can be in the region of twice this much resistance. The end user can then dial the desired colour. | ||
| + | |||
==Polarity== | ==Polarity== | ||
| + | [[image:Ledmrp.jpg|200px]] | ||
| + | |||
LEDs must be connected with the correct polarity, as they only conduct one way, and they can only withstand a few volts in reverse. | LEDs must be connected with the correct polarity, as they only conduct one way, and they can only withstand a few volts in reverse. | ||
Length of leads is not a reliable indicator of polarity, despite being often quoted as a method of determining it. The shape of the internal construction tells the polarity reliably. | Length of leads is not a reliable indicator of polarity, despite being often quoted as a method of determining it. The shape of the internal construction tells the polarity reliably. | ||
| − | |||
==Life== | ==Life== | ||
| − | LEDs are famed for very long lives of | + | LEDs are famed for very long lives of 100,000 hours. But this only applies to LEDs conservatively run, such as LED indicators. When much greater output for lighting is wanted, run currents must be higher, and lamp life falls to around 50,000 hours for some LED lighting, and sometimes significantly less. |
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
==See Also== | ==See Also== | ||
Revision as of 01:44, 13 August 2009
Types of LED
LEDs used in diy can fall into 3 types: - mains LED lamps (typ 1-11w) - micropower individual die LEDs (typ 40-60mW) - higher power lighting dice (eg 1-5w)
Mains LED lamps
These are intended as drop in replacments for other types of mains lightbulbs, and are available in various colours, including white.
Mains LED lamps aren't really equivalent replacements for filament lamps, and typically come with the following properties:
- much lower light output than the filament lamp they replace
- lower power, typ 1-11w
- much lower CRI (light quality) than other domestic lighting
- long life times
- Efficacy around twice that of halogen, but lower than CFL or linear fluorescent
- built in ballasts fry if used on an MSW invertor
- white LEDs degrade significantly in use
- Operating temp is much lower than filament lamps, life expectancy is long, and very low powers are available, making them a good candidate for nightlighting.
Individual die LEDs
Single die LEDs are miniature very low power solid state light sources sometimes used for low light output applications. They are commonly available in sizes from 2mm upwards. They have niche applications, but are not in a position to take over from other forms of lighting for general lighting service.
- Typ 40-60mW
- Available in a range of colours plus white
- Sizes from 2mm to 10mm diameter, with 5mm most common.
- Only 'ultrabright' LEDs are suitable for micropower lighting
- Good for lighting glass shelves and glass objects
- These require a current limited low voltage dc power supply. Trying to operate them any other way kills them.
Ultrabright coloured LEDs are commonly available in 2mm to 20mm sizes rated 40mW - 80mW for in the region of 20p-30p per LED. These LEDs are typically rated in the region of 2-4v 20mA, and must be supplied by a current controlled low voltage dc supply. Lots of these LEDs would be needed for even very dim room lighting.
Their tiny size, minimal power consumption, cold operation and safe low voltage makes them fittable almost anywhere. Their very low output makes them mostly used for dim but strongly coloured glows and nightlighting.
They may be used with glass shelving to give the glass edges a coloured glow, or to light glass objects.
Bicolour LEDs contain 2 dice of different colours back to back. These may be switched between the 2 colours, or may be faded from one colour to another at will by driving with ac and controlling the current in each half cycle separately.
Higher power lighting dice
- typ 1-5w
- come in larger flat packages (than 5mm LEDs)
- Otherwise the same properties as the micropower dice
LED properties
LEDs have their uses, but much hype about LEDs exists, and many users have been disappointed as a result.
- Available in many pure single colours as well as white
- Efficacy of over 40 lpw for the most efficient ones, less for many. Expect around twice the efficacy of halogens.
- Power per lamp is low due to thermal issues.
- Quality (CRI) of white light is poor
- Individual LED dice are tiny enough to feed light into the edges of glass shelves and glass objects.
- Colour changing LEDs are available
- Lamps are expensive per watt
- LED lights are usually very long lived, with 50,000 hours often quoted. Not all live upto this though.
LED vs Fluorescent
Disadvantages:
- Lighting LEDs haven't reached the efficacies of fluorescent lighting.
- The lowest cost lower efficacy LEDs have not reached the efficacies of low cost linear fl or CFL.
- LEDs' upfront cost is much higher for anything beyond tiny light output.
- LED light quality is poor compared to fluorescent.
- LEDs are not available in powers comparable to fl lights
Advantages:
- Some, but far from all, LEDs have much longer lives than fl tubes.
- LEDs are very mechanically robust
- LEDs in very low powers are extremely small
- The lowest power LEDs (single die fractional watt) are available in sizes 2mm to 10mm.
Things may change, as LED performance is getting better year by year. But they haven't got there yet, despite the hype.
Colour
LEDs are available producing single monochromatic colours or in white. Colour LEDs are considerably cheaper than whites and suffer less from deterioration. One LED colour deteriorates badly, and is thus unsuitable for lighting, this is pink LEDs.
Ballasts
Mains LED bulbs have their own built in ballast, so this section addresses ballasts used with the much smaller LED dice.
Micropower and single die LEDs can not simply be connected to a power supply, they need external current control. (Mains LED lamps don't.) A little basic external electronics is used to do this.
More or less all micropower LEDs are rated at 20mA max, and this figure should not be exceeded, or lifetime reduces rapidly.
The most common option is to use parallel series strings, with each series string having its own current limiting resistor. For example:
0v ---|>|-----|>|-----|>|---/\/\--- +
or
LED1 LED2 LED3 LED4 R1 +----|>|-----|>|-----|>|-----|>|---/\/\---+ | | +----|>|-----|>|-----|>|-----|>|---/\/\---+ | | +----|>|-----|>|-----|>|-----|>|---/\/\---+ | | +----|>|-----|>|-----|>|-----|>|---/\/\---+ | | | | o +12v 0v o
How close to the supply voltage your LED string voltage should add up to depends on how stable the supply voltage is, and how much brightness variation is acceptable.
LEDs are constant voltage devices, and will have the same V drop regardless of current. This then leaves the resistor in each string seeing voltage variations that are the same in absolute terms as the supply voltage variation, but much greater in percentage terms. Therefore any supply voltage variation causes several times the percentage of variation in light output.
For mains power supplies, LEDs adding upto to 2/3 - 3/4 of the supply voltage should be fine. Variation is not usually then noticeable.
Brightness variation can be avoided entirely by using a stabilised supply, but this isn't completely necessary.
LED circuits
+-----|>|-----+
-----| |-----^^^^-----
+-----|<|-----+
LEDs Resistor
2 LEDs on an AC supply
-----|<|>|----------^^^^----- Bipolar LED Resistor A bipolar LED on an AC supply
+-----|>|-----^^^^----+ The output of each
-----| |----- LED is controlled by
+-----|<|-----^^^^----+ its own resistor value
LEDs Resistors
Colour mixing LEDs on an AC supply
+-----|>|-----^^^^------+
| >
-----| ><--------
| >
+-----|<|-----^^^^------+
LEDs Resistors Potentiometer
Colour control with 2 LEDs on an AC supply
+-----|>|-----^^^^------+
| >
-----| ><--------
| >
+-----|>|-----^^^^------+
LEDs Resistors Potentiometer
Colour control with 2 LEDs on a DC supply
With adjustable colour circuits using a potentiometer, the max current is set by the fixed resistors alone, and the pot value can be in the region of twice this much resistance. The end user can then dial the desired colour.
Polarity
LEDs must be connected with the correct polarity, as they only conduct one way, and they can only withstand a few volts in reverse.
Length of leads is not a reliable indicator of polarity, despite being often quoted as a method of determining it. The shape of the internal construction tells the polarity reliably.
Life
LEDs are famed for very long lives of 100,000 hours. But this only applies to LEDs conservatively run, such as LED indicators. When much greater output for lighting is wanted, run currents must be higher, and lamp life falls to around 50,000 hours for some LED lighting, and sometimes significantly less.