This has always kinda bugged me. Sometimes books/online tutos ect... will say "Use a blah resistor to limit the voltage" and then say "Use a blah resistor to limit the current". I was wondering when you are limiting the volltage with a resistor and when you are limiting current. I believe you do both at the same time but can anyone clarify for a beginner?
Thanks that clarifies it up pretty good. I would like a more technical answer and andother one:
What is the difference between putting a resistor in front or behind the component. In front meaning POWERSOURCE->Resistor->Component->Ground.
Behind meaning POWERSOURCE->Component->Resistor->Ground.
Thanks that clarifies it up pretty good. I would like a more technical answer and andother one:
What is the difference between putting a resistor in front or behind the component. In front meaning POWERSOURCE->Resistor->Component->Ground.
Behind meaning POWERSOURCE->Component->Resistor->Ground.
In this setup will there be any different voltage/current to the LED? Also how could you decrease voltage but keep the current the same or decrease the current and keep the voltage the same? Or would this never need to happen?
here is one difference (in the case of LEDs); although it is not an electrical reason, but a thermal reason.
resistors should be placed on the anode lead of the LED (the high side) to keep heat from the resistor from migrating into the junction of the LED. the anode lead is joined to the junction by a very thin bond wire, in comparison, the cathode lead is directly connected to the substrate / die-cup.
this really only applies when you're designing a printed circuit board and wish to cover all your bases in terms of thermal design.
reference: Lumileds "Recommended Design Practices for Proper Thermal Management"
here is one difference (in the case of LEDs); although it is not an electrical reason, but a thermal reason.
resistors should be placed on the anode lead of the LED (the high side) to keep heat from the resistor from migrating into the junction of the LED. the anode lead is joined to the junction by a very thin bond wire, in comparison, the cathode lead is directly connected to the substrate / die-cup.
this really only applies when you're designing a printed circuit board and wish to cover all your bases in terms of thermal design.
reference: Lumileds "Recommended Design Practices for Proper Thermal Management"
here is one difference (in the case of LEDs); although it is not an electrical reason, but a thermal reason.
resistors should be placed on the anode lead of the LED (the high side) to keep heat from the resistor from migrating into the junction of the LED. the anode lead is joined to the junction by a very thin bond wire, in comparison, the cathode lead is directly connected to the substrate / die-cup.
this really only applies when you're designing a printed circuit board and wish to cover all your bases in terms of thermal design.
reference: Lumileds "Recommended Design Practices for Proper Thermal Management"
Strikes me as mostly a complete waste of time?, certainly in 99.99...% of cases - however, IF you are generating a LOT of heat in the resistor, IF you are pushing the LED right to it's limits, IF the PCB is badly designed to put the resistor close to the LED, then it 'might' be worth doing?.
However, better design in the first place would seem to be the order of the day?.
Also, bear in mind, this isn't for standard LED's, but for the stupidly bright ones that probably won't have a long life anyway?.
apparently the engineering team at Phillips-Lumileds thought it important enough to write about, and they're not alone ... Nichia, Lamina, Cree, HP all have similar documents
if your resistor is dissipating 150mw ((5v - 2v) / 0.05a), why would you want that heat conducted into the LED junction, which is already having to deal with a dissipation of 100 mw (2 Vf * 0.05 If)... if your design calls for ten resistors, each dissipating 100mw, that is an extra watt of heat that has to go somewhere... designing your board so that the heat is channeled elsewhere instead of into the junction of heat-sensitive LEDs makes "very good" sense to me.
It seems like the stupidly bright LEDs are already phasing out stupidly inefficient incandescent bulbs in many applications - its no surprise that thermal considerations are important with them as they are with any component.
I dont see any "slight mix up" in DIY's post.... anode - bond wire: cathode - die cup.