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You are reading: Constant Current vs Constant Voltage

Frequently Asked Questions

Why do I need an LED Driver ?

Yes you do – LEDs operate at safe extra low voltage (SELV up to 60v DC) yet outlets supply 240v alternating current. The purpose of an LED driver is to rectify (change) this higher 240v alternating current to a low voltage controlled current suitable for the LED.

LEDs are constant current devices with a forward voltage requirement. This means the SELV voltage from the driver must match the LED requirement in order for the current to flow and “light” the LED, by controlling the current mA, you control the intensity, the lower the current the less intensity but too much current will cause the LED to degrade at a faster rate due to over heating. LED’s are sensitive technical electronics and need care and attention matching the correct driver.

Constant Current or Constant Voltage ?

Constant Current Drivers

A “constant current” LED driver varies the voltage to maintain a constant electrical current. This guarantees that no matter the fluctuation voltage, the current driven to the LED will be maintained at the specified level. Constant current drivers list their specification as an output current e.g. 500mA and the forward voltage range e.g. 10-32fV. MLP. supplies the LED and driver as a package ensuring compatibility.

Constant Voltage Drivers

Constant voltage drivers have a fixed voltage that is typically either 12VDC or 24VDC, mainly used on LED tape. The LED are supplied with a constant DC voltage, each section of the LED tape has a constant current driver located on the LED tape. So although the tape is fed with 24Vdc this is converted to constant current to power the LED.

How to dim an LED ?

When we talk about dimming the focus is on the control method to the driver, e.g. Dali, 1-10v, phase, Casambi this is the input control side, what we don’t talk about is how the driver dims the brightness of LED.

Continuous Current reduction – CCR

If the normal current is 700mA and we reduce the current to 350mA and will get approx. 50% light reduction. If we can vary the current output of the driver from 0mA to 700mA we will get 0-100% brightness. This is called “continuous current reduction”. The problem is that as you reduce the amperage to the LED its characteristics change, it becomes more efficient, so the dimming curve is non linear ( the eye does not see 50% electrical reduction in power as 50% reduction in light, the retina delates and allows more light in as you dim) So we need to dim harder and harder at lower levels.

CCR also called amplitude dimming is the default for most LED dimming drivers

PWM – Pulse width modulation

This is switching the output of a driver on and off really quickly, typically min of 300 Hz a second. The eye can’t see high frequency switching over 120+/-  times per second, so the eye sees a reduced brightness. If you want to dim 50% you turn the power to the LED off 50% and 50% on each second at high frequency. This works really well until around 30% or lower dim levels. At these low levels there is a lot more “off” than “on” time …. This can be seen as flicker. At very low dim levels the LED could be lit only on 1 in 99 cycles. There are now standards for minimum flicker due to negative health effects, IEEE P1789

PWM is mainly used with 24v constant voltage LED dimming

Hybrid both CCR and PWM

Some suppliers have taken the best of both brightness reduction techniques and combined them into one, the best known is EldoLED which uses PWM 100 to 30% and CCR 30-0% but mixes the two with every clever software. EldoLED also market a product range called “dim to dark” this down to 0.1% then off, all within the flicker standards IEEE P1789.

EldoLED hybrid is regarded as the BMW of LED’s drivers with a premium price

Note – “Warm dim” LEDs must use CCR or EldoLED, they don’t work with PWM. This is a good example of the complexity of LED’s and their drivers, it requires years of experience from trusted suppliers to match the LED, driver and dimming system.

What is the max amperage ?

The specification of the fixture will list the max amps expressed in milliamps (1000th of an amp) typically this may be 350mA, 500mA, 700mA. Its ok to under-run a fixture at a lower mA rate. On many Modular Lighting Instruments fixtures they list three mA ranges. Do NOT exceed the max mA. The reason is that the higher the amps – the higher the power – the higher the heat. Exceeding the amperage will shorten the life of the LED. Reducing the amperage will increase the life.

What is forward voltage ?

Forward voltage is the amount of voltage required to make the LED “light” (the voltage creates a flow of electrons across the “band gap” this creates blue spectrum light that is converted to white light via the phosphors) The LED will have a forward voltage specification e.g.  Modular Smart Lotis 82 is 17.1 -19.8Vf at 500mA. Its a range because LED chips are “grown” in high pressure ovens and like children they are not exactly the same.

Some times the Vf is expressed as “typical” this is to simplify the specifcation and will be the average.

 

 

 

 

 

The driver is “constant current” but has a variable forward voltage. A typical driver would state 500mA and Vf 15-40, on the Smart Lotis 82 example we know the LED requirement is 19.8Vf, the driver voltage range must be lower than the Vf spec and higher than the Vf spec, the driver will vary the voltage, this will take into account the cable distance from driver to LED, and the LED voltage tolerance. If the driver maximum voltage is less than the LED voltage requirement  the LED will not light. If the lowest voltage range of the driver is higher that the LED voltage requirement the LED will fail early though over voltage.

Drivers are more electrically efficient at max load, we try and select a driver as close as possible to its max (but not too close …) Some drivers have a very wide Vf like EldoLED Eco 20w 2-40VF this means it will work with almost anything… the downside is more expensive circuit design and if only loaded with a single LED chip at 700mA its 3.4VF x 0.7amp = 2.4w load on a 20w driver. Driver consumption is around 3 watts plus the load, so 5.4w for a 2w LED…

Series or parallel wiring ?

Think about three batteries in a torch end to end, each battery is 1.5v, you have the positive end on the negative end, this gives a total of 4.5v, the voltage is added but the power (current) remains the same. This is series wiring. If you join the three positives together and the three negatives together the voltage will remain 1.5v but the power increases by 3 times, this is parallel wiring.

99% of cases we wire LEDs in SERIES, the Vf increases and the amperage remains the same. As most LED fittings are SELV (Safe extra low voltage) less than 60vDC this limits the quantity of LED we can wire in series. We can’t exceed 60vDC

This example is right on the limit, 3 x Lotis 82 at 500mA = 19.8Vf = 59.4Vf so would not be ideal, its is very close to the max 60vDC SELV limit. Two Lotis yes, three no. In most cases we use one driver per downligh, easy so the voltage requirement is 19.8Vf

We do regularly wire small wattage LED fixtures in series, these have one LED with a voltage of 3.2Vf at 500mA, so the maximum we can wire is 60v / 3.2v = 18. In practice we would limit this to 12 to 15 to allow tolerance in the wiring from driver to LEDʼs (there is volt drop along the total cable length, the danger is that there is not enough forward voltage to light all 15 fittings)

In an example of outdoor step lightning it makes sense to use one remote driver to power all 12 fittings. The Vf requirement is 12 x 3.2v = 38.4v it is wise to use a driver that has a higher forward voltage eg EldoLED 30w Solo which has a Vf of 2-55Vf, this allows a voltage drop along the cable of 55v – 38.4v of 16.6v, this is enough for say 30mts of cable. If the cables are long and the Vf load high it is worth asking the electrical engineer to calculate the volt drop along the cable. This is the load (amps), the resistance of the cable (bigger cable less resistance), and the length in Mts

We rarely wire in parallel (voltage remains the same but amperage increases)in this case the amperage of 2000mA is across the 4 fijngs so each fitting gets 500mA. The issue is that if one fitting fails we then have 2000mA across 3 fitting’s which is higher than the max allowed, then another one will fail so 2000mA on 2 fittings. You can see the advantage of series wiring, if a fitting fails the current is constant and the voltage will vary to suit the load, hence our preference for EldoLED 2-55Vf , its OK to run 1 to 12 fittings on the same driver.

By the way your house is wired in parallel, maybe why electricians who mainly do houses struggle with LEDs.

How many LED’s on the driver ?

In many ways we have covered this. Most standard downlights will have one driver per downlight, easy. When wiring small LEDs in series we need to be look at amperage and forward volts. We supply our products as a package with fixtures and a suitable matched driver. We do not supply fixtures only, its just asking for trouble.

What dimming control method Dali – 1-10v – Phase – wireless ?

This is generally advised to us in the request to quote, if we don’t know the dimming control method we allow for Dali drivers as they are the most common in commercial lighting. LEDs are complex fragile electronics and require knowledge and care. If in doubt please ask.

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