Too Hot? Too Cold? The Goldilocks Syndrome - LUX-TSI
Transcription
Too Hot? Too Cold? The Goldilocks Syndrome - LUX-TSI
Too Hot? Too Cold? Life was simple when the only choice we had was between the different wattage on an incandescent light bulb. The Goldilocks Nowadays we need to know about such Syndrome locus and CIE colour space diagrams. things as Colour temperature, Planckian Before you start feeling blue, or indeed seeing multiple shades of it, have a quick word with the Doctor, who might be able to help. So why temperature to describe C olour? When we in ‘the trade’ want to describe the colour of light, and specifically when we want to ensure nobody else really understands what we’re going on about, we talk about chromaticity coordinates xy, uv or u’v’ or tristimulus values XYZ (so either a 2 or 3 number description). Yes our Christmas parties can be quite a humdinger! Clearly this is meaningless in the real world, so a more intuitive “Colour temperature” T:01656864618 description is used to describe the colour of [email protected] light emitted by a white light source. www.lux-tsi.com ©Lux-Tsi.Allrightsreserved 1 Buteverysimplificationintroducesitsownproblems It’s possible that light from different sources (e.g. fluorescent lamps, HIDs or LED modules) – with ostensibly the same ‘temperature’ are noticeably different. But nobody would ever know if it weren’t for the fact that sooner or later, you would want to source (say) a matching LED module from another vendor! Sowhythedifference? Good question! … and to get to the bottom of this issue, we do need to go back to some basic physics and colour temperature definitions. True colour temperature is defined as the colour of radiation emitted from a perfect blackbody radiator held at a particular temperature……. …… and a blackbody radiator is a source that emits radiation across a wide wavelength range according to Plank’s law. BeforewegotoPhysics,letshaveahistory lesson: Remember the humble light bulb? Edison* discovered that when you pass an electric current through a filament of tungsten wire, the current encounters resistance. This resistance creates heat and the tungsten wire starts to glow – a process called incandescence. ©Lux-Tsi.Allrightsreserved 2 With increasing current the temperature increases and the light evolves from red to white. Another scientist by way of Max Planck (1858-1947) discovered that a black body’s (electromagnetic) radiation is determined only by its temperature. ‘Modestly’ he called this Planck’s Radiation Law. And in our example, the blackbody radiator is the hot metal tungsten wires in Edison’s light bulb! So there we have it in simple terms: The hotter the tungsten wires becomes, the more the colour changes. All we needed now was a way of correlating the exact relationship between the two. This was provided (in 1931 and updated numerous times since) by The Commission Internationale de l'Eclairage (CIE) a very well respected International institution. The CIE defined the link between physical pure colors (i.e. wavelengths) in the electromagnetic visible spectrum, and physiological perceived colors in human color vision. They plotted blackbody radiation ranging from temperatures between 1,000 Kelvin to 20,000 Kelvin on what is now known as a Planckian locus. This locus is a twodimension graph with x,y coordinates known as chromaticity coordinates. Colours on this locus are considered to be “white”. However at the lower end (2,000 K) the light is considered reddish (or “warm”) white”, whilst at 20,000 K the light is considered bluish (or “cool”) white. So, confusingly, the colder the black body the warmer the colour temperature – as if nature ©Lux-Tsi.Allrightsreserved *Edison - Ok I know that you know that Edison did not discover the light bulb, but was at the end of long line of inventors that did all the hard work in refining and perfecting it. It wasn’t even Edison whose name was on the patent, but his chief engineer- but never the less he’s the one that made money out of it. 3 was not cruel enough! Most traditional (incandescent) light bulbs emit light at a colour temperature of about 2,800 to 3,100 Kelvin – which as explained earlier would put it in the “warm” white light category as there is still a red (warm) hue to the light. Now here comes an interesting twist. Other light sources, such as fluorescent or discharge lamps, or LEDs emit light by a process called electroluminescence and not by heating up lumps of metal (incandescence) so do not emit radiation with the same distribution of wavelengths. This means that the white light emitted by that source will not (necessarily) fall directly on the Planckian locus, so scientists had to conjure up a ‘fix’. This fix called the correlated colour temperature (CCT) is designed to approximate the closest point on the locus for the light being categorized. The key word to note here is C orrelated. But this fix is not always perfect and not always well understood- it’s all in the definition! We’ve established the chromaticity coordinates of a true blackbody source must (by definition) fall exactly on the Planckian locus - whereas the chromaticity coordinates for other light sources will fall along a line that intersects the blackbody locus at the equivalent (true) colour temperature (this line is called the “ISO-CCT” line). So for example, for a standard incandescent lamp (in this case a CIE “illuminant A”) with a colour temperature of 2856 K, its x, y chromaticity coordinates will be exactly 0. ©Lux-Tsi.Allrightsreserved 4 4476 and 0.4075 respectively. However a light source with a CCT of 2,856 K can actual have chromaticity coordinates which are not on this Planckian locus. This is better explained in the picture shown in CIE 1931 colour space (x,y, coordinates) where the curved line is the Planckian locus and the lines intersecting this are the lines of constant correlated colour temperature (CCT) thus showing a large range of chromaticities which are described by the same CCT. Above the line the light will be more green in appearance and below the line it will be more pink. Now given the human eye perceives differences with a variation of just ± 0.001 in x or y, describing light colour using only CCT permits deviations up to 20 times beyond this perception threshold. Therefore CCT is not a good way to specify light colour. If you stick to defining the colour of your white LEDs by their CCT, you’ll likely end up with a smorgasbord of shades of greens and pinks. This clearly is unsatisfactory when you wish to produce a high quality lighting product with a consistent colour. The solution is obvious of course: Define the colour of your white LED in terms of the CIE chromaticity coordinates. Maybe not as elegant but it will stop you seeing Red T:01656864618 [email protected] www.lux-tsi.com ©Lux-Tsi.Allrightsreserved Measuring the colour, luminous efficacy and brightness of LEDs, luminaires, lamps and displays is what Lux-TSI does (amongst other light related activity) –we’ll even do CCT readings. 5