4 - Lighting, part II: Measuring Light and LampsOk, so β Which lamps do you need for an indoor garden? How many of them? And where to place them?
To make sure that any money and time spent in lighting setup will pay off, and that no significant amount of energy will be wasted once it's plugged in, it's essential to understand how light is measured and what do lamp parameters mean.
4.1. β Measuring LightOk, so here's a first truism: In order to deliver to your plants at least as much light as they need to sustain reasonable growth (and ideally you should give more than that so they grow lushly) you have to figure out how much light do they need.
The first requirement for that is to have a measuring unit for light. Often, for photography, the unit for measuring light intensity is the
candle; for our gardening purposes, and to agree with the most common parameter in light bulbs available commercially, we will use as our measuring unit the
lumen.
In photometry, the
luminous flux (or luminous power) is the measure of the perceived power of light. Since the PAR range in the plants agrees with the sensitivity of the human eye, we can rely on the measure of luminous flux for our plants.
The
lumen is defined as the amount of luminous flux emitted across a solid angle of one steradian by a light source of one candle of intensity.
Don't be scared, we are going to get practical.
Of course, every plant will have her own ideal light needs, but in this thread we are trying to speak as generally as possible, so I will leave a reasonable rule of thumb for general purposes.
You should aim to deliver at least 20,000 lumens per square meter of growing space (roughly equivalent to 2,000 lumens per square foot) for plants sustaining vegetative growth, and at least 30,000 lumens per square meter (about 3,000 lm per square foot) if you are growing for fruits, flowers or seeds. Remember that the amount of energy contained in a long wavelength (red range) photon is smaller than the amount of energy contained in a short wavelength (blue range) photon, so you need to make up for that difference by delivering more photons to the plant, and that means more lumens per surface unit.
Now let's take a look to the alternatives we have to achieve this.
4.2.β Lamp ParametersI'm compiling here different wiki definitions for all the relevant parameters that you will find in lamp specifications.
Potency: Is the measure of the consumption of energy by the lamp, measured in
Watts.
Luminous Flux: Is the total output of the lamp, measured in
Lumens, when working at full wattage power.
Efficacy: It's the measure of lumens the lamp delivers per every Watt of power consumption. Low efficacy means high production of heat (waste of energy). In order to maximize the results of energy consumption, and considering that gardening lamps will be working for a long time, it's important to aim for high efficacy values. The measure of efficacy, then, is expressed in
Lumens/Watt (lm/W)Color Temperature (CCT) β It's the temperature needed for an ideal black body radiator to emit light of a comparable hue to that of the light source. It's measured in degrees
Kelvin (K). For our practical purposes, it will be enough to remember that the CCT rating is an indication of how βwarmβ or βcoolβ the light source is. CCTs of up to 3000 K correspond to warm colors, and CCTs of 5000 K and more correspond to cool colors.
Color Rendering Index (CRI): Measure of how well colors can be perceived using light from a source, relative to light from a reference source such as daylight. By definition, an incandescent lamp has a CRI of 100. Real-life fluorescent tubes achieve CRIs of anywhere from 50 to 99. Fluorescent lamps with low CRI have phosphors that emit too little red light. Skin appears less pink, and hence "unhealthy" compared with incandescent lighting. Colored objects appear muted. For example, a low CRI 6800 K halophosphate tube (an extreme example) will make reds appear dull red or even brown.
Spectrum: It's the portion of the EM spectrum that can be found in the light produced by the lamp. A good spectrum for gardening delivers plenty of light in the wavelength bands that are optimally used by the plants.
4.3.β Lighting Technologies: Types of LampsIn the last three decades, indoor gardening and horticulture have been revolutionized by the advances in lighting technologies. Here's a summary of the current standard types of lamps. Please note that figures are approximated, and that generally efficacy ranges relate to different wattage powers and different chemical materials within the same category of lamps.
Incandescent LampsWattage Range:
5-500 WEfficacy:
4-20 lm / WCCT:
2400-3400 KSpectrum:
ContinuousLifetime:
2-2,000 hoursIncandescent light bulbs produce light by heating a filament with electric current until it glows. In this family you can find the classic tungsten incandescent bulbs and the halogen lamps. They are cheap but very inefficient, since most of the electric energy they use (95% or more) is converted to heat, and only a little fraction is converted to light. Their spectrum is not good for gardening either. Unless you want to grow plants that have extremely low light requirements (such as certain types of ferns), and you want to make them sweat while wasting a lot of energy, these types of bulbs have no place in an indoor garden.
Fluorescent Lights (FLs)Wattage Range:
15-80W (up to 250W in Compact Fluorescents)Efficacy:
50-100 lm / WCCT:
2700 β 5000 K, depending on the type of fluorescentSpectrum:
Combined (Continuous from the phospor coating, plus the line spectra of the mercury gas discharge)Lifetime:
8000-20,000 hoursFluorescent lamps use electricity to excite gas vapors, producing them to emit short wave ultraviolet light that causes the coating in the tube to fluoresce. The coating produces the visible light, and different types of coating deliver different qualities of light. The overall spectrum of a fluorescent results from the combination of the light emitted by the vapor inside of the tube and the light emitted by the phosphorescent coating.
FLs have much higher efficacy and efficiency than incandescent lamps; they require 25-30% of power to produce the same light as an incandescent. Different types of FL lamps will deliver different CCTs and color dominances, so the choice of lamp should be related to the type of result you want to achieve.
Cool White and
Daylight FL produce a small amount of light in the red range and a larger amount in the blue range, what makes them good for starting seeds or for leafy plants that will not be encouraged to flower.
Warm White FL deliver primarily red wavelengths and less blue light, so they are not ideal for vegetative growth and are more often used to supplement Cool White FLs.
There is also another difference within tubular fluorescent bulbs. You will often see FLs labeled as T5, T8 or T12. The letter T indicates the Tubular shape of the bulb, and the number following represents the diameter of the bulb in eighths of an inch. The standard fluorescents use T12 bulbs, and these are fine for seedlings and early stages. However, if you intend to use FL seriously for growing, you should look for the T5 fluorescent grow lights. Those are much more efficient than the regular wider FL bulbs.
Update: Let's make it a T4. More efficient, thinner fluorescent lamps have become available. I've added a couple 20W T4 6400K tubes to my indoor space, for germination and vegetation, and I'm very pleased with the results.Compact Fluorescent Lights (CFLs) use the same technologies, but their tubes are curved and folded to fit into the space of an incandescent bulb, and include a compact electronic ballast (see
4.4 below) in the base of the lamp. This architecture allows much longer tubes, hence larger power inputs.
They are usually available either in full-spectrum bulbs, that produce a vast range of light wavelengths, and cool-spectrum bulbs that mostly produce blue light. In spite of being placed in a regular incandescent fixture, they also as FLs burn much cooler than incandescent lights, so they can be placed very close to the plant without risks of burning the leaves.
High Intensity Discharge Lamps (HID)HID Lamps produce light with an electric arc between two electrodes housed inside of a alumina or quartz tube, filled with gas and metal salts. They are more efficient than fluorescent lamps, producing more light per unit of electric power consumed. That makes them a good choice for illuminating larger areas, or simply to provide an overall higher light output using a single lamp instead of multiple fluorescent tubes. However, you should always do the maths to see which combination is better for your interests.
They produce light in discrete lines or bands, used in spectral analysis to identify or fingerprint the material producing the light. Different types of HID lamps are classified depending on the elements used inside of the tube.
a.- Mercury Vapor Lamps (MV)They are the less expensive among HID lamps. Unfortunately, they provide the worst spectrum for plant growth, so they are not recommended for indoor gardening.
b.- High Pressure Sodium Lamps (HPS)Wattage Range:
35-1000 WEfficacy:
55-140 lm / WCCT:
1800 β 2200 KSpectrum:
BroadbandLifetime:
10,000-40,000 hoursUnlike Low Pressure Sodium lamps (extremely efficient light sources, often used in street lamps but not useful for gardening due to their narrow yellow light spectrum), HPS lamps emit a wide spectrum more concentrated in the range of red/orange light, so they are particularly useful for the fruiting and flowering stages of plant development.
They show overall a little advantage regarding other HID lamps in terms of efficiency, light output and lifespan, although as said they do have a slightly more specific gardening profile.
c.- Metal Halide Lamps (MH)Wattage Range:
70-1500 WEfficacy:
75-125 lm / WCCT:
3000 β 20,000 KSpectrum:
Quasi-continuousLifetime:
6,000-20,000 hoursMH lamps produce an intense white light output, closer to sunlight than any other HID source, have a good CRI measure, and same as FLs, CFLs and HPS, they are extensively used in indoor gardening. They show a wide spectrum with a strong presence of blue wavelengths, which makes them overall good and specially suitable for vegetative growth.
Traditional MH lamps use a quartz arc tube and can also be referred to as QMH.Also, CMH lights are definitely worth a mention. Thanks to Shaolin for the heads up.
Ceramic Metal Halide (CMH)
Wattage Range: 20-400W
Efficacy: 80-117 lm / W
CCT: 3000 - 5200 K
Spectrum: Quasi-Continuous
Lifetime: 6,000 - 25,000 hours
CMH lamps, also called CDM (Ceramic Discharge Metal Halide) lamps, combine the ceramic arc tube of HPS lamps with the metal salts used in Metal Halide traditional lamps to achieve a very hot plasma illumination source, thanks to the high resistance of the arc tube material. The light produced by CMH lamps presents an excellent CRI of up to 96, with a bluish tint remarkably similar to daylight, that supplies an excellent spectrum. Their performance values make them an optimized cross of HPS and MH technology.
Snozzleberry, in an older thread, wrote:If you're going HID, you should go for Ceramic Metal Halide...They put out more lumens, a broader spectrum that's much closer to the sun's light, burn longer, retain luminosity longer, are cheaper than MH or HPS bulbs, throw less heat, throw more photosynthetically active photons...the list goes on.
Only downside is they currently max out at 400 watt...But use 2 400 watt CMH and I guarantee you'll have better result than a 1000 watt MH.
Warm white CMH lights with lower CRI values are also available. It's recommended to operate both cool and warm CMH lamps with digital ballasts, usually the same type of ballast suitable for high wattage HPS lamps.Light Emitter Diode Lamps (LEDs)Wattage Range:
VariesEfficacy:
10-110 lm / WCCT:
Various ranging from 2700 to 6000 KSpectrum:
Line plus phosphorLifetime:
50,000-100,000 hoursA LED lamp is a lamp made with semiconductor light sources. LED technology is in continuous development, and some of the fancy features of LED lighting include very low heat dissipation, good efficacy and highly customizable lamp setups, since individual LEDs can deliver virtually any discrete light wavelength depending on the materials used. There's many LED lamp fixtures in the market that include combinations of LEDs of different saturated colors, trying to attain a good result for all-purpose indoor gardening. The total power of LED lamps equals the sum of the power of all the individual LEDs included in the fixture.
LED technology is complex and covering it in detail currently exceeds the purpose of this post; it's certainly an option to consider, and it becomes more solid every year, even if the prices of good LED lamps are still expensive when compared to other alternatives. If you intend to go the LED route, you will need to do some research. So far, I can tell you that highly efficient LED lamps require individual LEDs with power higher than 1 watt, preferably 3 watts or more. Be careful with the cheap LED systems, since a lamp with 200 LEDs of 0,5 W each will deliver quite worse results than a lamp with 30 LEDs of 3 W each.
4.4.β Ballasts and Lighting System OutputIn order to work, fluorescent lights and HID lights require a
ballast, a device that regulates the electricity used by the bulb. Lots of pre-assembled lamps like standard fluorescent fixtures and CFL lamps already include their own ballast, so those can be plugged right away to your current supply, but if you want to put together a fluorescent fixture yourself (which will save you some money, and it's pretty easy) or if you intent to use a HID lamp, you will need to purchase a ballast.
There are a couple of different types of ballasts you can choose. Electronic ballasts virtually eliminate flicker, operate quietly, and maximize energy efficiency by reducing heat radiation. Reactive or magnetic ballasts are cheaper but more cumbersome, and their operating hum might be annoying.
It is important that the light and ballast are compatible in voltage and current, so make sure to match the bulb with the ballast. Your hardware store guy can easily help you with this. Also, it's convenient to get a ballast that can deliver at least the wattage power of the lamp you intend to use. If you plug a 150W ballast to a 250W lamp, you're asking the ballast to deliver more power than it's designed to give, and the ballast will end up burning. So if you have a 150W ballast, you could plug to it a 150W lamp, or two 75W lamps, or just one 100W lamp, for instance.
Besides these compatibility bits, the overall efficacy (lm/W) of your lighting setup will be determined by the combination of lamp and ballast. The
ballast factor (BF) is the measured ability of a particular ballast to produce light from the lamp (or lamps) it powers. The BF is a coefficient which returns the actual output in lumens of the lamps powered by it.
For example, if you have two fluorescents that deliver 3500 lumens each, and you assemble them in a fixture using a ballast with a 0,90 BF,
3500 lumens x 2 lamps x 0,90 BF = 6300 lumens
That would be the actual light output of your fixture.
Note that ballast factor is not a measure of energy efficiency. A lower BF will reduce the lamp lumen output, but it also consumes proportionally less input power, since the ballast only delivers what the lamp can consume, limited by its own BF coefficient.
4.5.β Positioning lampsOk. So now you have chosen a lamp, a proper ballast if necessary, and you count with an overall light output of, say, 15,000 lm. But the fact you have 15,000 lumens coming out of your lamps doesn't mean that your plants are receiving the whole 15,000 lumens of light. Of course, you want to make sure that as many of those precious lumens as possible will eventually hit a hungry leaf or stem, so the rest of your job is to maximize the number of photons that hit the spot without causing any trouble in the process.
The first potential source of trouble, obviously, is the
physical electric safety of your setup. That means using plugs and cords in good shape (preferably new ones) and making sure that your hardware is suitable to carry the amount of power you are intending to use. You do NOT want to overload power lines or to smell any hint of burning plastic. Ask in your hardware store to make sure you are good to go if you have any doubts. To be in the safe side, I wholeheartedly recommend to purchase new plugs and cords if you are going to use a significant power input. Also, making sure that the wall appliances are okay and that your electricity supply will handle your plants needs with no problem, on top of the rest of energy requirements in your house.
Make sure that you hang any lighting devices safely, and double-check every plug and connection before you actually place any plant on the shelf under the lights or inside of your growing closet.
Once your physical safety is granted, you can start thinking about the physical safety of your plants. The risks for them can occur in the form of excess of heat, and heat can be a hazard particularly if you are using HID (HPS, MH) lights. With fluorescents it is difficult to actually burn a plant (you would have to place the plants a mere inch or less from the light in order to burn the leaves with a 125W CFL) but you CANNOT position HID lamps too close to the plants or they will burn and wilt. At the same time we know that the intensity of light radiation decreases with the square of the distance, so you want to be able to hang the lights (or to raise the plants) in a position where you have the optimal balance between proximity to the light and protection from excess heat.
As said before, seedlings growing under fluorescent tubes can be safely placed three or four inches below the tubes (try to keep the distance below a foot) so they can use light properly.
For mature plants growing under HID lights, a general guideline for the proper hanging/positioning height of the lamp would be from 12 to 48 inches depending on wattage. That is, 12-24 inches for low watt systems (up to 150W), 18-36 inches for medium watt systems (200-400W) and at least 24 inches for high watt systems above 400W. However, the particular characteristics of the plants you are growing might have the last say in this.
When in doubt, just check for excess heat at the top of your plants by placing your hand palm down over the plants. If the top of your hand is hot, you need to move your lamp higher.
A very convenient device to add, specially in the case of high-wattage lighting systems in closed spaces, is a good
exhausting fan. I'll talk a little about ventilation in a future post.
Other things to keep in mind related to lights placement are
phototropism (see
post #3) and the convenience of using reflective materials in the sides or walls of your grow space to maximize the number of photons reaching the plant. Mylar is a top option, but just white paper or paint will show excellent reflective properties. Just be careful when using tin foil, specially if it's wrinkled, because the irregular reflection of light might cause hot spots that could leave burn marks in the plant leaves.
You also have the possibility of using (or designing yourself) a system for the lights to move or rotate periodically, to evenly reach every corner in your plants, but honestly I have no experience with those and I think that proper light placement and orientation should be enough. But of course, experimenting is great and you might make lighting discoveries for particular plant species, so definitely try, learn and report.
So, in summary β unless you are willing to roll up your sleeves and learn about LED lighting (and you have some real money to spend) you should use fluorescent, MH or HPS lamps for indoor gardening. Choose which type of lamp suits better the needs of your plants following the information you have, calculate the power you need in order to energize your plants according to the garden surface to light up, get a proper ballast if your lamp needs it, deploy the fixtures in an electrically safe and effective way, set the photoperiod using a programmable timer, and you are good to go
"The Menu is Not The Meal." - Alan Watts