“DSLR Camera” – The Internet Reefer’s Decoder Ring

DSLR Camera

p_cameraA type of camera used in the hobby to take unrealistically detailed pictures of corals and their aquariums.

These pictures rarely look like what you’d see with your naked eyes even if no software “fakery” has been applied.  (A safe assumption?)

The camera can take in more light and see in much higher resolution than your eyeball in real life.

Entries in the Internet Reefer’s Decoder Ring are terms you’ll find in the course of online discussion about reefing that make very little sense.   In some cases, these terms seem to have been borrowed from another industry where the term did have meaning, but the meaning did not carry over to reefing.

Kill A Watt Power Meter

20160125-110540.jpgI use this Kill A Watt meter to measure any device I have electricity questions about.  I also use it to measure total system power usage and even to track cost over time.

For the price, a Kill A Watt meter eliminates so many questions and has even given me some answers I didn’t know the questions to yet!

Highly worth the cost!

“Full Spectrum” – The Internet Reefer’s Decoder Ring

Full Spectrum

Visble Light Spectrum
Visible Sunlight (Credit: NSO/AURA/NSF)

By Matt Carroll

Before we even talk about the term “full spectrum“, please take a moment to enjoy the above high resolution spectrograph of “white light” from the sun, courtesy of the folks at NOAO.

(They offer even higher resolution versions at the link.   They also offer a hi-res spectrograph of the sun’s entire spectrum – white light, plus everything else.)

Note the numerous gaps as we get on with the discussion!

History

The original electric light was an incandescent light bulb.

Incandescent bulbs produce a full spectrum light not unlike the spectrum of white light put out by the sun at a certain time of the day.

In contrast to these old-style lights, electric lights we are familiar with in the hobby such as fluorescent lamps and high intensity discharge (HID) metal halide lamps all put out nearly monochromatic light mostly based on the emission of mercury vapor at various combinations of pressure and temperature.  Although sodium lights are another monochromatic alternative.220px-hg-spektrum_crop

Here’s an example spectrum of mercury’s color emission from Wikipedia:

Not full spectrum at all.  To the eye it’s more of an ugly green light with very few wavelengths of light present.

Let’s look at more examples!

Incandescent

imageHere’s a sample of the output from my spectrometer with the spectrum provided by a GE Reveal incandescent bulb.

This is a bulb with a bluish neodymium coating that causes the spectrum to be choppier than a regular clear glass incandescent bulb.  That is the reason for the few dim spots in the spectrum.

Fluorescent

Most cheap, household fluorescents aren’t that far removed from the basic mercury emission, which you will recall only puts out a few  spikes of color in red green and blue.

imageHere’s a sample of the output from my spectrometer with the spectrum provided by an Ikea branded 11-watt compact florescent (CFL) bulb:

spectrometer_outputNext is a great example of a Phillips florescent bulb that has been heavily modified to be “full spectrum”:

From comparing those two photos, it’s clear what folks meant when they came up with the term “full spectrum”.

It meant not missing 90% of the color spectrum. Pretty sensible.

(Interestingly, you can still see the mercury emission lines standing out among the rest of the spectrum generated.)

LED

In reefing, “full spectrum” is a different thing altogether.  A “full spectrum” LED light does not restore 90% of the color missing from ordinary white LED’s, for example.  In fact, the term doesn’t really have any inherent color meaning.

Instead, it is used as a term to contrast with either the light given off by ordinary “white light” LEDs or a basic blend of blue and white light LEDs.

The problem with this is that white LED’s are already very full spectrum – there are merely a few weak wavelengths below the greens and above the blues.

img_3237Here’s a sample of the output from my spectrometer with the spectrum provided by a generic 6500K “white” LED bulb:

Unlike the CFL picture above, this looks “full spectrum”.  Very similar to the incandescent photos.  If you have good eyesight or look hard, you can see the dim spot in the spectrum.  It is real, but it’s barely there.

Confusingly, in practice, “full spectrum” reef lights do nothing about missing wavelengths.

What they do, generally speaking, is start with a solid, blue+white LED “reef blend” and add RGB (red, green and blue) LED’s so folks can add a decorator effect where one or more of the colors is exaggerated.

How added RGB is supposed to translate into filling that little blue-green wavelength gap in the photo – and why “full spectrum” is the marketing term they chose to use – is anyone’s guess.

(And please don’t tell anyone about the holes in the spectrum of sunlight or it’ll be deemed not full spectrum too!)

Stay tuned to the Internet Reefer’s Decoder Ring series for more!

Entries in the Internet Reefer’s Decoder Ring are terms you’ll find in the course of online discussion about reefing that make very little sense. In some cases, these terms seem to have been borrowed from another industry where the term did have meaning, but the meaning did not carry over to reefing.

“AC and DC Pumps” – Internet Reefer’s Decoder Ring

By Steve Frick

They’re not as different as you might think!

Reef aquarium caretakers tend to obsess over flow. We use pumps to pull water through our sumps. We put in powerheads and wavemakers all in an effort to push water around. We use pumps with aerators to run skimmers. Even though we have many different applications almost all our aquarium motors work the same way. If you don’t know how your motor works, I want to help with that. Continue reading ““AC and DC Pumps” – Internet Reefer’s Decoder Ring”

Spectrometer

 

This is my Project STAR spectrometer.  It was very inexpensive.

img_3218
The Project STAR spectrometer. Clockwise from the top-left, the long, curved feature is the housing for the graduated scale; next to it is the small light-intake port; at the bottom-edge is the whitish diffraction grating which is just above, or in front of, the eyepiece.

I  use it for examining the color of different lights inside and outside.  (Don’t look directly at the sun through this device – or anything else!)

It works by taking in light via the small opening at the upper-right.

The light bounces off the diffraction grating at the bottom of the photo.

It then spreads out over the graduated scale, which is inside the curved feature at the top of the photo.

I view the scale through the eyepiece that’s at the bottom of the photo.

I don’t get a histogram showing relative wavelength intensity, but it’s really easy to see what wavelengths are strong or weak, or which ones are missing.

I love having this!

 

 

 

 

spectrometer_output
View through the eyepiece of a Project STAR spectrometer. The light is from a 48″ Phillips 6,500K T12 lamp.
spectrometer_light_intakes
The Project STAR spectrometer. Clockwise from the top-left, the long, curved feature is the housing for the graduated scale; next to it is the small light-intake port; at the bottom-edge is the whitish diffraction grating which is just above, or in front of, the eyepiece.
spectrometer_intake_port
The Project STAR spectrometer. Clockwise from the top-left, the long, curved feature is the housing for the graduated scale; next to it is the small light-intake port; at the bottom-edge is the whitish diffraction grating which is just above, or in front of, the eyepiece.
spectrometer_backlight_port
The Project STAR spectrometer. Clockwise from the top-left, the long, curved feature is the housing for the graduated scale; next to it is the small light-intake port; at the bottom-edge is the whitish diffraction grating which is just above, or in front of, the eyepiece.
spectrometer_refguide
The Project STAR spectrometer. Clockwise from the top-left, the long, curved feature is the housing for the graduated scale; next to it is the small light-intake port; at the bottom-edge is the whitish diffraction grating which is just above, or in front of, the eyepiece.