Here is a short excerpt regarding "secondary optics"
For simplicity’s sake, if a 100 lumen will produce 100 lumens of light at the center and a measurement taken 25 degrees from its central axis, the output of the LED will appear to drop to only 80 lumens. Continuing on the path away from the center axis a measurement taken 45 degrees off axis will yield only 40 lumens, and so on, until at 60 degrees, only 10 lumens or so are emitted.
Now that we have a better understanding of the primary optic, let’s delve into secondary optics. The secondary optic are separate components that are usually made from optical-grade acrylic or polycarbonate mounted over the primary to help further shape the beam of light. The purpose of the secondary optic is to increase the relative luminous intensity. An example Littlejohn uses is the Fraen 8 degree optic that can actually increase the intensity of the LED 27 times.
“2,700 lumens out of a 100 lumen LED sounds great, right?,” notes Littlejohn. “Not so fast. All of this extra intensity is still only achieved directly under the central axis of the LED. In the case of a narrow optic, there is a SEVERE drop off in light intensity only a few degrees from the central axis. A narrow optic creates a “pencil” of high intensity light, and almost no light is emitted outside of this very narrow beam.”
The numbers sound incredible but in your typical aquarium lighting application the light would have to be mounted so high above the tank to get any usable spread off the LEDs making them unusable from a practical standpoint. There are some more practical secondary optics for use in the hobby, Fraen wide beam or the Ledil Rocket W for example, that do increase the light output of the LED but at a much smaller scale. The Fraen wide optic *increases output 2.4 times and directs it into a 58-degree come.
“Besides the obvious advantage of achieving more light from the same number of LEDs, for deeper tanks, the addition of a secondary optic will greatly benefit the light penetration through the water column,” he adds. “In my opinion, for tanks up to 24-inches deep, LEDs do not require a secondary optic to reach the bottom with a significant amount of light energy intact. For tanks over 24-inces deep, the extra light penetration provided by the secondary optic overrides enough of their disadvantages to warrant their use.”
So why aren’t optics used everywhere then? According to Littlejohn, there are disadvantages of secondary optics with some of them being pretty significant:
They can be expensive. They typically add between 25%-50% to the cost of each LED.
With few exceptions, they create a harsh transition from bright to dark. In other words, the “edges” of the cone-shaped light pattern can be very distinct. This creates a “flashlight effect”, where everything within the light beam is very bright, and everything just outside the beam is very dark.
They hinder color blending. Since most of us like the actinic effect of all blue lighting, and since most of us prefer a cooler color than the coolest white LED available, we must use a combination of royal blue and white LEDs in our systems. When secondary optics are added, you may see obvious white and blue spots in your tank. This effect can be reduced by reducing the center to center spacing of each LED, so that the cones effectively overlap, but it may still be very apparent as our corals grow towards the top of the tank. Also, our rock formations and corals cast shadows, which may be distractingly blue or white under secondary optics.
Hope you found some useful info in there
