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    What is an LED?

    Reflect

    Stephen P. Clark Government Center

    Miami, Florida, USA

    All Color Kinetics lighting solutions are based on LED technology. Why?

     

    Because LED lighting solutions are highly efficient, long lasting, environmentally friendly and inherently controllable — enabling amazingly creative lighting implementations around the world. That's why lighting professionals are using our LED luminaires for a wide range of interior and exterior applications — leveraging the remarkable flexibility of LED technology to explore new opportunities and achieve their creative visions.

    A closer look at LEDs

     

    When we take a look at the underlying technology that enables LED lighting, we see why it's so long-lasting, reliable, and flexible. An LED has a simple and strong structure. The beauty of this structure is that it's designed to be versatile, allowing for assembly into many different shapes. The light-emitting semiconductor material determines the LED's color, so the number of colors is infinite.

    As indicated by its full name — Light Emitting Diode — an LED is a diode that emits light. A diode is a device that allows current to flow in only one direction. Almost any two conductive materials will form a diode when placed in contact with each other — with a single p-n semiconductor junction between them. To create an LED, the n-type material is negatively charged, while the p-type material is positively charged. The atoms in the n-type material have extra electrons, while the atoms in the p-type material have electron holes — electrons missing from their outer rings.

     

    Applying electrical current to the diode pushes the atoms in both materials toward the junction area. When they get close to each other, the n-type atoms donate their extra electrons to the p-type atoms, which accept them. When extra electrons in the n-type material fall into the holes in the p-type material, they release energy in the form of photons — the basic units of electromagnetic radiation.

     

    All diodes release photons, but not all diodes emit light — just light-emitting diodes. The material in an LED is selected so that the wavelength of the released photons falls within the visible portion of the light spectrum. Different materials produce photons at different wavelengths, which appear as light of different colors.

    LED Diagram

    LED Anatomy
     

    The two basic types of LEDs are indicator-type LEDs and illuminator-type LEDs. Indicator-type LEDs are usually inexpensive, low-power LEDs suitable for use only as indicator lights in panel displays and electronic devices, or instrument illumination in cars and computers. Illuminator-type LEDs are durable, high-power devices capable of providing illumination. All illuminator-type LEDs share the same basic structure. They consist of a semiconductor chip (or die), a substrate that supports the die, contacts to apply power, bond wire to connect the contacts to the die, a heat sink, lens, and outer casing.
    LED Anatomy

     

     

    Illuminator type LED

    How LEDs Produce Different Colors


    LEDs produce different colors by using various materials which produce photons at different wavelengths. Those individual wavelengths appear as light of different colors.

     

    LEDs use materials that can handle the necessary levels of electricity, heat, and humidity. High-brightness red and amber LEDs use the aluminum indium gallium phosphide (AlInGaP) material system. Blue, green and cyan LEDs use the indium gallium nitride (InGaN) system.

     

    Together, AlInGaP and InGaN cover almost the entire light spectrum, with a gap at green-yellow and yellow. One method of achieving a larger spectrum of colors is to mix different colors of LEDs in the same device.

     

    Combining red, green, and blue LEDs in a single LED device, such as a lighting fixture or multi-chip LED, and controlling their relative intensities can produce millions of colors. Additionally combining red, green, and blue in equal amounts produces white light.

    Additive Light

    LED Luminaire Anatomy

     

    To be used for illumination, LEDs must be integrated into luminaires that incorporate optics, LED drivers, power supplies, and thermal management. Well-designed LED luminaires integrate all of these critical components into the luminaire itself.

    Blast gen 4

    RGB version of ColorBlast Powercore gen4

    What are the advantages of LEDs?

     

    LEDs offer a variety of advantages to lighting professionals and ultimate beneficiaries of LED lighting systems — from creative individuals to innovative businesses to visionary cities and countries:

     

    • High-levels of brightness and intensity — LEDs generate high lumen output, ensuring brightness of white and color light.
    • Exceptional range — Color, dynamic color, and tunable white-light LED luminaires can produce millions of colors or color temperature ranges — extremely accurately — without gels or filters.
    • Energy-efficiency — LED lighting can be 5x more energy-efficient than incandescent and halogen sources — cutting costs while lowering environmental impact.
    • Low-voltage and current requirements — LED lighting systems offer simple, flexible installation and use.
    • Low radiated heat — Since LEDs don't emit infrared radiation, they can be installed in heat-sensitive areas, near people and materials, and in small spaces where collected heat might be dangerous.
    • High reliability — LEDs can operate in colder temperatures and withstand impact and vibrations, making them suitable for extreme environments or areas that are difficult to access. LEDs have no moving parts of filaments that can break or fail.
    • No UV rays or infrared radiation — Because LEDs do not emit harmful UV rays that can degrade materials or fade paints and dyes, they're ideal for use in retail stores, museums, and art galleries.
    • Long source life — LEDs offer a significantly longer useful life than conventional light sources, which reduces the cost an inconvenience of maintenance and replacement.
    • Easy control — LEDs can be digitally (and automatically) controlled for maximum efficiency and flexibility.

    What do all these advantages mean?

    Over the past decade, LED technology has advanced rapidly as demand grew and innovation improved manufacturing methods and LED-related technologies. The once-humble LED (used for indicator lights and other lowly applications) is now the preferred light source for high-profile and large-scale lighting projects. And today's lighting professionals are exploring a remarkable new frontier opened up by LED lighting — and Color Kinetics.

     

    Visit the LED Lighting Showcase to see hundreds of other installations, from small to complex, that all benefit from the many advantages of LED lighting.

    Empire State Building

    New York City, New York, USA

    At the forefront of LED lighting innovation

     

    From tunable white to dynamic color, Color Kinetics LED luminaires now illuminate the world’s most iconic buildings, bridges, and other landmarks – as well as retail shops, television studios, theater and concert stages, hotels, casinos, hospitals, restaurants, celebrity-filled nightclubs, and much more. And we provide all the related solutions and technologies that enable and optimize innovative LED lighting – from thermal management, binning, optics, and color consistency to high-efficiency LED drivers and advanced power components.