LEDs, or Light-Emitting Diodes, have revolutionised the world of lighting over the past six decades. Originally introduced as simple indicator lights in electronic devices, LEDs have evolved into powerful lighting solutions that dominate various applications. In this comprehensive guide, we’ll explore the fascinating history of LED technology, understand how LEDs work, delve into their construction, explore sub-types, and discuss supporting components. Additionally, we’ll touch on the diverse applications of LEDs beyond lighting, highlighting their potential in the realm of communication.
The roots of LED technology extend back to the discovery of electroluminescence in 1907 by H.J. Round, setting the stage for subsequent breakthroughs.Oleg Losev, a Russian inventor, invented the first LED in 1927. However, practical LED usage became possible in 1962 when James R. Board and Gary Pittman of Texas Instruments discovered near-infrared light emission. This led to the patenting of the “Semiconductor Radiant Diode,” marking the birth of commercially viable LEDs.
Hewlett-Packard (HP) furthered LED development in collaboration with the Monsanto Company. In 1968, HP introduced LED displays, and Monsanto released LED indicator lamps, marking the commercial debut of LED products. Over the decades, LEDs continually improved in terms of colour range, durability, longevity, and overall performance. The introduction of High-power LEDs (HP-LEDs) over the past decade propelled LEDs to dominance in various lighting applications.
Understanding how LEDs work involves grasping the unique role of semiconductors. Unlike traditional lighting sources relying on heat or chemical reactions, LEDs use semiconductors for illumination. Semiconductors, like aluminium-gallium-arsenide (AlGaAs), have impurities added through a process called doping to facilitate the flow of electrons.
The basic LED construction involves an N-type material (extra electrons) and a P-type material (extra holes) bonded together, creating a diode. With no voltage, a depletion zone forms between the N and P-type materials, restoring the semiconductor to its insulating state. When a voltage is applied, electrons move across the diode, generating light through the interaction with holes.
The light produced is a result of photons being released as electrons move from one orbital to another within an atom. This orbital change’s distance determines the energy released and, consequently, the frequency of light. LED lighting offers a wide range of colour temperature options, providing flexibility and versatility compared to traditional lighting.
LEDs, or Light Emitting Diodes, are pretty cool because they’re not just tiny bulbs; they’re like mini superheroes working together to give us light. Let’s break down their construction:
Think of the lead frame as the central command for the LED. It has two parts: the anvil (the negative side) and the post (the positive side), and they talk to each other through a special wire bond. It’s like they’re best friends, but they don’t actually touch each other.
Picture the reflective cavity as a shiny cape around the LED’s main part, the semiconductor die. This cape helps direct the light outward, making sure it goes where it’s supposed to—like a superhero with a perfectly reflective costume.
Now, imagine a super tiny wire that runs from the positive post to the centre of the semiconductor die. This little wire is like a messenger, carrying the electric current and making sure everything stays connected. It’s like the power line for our LED superhero.
Finally, the epoxy lens or case is like the armour that protects our superhero LED. It keeps all the components in place and makes sure they don’t go flying off. This armour is tough—it can handle impacts and vibrations, keeping our LED safe and stable.
So, in simpler terms, the lead frame sets the stage, the reflective cavity guides the light, the wire bond delivers the power, and the epoxy lens or case protects and holds everything together. All these parts work together to create the magic of LED lights, making them not just bright, but also durable and reliable. It’s like a team of tiny superheroes working behind the scenes to light up our world!
Light-emitting diodes, or LEDs, are cool and energy-efficient sources of light. While they all work on the same basic principle, there are some cool variations to explore. Let’s dive into the three main types: Standard Diode, SMD LED (Surface Mount Device), and COB LED (Chip on Board).
Standard Diode LED: The Basics
SMD LED (Surface Mount Device): The Compact Marvels
COB LED (Chip on Board): The Powerhouse
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Given LEDs’ low voltage requirements (3 to 3.6 volts), household power (120 to 240 volts) and alternating current (AC) are unsuitable. Conversion circuitry is necessary, comprising components like an input fuse, input transient protection, bridge rectifier, capacitor smoothing, DC-DC converter, and heat sink. These components work together to ensure LEDs receive the appropriate voltage and current, preventing damage.
LEDs extend beyond lighting applications, finding a unique role in communication. Their ability to cycle on and off rapidly enables high data bandwidth, making them effective for wireless communication. This principle aligns with how fibre optic cables operate, transmitting information via light. While this communication method has advantages, it requires a clear field of view, as LED signals cannot penetrate barriers like walls.
The journey of LED technology from its humble beginnings to its current dominance in lighting and communication is truly remarkable. Understanding the history, working principles, construction, sub-types, and supporting components provides insights into the versatility and potential of LEDs. As technology continues to advance, the future of LEDs remains bright, promising continued innovation and widespread applications.
LED stands for Light-Emitting Diode. Originally used as indicator lights in electronic devices, LEDs have transformed into powerful lighting solutions. Over the years, advancements in colour range, durability, and performance have made LEDs dominant in various applications.
In 1907, H.J. Round discovered electroluminescence, laying the foundation for LEDs. Oleg Losev created the first LED in 1927, but practical usage began in 1962 when James R. Board and Gary Pittman of Texas Instruments patented the 'Semiconductor Radiant Diode.' HP and Monsanto furthered LED development in 1968.
LEDs use semiconductors like aluminium-gallium-arsenide for illumination. The basic construction involves an N-type material (extra electrons) and a P-type material (extra holes) forming a diode. When voltage is applied, electrons move, generating light through interaction with holes. This process is more efficient and durable compared to traditional lighting.
LED construction includes the lead frame (anvil and post), reflective cavity, wire bond, and epoxy lens/case. The lead frame serves as the central command, the reflective cavity directs light, the wire bond delivers power, and the epoxy lens protects and stabilizes the LED.
There are three main types: Standard Diode LED (basic and efficient), SMD LED (compact and space-saving, often used in gadgets), and COB LED (chip-on-board, powerful and suitable for spotlights). Each type has unique characteristics and applications.