Whether number plate recognition at the gate of a company’s car park, video cameras in banks, wide-range surveillance of parking lots, industrial sites or airports – Closed Circuit Television (CCTV) keeps a close watch. Many solutions add infrared light to enhance the quality of images recorded in the dark. It was the development of powerful infrared LED (IRED) which made many of these applications economical. Meanwhile, manufacturers can choose from a wide range of IRED for illumination applications. The product line ranges from devices of medium power to multi-chip modules supplying several Watt in continuous wave operation. IRED in the medium power range
Picture 1: Systems for number plate recognition take several photos per second
Typical examples of the medium power range are Power Topled with highly efficient emitter chips in thin-film technology. For more narrow emission angles of +/-15° and +/-25° are compact SMT devices with integrated lenses available. In continuous wave operation a current of 100 mA is admissible. Also in pulsed operation, Power Topled facilitate compact and powerful illumination units. They are particularly well suited for applications with a lower duty-cycle, e.g. Automatic Number Plate Recognition (ANPR) at gates, where only a few pictures per second are taken. Pulsed operation also facilitates synchronizing illumination and exposure time, thus reducing power consumption. Combined with the Nanostack technology for 850nm emitters – another recent development by Osram Opto Semiconductors, which realizes two light-generating pn-junctions per chip – Power Topled yield a record-breaking power. A Power Topled with Nanostack supplies almost double the amount of light and yields an optical power output of 560 mW at 0.7 A in pulsed operation. Thus not only the number of IRED per illumination unit drops, but designers can also increase the brightness of existing Power Topled systems without difficulty by using identical IRED devices with Nanostack.
Powerful IRED For developing high-power IRED, OSRAM Opto Semiconductors could benefit from its LED illumination technologies. The result is a large variety of devices featuring an optical power in the 1-Watt range. The IRED are based on chips with a size of 1mm˛ in modern Surface Mount Technology (SMT) packages. Devices with one Nanostack-chip only supply an optical power of almost 1 Watt. Since chips in thin-film technology emit almost all their light on the top-surface, multi-chip devices like the OSTAR Lighting yield a power of several Watt.
Picture 2: A broad range of lenses is available for many high-power IRED.
The infrared Platinum Dragon more and more replaces the conventional cascades of radial IRED. With its extremely low thermal resistance the device is particularly well suited for continuous operation in which the 850nm version supplies more than half a Watt optical power at 1 A. A range of several 10 meters can be reached using the classical Dragon design without lens. For longer distances, a large variety of lenses is available . Dragon IRED are also available in Nanostack technology, supplying almost double the power. It allows designers to easily upgrade existing systems or to reduce the number of components. In case the size of the system is crucial, the infrared Oslon is a suitable alternative. At present it is the smallest IRED in the category of more than 1W optical power. This device produces a +/-45° beam, therefore coupling more light into external optics. Oslon is also a suitable alternative to Power Topled designs with external optics. For long-distance systems, the 6-Chip-IRED OSTAR Lighting is a compact and elegant solution, supplying 3.5 W light at 1 A in continuous wave operation.
Picture 3: IRED with one or more Watt power: Platinum Dragon, OSTAR Lighting and Oslon
Click on the link below to check out the collection of Design Articles, Case Studies, Product How-To articles,... related to LEDs that have been published on Smart Energy Designline.
Check back frequently. The list will be updated as new articles arrive.
David Patterson, known for his pioneering research that led to RAID, clusters and more, is part of a team at UC Berkeley that recently made its RISC-V processor architecture an open source hardware offering. We talk with Patterson and one of his colleagues behind the effort about the opportunities they see, what new kinds of designs they hope to enable and what it means for today’s commercial processor giants such as Intel, ARM and Imagination Technologies.