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Wavien, Inc. Licensed Premien Recycling LED Technology to TaYih Industrial Co., Ltd. for Flashlights
LIGHTimes News Staff
May 11, 2010...Wavien of Valencia, California USA and TaYih Industrial Company of Taiwan report that Ta Yih Industrial has licensed Wavien's Premien LED Recycling technology for use in ultra-narrow beam, high-output tactical LED flashlights. Wavien contends that its new design produces over 80% increase in output intensity compared to standard technology.
Wavien' claims that its Premien Recycling Collar is a very low-cost component that captures the wasted light in conventional LED lighting designs, recycles the light, and directs it back into the output beam.
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NNCrystal US Announces New Color-Free, Heavy-Metal Free Nanophosphor Technology
LIGHTimes News Staff
May 6, 2010...NNCrystal US Corporation will be unveiling new phosphor technology at Lightfair International 2010.
The technology is the company's Qshift Coral* and Qshift Lucid* colloidal phosphor.
NNCrystal, a wholly owned subsidiary of Hangzhou Najing Technology company, and an exclusive licensee of advanced materials synthesis technology and know-how from NN-Labs LLC, produces colloidal nanocrytals (quantum dots).
The company's Qshift Coral technology uses conventional colloidal nanocrystals (quantum dots) to finely tune and precisely control the color of the light output. The company claims that its Qshift Coral technology makes the lighting warmer and improves light quality while reducing its energy consumption for the same lumen output compared with traditional phosphor-based warm white lighting.
The company's other technology Qshift Lucid is a clear, quantum dot-based color converter that is a not have heavy metal. The company says it is alternative for existing rare-earth phosphor materials. The company claims that it offers superior optical performance and greater design flexibility while eliminating the use of toxic materials such as cadmium and mercury.
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Philips Lumileds Explains Method of Assessing LED Array “Lifetime” Performance in New White Paper
May 6, 2010...Philips has published a new white paper
entitled "Evaluating the Lifetime Behavior of LED Systems" that Philips says provides a methodology for evaluating how arrays of LEDs behave over time. The methodology also explains how LED luminaire manufacturers can make business decisions such as warranty commitments.
While many manufacturers have substituted the lifetime of a single LED to be the lifetime of a luminaire, the paper goes beyond simple lumen maintenance data which describes how a single LED behaves and addresses the more common lighting system which uses multiple LEDs in a wide variety of use conditions.
Philips asserts that a more accurate estimation of an LED luminaire’s usable life is determined by a manufacturer’s determination of expected lumen maintenance of the multiple LEDs and by the actual usable life of the many components included in the system.
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Teridian, Synapse Wireless and California Eastern Laboratories Showcase Energy Measurement Design Solution
SSLDesign News Staff
May 6, 2010...Teridian Semiconductor, Synapse Wireless and California Eastern Laboratories (CEL) will demonstrate a new design solution for the intelligent wireless control and energy monitoring of LED light fixtures and advanced solid state lighting products in Booth #2428 in the Building Integration Pavilion. The comprehensive solution includes Teridian's 78M661x system-on-chip (SoC), CEL's MeshConnect™ 802.15.4 product line and Synapse's SNAP® network operating system.
Teridian, Synapse and CEL are introducing a comprehensive, plug-and-play solution targeted to manufacturers of LED and advanced solid state lighting products. The solution will measure the use of energy and provide intelligent control for lighting applications in an 802.15.4-based wireless network.
Teridian's 78M661x chip family enables power measurement in a range of applications that include home and building automation networks, appliances, power supplies, HVAC, and communication equipment. Synapse's SNAP is a mesh network operating system that provides embedded intelligence and wireless communication for engineers to design products that require remote monitoring and control, such as LED lighting and energy systems, building automation, asset management and more. CEL's MeshConnect product line, which includes ICs, modules and development kits, provides a fully integrated transceiver solution for IEEE 802.15.4/ZigBee networks that are ideal for voice, LED lighting control, solar/wind power, HVAC control, security systems, simple cable replacement, low-resolution video, asset location and AMR/AMI.
"CEL is excited about expanding its existing partnership with Synapse to now include a collaborative effort with Teridian. Each of the three partners provides an important component for intelligent wireless control and energy management for LED lighting and other solid state lighting applications," said Rich Howell, director of Business Development for CEL.
In April, Teridian launched the 78M6618, the second in the family of energy measurement solutions for the home and enterprise. Teridian's energy measurement SoCs boast accuracy of better than +/-0.5 percent over a 2000:1 dynamic range with self calibration. The end result is the ability to measure even the smallest amounts of energy.
"We designed the 78M661x family to be a complete, ready-to-use embedded measurement solution," said Jay Cormier, Teridian vice president and general manager, Energy Measurement & Communications. "The outcome of the collaboration between Teridian, Synapse and CEL is the complete integration of electronic components and software into a reliable, cost-effective solution that enables products to come to market faster."
"Teridian is a natural extension to our partnership with CEL," said Wade Patterson, Synapse CEO. "Now the SNAP network operating system and CEL's MeshConnect modules can combine with the outstanding performance of the Teridian embedded energy monitoring solution to provide exceptional value and accelerated time to revenue for our solid state lighting customers."
The new design solution integrating the three technologies from Teridan, Synapse, and CEL will be showcased next week at Lightfair International 2010 in Las Vegas from May 12-14 at booth #2428 in the Building Integration Pavilion on the show floor.
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Driving down the costs - Part 1
Tom Griffiths - Publisher
April 29, 2010...One of the common questions we get from those outside of the "chip head" side of the industry is, "Why don't they just make the LEDs (and/or solar cells) cheaper? It can't be rocket science." Well, actually, part of it is, or nearly so, and others parts are driven by the economics including "economies of scale" that everyone is always so knowledgeable about. Make no mistake, we'll get there, but it is a process of innovation that will follow an evolutionary path, helped along with some occasional breakthroughs. In the first of this two-part commentary, we'll cover what's happening to move those costs down at the bottom and in some detail at the top of the chain, with Part 2 aimed at the middle and fleshing out that view from the top a bit more.
Materials and reactors... It all starts, not surprisingly, at the bottom. For those coming from a higher level of the food chain, the simplest analogy the industry offers is that making semiconductors is like making a pizza. You have a crust, called a substrate, that everything is layered on. Then comes the sauce, which is a blend of just the right main ingredients, and little added "spices" that make it unique to the particulars of the kind of pizza you're making. That sauce is the "epitaxial layers" or simply "epi". In this case, you cook it while you add the secret ingredients that make up the sauce, and what you get at the end is an "epi-wafer". Some of the ingredients manufacturers blend include gallium, indium and arsenic (called "source metals"), along with other ingredients, which are basically vaporized and then showered very precisely over the sapphire or silicon-carbide substrate in big things called epitaxial reactors. The most common of the volume production techniques is to use MOCVD, or metal oxide chemical vapor deposition. Taken one word at a time, the name is actually pretty sensible.
Those machines are not cheap, running probably $1.5M to $2M+ each, nor are they simple. They use a lot of electricity and take a fair amount of time to get the layers just right. The rocket science in the machine itself is how to get exactly the right amount of everything even blended, across the whole substrate, on multiple substrates at a time, to tolerances in the range of hundredths of a millimeter. The objective is uniform coverage that minimizes the "defects" which may be holes, or cracks, or shortage or overages of elements in the material that's supposed to be there. How well you do at this step will set the stage for the overall yield, or "percentage of good devices" you get from a wafer. More is better, since you go to all the trouble, time and expense of getting the materials on there, you want every square millimeter to be useful. The reactors take time to do their job, take time to finish one run and set up for the next, and also need maintenance (as you can imagine, flowing a bunch of hot metals at high pressure take their toll on the equipment). There is also a need to purge out anything that's not part of the formula for any particular run, so changing from one color LED, or efficiency level of a solar cell, to another, takes time to clean the previous formula's leftovers out.
Improvements are happening, and while incremental, they are noticeable. A few years back, at one of our Blue conferences in Taiwan, currently the larger of the "Big 2" when it comes to our world of non-silicon epi-reactors, Aixtron, was sharing the migration path to larger wafer sizes. In the simplest context, edges are useless for putting devices on, and the larger the wafer, the lower the ratio of "useless" edge to "useful" interior. A move from 2-inch to 4-inch, and then 4- to 6-inch wafers can provide a substantial increase in the yield per square millimeter from each run if (big if) you can maintain the uniformity. Veeco has made a big push recently to clearly communicate its intention to drive the fabrication costs, from the substrate through a device ready to packaged, down by a factor of 4 by 2015. According to Jim Jenson, Veeco's VP of Marketing for their MOCVD business, these reactors, and their accessories, currently make up about 50% of the capital expense of an LED fab. Their model K465i, introduced in January, has brought in a new approach to the deposition nozzle (technically, their "uniform flow flange") that has enabled a whole bunch of things to get better all at once. Jensen claims that their customers have seen yield improvements from what has traditionally been in the mid-70% range to something more in the 90's with this update. That represents just a yield-based cost reduction of 20-25%. Yield improvements ripple through the whole LED manufacturing process, as a higher percentage of good devices means that for the same amount of work at each step (such as fabrication of the chips and testing), more LEDs get produced. Changes to the line have also shortened the time it takes to get a new reactor up to speed, with recent results being customers having being able to take delivery of one of the reactors, and fully qualify their process on it in just 2.5 months.
LEDs, the other rocket science... It wasn't that long ago that packaged "lighting quality" LEDs were running at $10 for 100 lumens, or 10-cents per lumen (remember, blue and white weren't commercially available until around 2002/2003). Announcements in the last few months have shown us 2-cents per lumen (Cree), then 1.5-cents (Bridgelux), and most recently less than 1-cent for warm white (Intematix, part of today's news). It's assured that Philips, Osram, Nichia and others out there aren't standing pat at 10-cents per, they just didn't happen to specifically promote the price in the their announcements. That's a factor of 10 decrease in something like 5 years. We'll discuss what's driving that in the next installment of this commentary.
Supporting components... Suffice it to say in Part I here that there's room for improvement in both drivers (which feed and control the LEDs) and power supplies (which feed the drivers). The capable and reliable ones aren't cheap, especially when it comes to the power supplies.
Integrated lamps and luminaires... When do we get a $5 LED lightbulb? Maybe never, but not because it can't be done, but rather because it won't make sense to. At some point, a product becomes "cheap enough" that mass market adoption proceeds simply because it is a better solution than what existed before. One of my continuing favorite examples to evaluate some of what is happening, and what we think will happen in this industry, is the progression of the PC market. Introduced in the early 1980's, they started out as $2000 tools, and $1000 toys. You had to really need one for business at $2000, and most mid-sized or larger companies were doing just fine on the "cost per terminal" with their existing minicomputers. Small businesses had nothing in the way of a computer, and couldn't afford the $50,000 to $100,000 or more for their few employees who would benefit. $2000 for the PC, plus another few thousand for what was likely custom software, was way better than paying an extra accountant $30K a year (back then) to do the math on paper. As the business-level machines came closer to $1000, the 20-50 seat installations began to make sense as well, and massive adoption proceeded. Later, $500 PCs put them in most of our homes, but did you notice, they didn't keep heading on down to $300, or less (other than rare deals, so super-strippers)? The distribution channel (retailers) couldn't make the money they needed at that kind of price, and having PCs in every consumer electronics store drove far more sales than a lower price (by mail order) every would. They hit the value point at $500 and have stayed there, with features and capabilities being added, rather than prices proceeding lower.
We can expect to see much the same approach in LEDs, and interestingly, there's a bit of a challenge picking what that number might be. We'll explore some of what is driving that for replacement lamps ("bulbs") and luminaires in the next installment. (Continue to Part 2)...
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