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Lighting
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Verticle Debuts UV LED Chip on Cu Substrate
LIGHTimes News Staff
May 15, 2013...Verticle, an LED chip maker in Silicon Valley with production in Korea, has come out with a hexagonally shaped UV-LED on a copper substrate that can be driven at high current. The chip employs what the company calls Chemical Chip Separation Technology between the Cu substrate and the GaN-based UV-LED. Verticle points out that despite their numerous advantages UV LEDs tend to have lower optical power due to lower internal quantum efficiency (IQE) compared to blue LEDs.
While improving the IQE of UV epitaxial wafers is a long-term prospect,
Verticle contends that an alternative way to boost the overall output of a UV-LED is to drive
more current into the UV-LEDs, and manage the resulting heat. The company states that heat-related droop is more of an issue in UV-LEDs than in blue, and therefore, the
company reasons, one of the main challenges of UV LEDs is lowering junction temperature.
In order to operate at higher current injection conditions and dissipating heat more efficiently, Verticle’s UV-LED chip is constructed with a copper substrate. As shown in the accompanying image that contains both graphs, Cu base vertical chip’s thermal resistance (Rth) is 2K/W lower than GaN/Si vertical chip. As a result, junction temperature (Tj) of GaN/Cu is lower than GaN/Si. It is noted that the junction temperature difference is 2 degrees C at 350 mA current injection between two chips, however, the difference become larger (6 degrees C) at 1A current injection.
The company points to testing it conducted that shows that a vertical Cu-base UV-LED chip has higher radiant flux than a lateral chip fabricated with same epitaxial wafer. Furthermore, Verticle says that its UV-LED chip on a Cu substrate can be driven at a higher current than other vertical chips constructed with different substrate materials. For example, the company says that Verticle’s GaN/Cu UV-LED chip does not saturate over 1A, while GaN/sapphire UV-LED chip start to saturate after 500mA. This suggests that a GaN/Cu chip has higher heat dissipation capability compared with GaN on other substrates, giving Verticle’s Cu-base UV-LED chip distinct advantages for applications in which high current injection and good thermal properties are required.
Verticle’s hexagonal UV-LED chip’s (45 Mil size) radiant fluxes are measured at 416mW at 350mA current injection, 787mW at 700mA, and 1025mW at 1A for the 392 nm wavelength, respectively. In addition, the company notes that it's hexagonal "Honeycomb" chip shape offers a higher extraction efficiency when packaged with a circular lens as a result of the near circular beam profile.
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Recently Launched EU Project Aims to Commercialize Flexible OLEDs
LIGHTimes News Staff
May 14, 2013...Neuchatel – CSEM has joined a recently launched €11.2 million European initiative to help bring flexible OLEDs to market. The project, known as Flex-o-Fab, will create a pilot-scale manufacturing line for flexible OLEDs and use it to develop reliable production processes. The project is funded through the EU’s 7th Framework Program.
The first OLED products using rigid glass tiles are already on the market. However, OLEDs have also been produced and demonstrated (at least in the lab) on plastic films to create flexible light sources. It is expected that eventually, Flexible OLEDs could be produced at lower cost than glass-based OLEDs. Flexible OLEDs could be embedded into most kinds of everyday objects.
While flexible OLEDs have been successfully demonstrated in the laboratory scale by many groups (including CSEM), the Flex-o-Fab project aims to take them from lab to fab through the development of reliable processes for manufacturing OLEDs on plastic foils. The project will reportedly set up a modular, integrated pilot production line and associated manufacturing chain to achieve this. The Flex-o-Fab project will migrate existing sheet-to-sheet processes to roll-to-roll (R2R) production for a further reduction of costs and to enable high-volume production. The project will focus on lighting applications. The project participants hope to have a proof-of-concept pilot line operational by September 2015.
In collaboration with a range of partners, CSEM will contribute to develop new bonding-debonding solutions to facilitate reliable manufacturing of flexible OLEDs based on “foil on carrier” concept. The solutions developed will be compatible with the complete OLED processing flow. This will eventually provide the consortium with a reliable and roll-to-roll compatible handling method for OLED processing on polymer foils.
Osram Opto Semiconductors Joins Project to Improve Functionality of Adaptive Forward Lighting Headlamps
LIGHTimes News Staff
May 14, 2013...Osram Opto Semiconductors is coordinating a project to develop the framework for adaptive forward lighting headlamps. The joint project, which is part of the “Photonics Research Germany” program, is in the “Integrated Microphotonics” Field of the German Federal Ministry of Education and Research (FMER).The goal of the project is to develop develop the technical framework for a new class of energy-efficient LED headlamps with supplementary traffic safety functions.
Adaptive forward lighting, which is glare-free camera-controlled headlamps that react instantly, will help drivers even more in the future thanks to additional intelligent functions. This functionality requires the integration of microelectronics and optoelectronics. Osram is contributing its expertise as the project coordinator and market leader in LED lighting for the automotive sector.
This framework can provide the basis for adaptive forward lighting systems (AFS) that will offer drivers and passengers increased safety. The design of adaptive lighting will come for example from glare-free high-beam, and low-beam that adapts to the speed of the vehicle. At high speed the range of the light is automatically increased. In city traffic, a wider distribution of the light can help illuminate more of the sidewalk and margins. These functions will be fully electronic so there is no need for mechanical actuators.
Osram’s Specialty Lighting division will be developing new electronic control gear for controlling the LED headlamp system. The Fraunhofer Institute for Reliability and Microintegration (IZM) is contributing its expertise in interconnection technology and materials, and Infineon Technologies is offering its experience in automotive electronics and LED drivers. The automotive industry supplier and lighting specialist HELLA KGaA Hueck & Co. will develop the entire optical system for the LED module and the headlamps, and will build prototypes. Daimler, an engineering company in the automotive sector, will carry out the vehicle tests.
Project coordinator Stefan Grötsch is responsible for LED applications in automotive lighting at Osram Opto Semiconductors. Grötsch said, “We have brought together major-league players in their respective sectors, assembling a wealth of expertise for this pioneering project around one table.” The project is being sponsored by the German Federal Ministry of Education and Research (FMER) under reference number 13N12510 and is scheduled to run from February 1, 2013 to January 31, 2016.
Research and Markets Company, TechNavio Predicts Market for Packaged GaN LEDs to Grow Through 2016
LIGHTimes News Staff
May 14, 2013...TechNavio, a market analysis firm owned by Research and Markets, predicts
that Global Packaged GaN LED market will grow at a CAGR of 12.1 percent during
2012-2016. According to Technavio, one of the key contributors to this market
growth is the increased adoption of packaged GaN LEDs in the lighting segment.
Packaged GaN LEDs have been getting smaller, and more powerful. So fewer LEDs
are needed to produce the same light output as older LEDs. However, the company
says that the current oversupply of packaged GaN LEDs could pose a challenge to
the growth of this market.
According to TechNavio, key vendors in this market include Cree Inc.,
Epistar Corp., Osram Opto-semiconductors GmbH and Samsung Electronics Co. Ltd.
Other vendors mentioned in the report are NXP Semiconductors N.V, Soraa Inc.,
and Seoul Semiconductor Co. Ltd An analyst from TechNavio's Hardware team said, ''One of the major
trends in the Global Packaged GaN LED market is rapid technological advances.
The continuous technological advancement has increased the number of
applications in which packaged GaN LEDs are used. Furthermore, these advances
have enabled packaged GaN LED vendors to deliver high-quality output for
customers. The technological advancement has resulted in the development of
advanced, compact, and power-efficient packaged GaN LEDs that can be deployed
in a wide range of applications.''
Vishay Intertechnology Introduces 850 nm and 940 nm IR Emitters and Silicon PIN Photodiode for Infrared Touch Panels
LIGHTimes News Staff
May 14, 2013...Vishay Intertechnology, Inc. of Malvern, Pennsylvania USA, has introduced two new high-speed 850 nm and 940 nm infrared emitters and a package-matched high-speed silicon PIN photodiode with high radiant sensitivity from 780 nm to 1050 nm. The VSMG10850, VSMB10940, and VEMD10940F offer an ultra-wide ± 75° angle of half intensity in a compact side-view surface-mount package measuring 3 mm by 2 mm and a height of only 1 mm.
The IR LEDs come in untinted plastic packages and provide high radiant intensity of 1 mW/sr typical at 20 mA, which Vishay claims is up to 33% higher than comparable devices on the market.
The IR LEDs have fast switching times of 15 ns. The 940 nm VSMB10940 emitter features GaAIAs multi quantum well technology and a low forward voltage of 1.3 V typical. The 850 nm VSMG10850 emitter offers the company's GaAIAs double hetero technology and has a forward voltage of 1.4 V.
The VEMD10940F photodiode features a daylight blocking filter matched with 830 nm to 950 nm IR emitters, including the VSMG10850 and VSMB10940. The device offers a reverse light current of 3 µA, low dark current of 1 nA, 920 nm wavelength of peak sensitivity, and a low 0.1 %/K temperature coefficient of light current.
The low profiles VSMG10850, VSMB10940, and VEMD10940F are optimized for use in IR touch panels for devices such as printer displays, eBook readers, smartphones, tablets, ultrabooks, and GPS units.
The devices provide a floor life of 168 hours and moisture sensitivity level (MSL) of 3 according to J-STD-020. The emitters and photodiode support lead (Pb)-free reflow soldering and conform to Vishay's "Green" standards.
Samples and production quantities of the new IR emitters and photodiode are available now, with lead times of six to eight weeks. Pricing for U.S. delivery in 5,000-piece quantities starts at $0.06 per piece for the VSMB10940, $0.08 per piece for the VSMG10850, and $0.06 per piece for the VEMD10940F.
Government Subsidies Decrease for China LED Chip Makers; Taiwan LED Chip Makers to Benefit from Reduced Price Pressure
LIGHTimes News Staff
May 9, 2013...China's LED chip makers have seen a large decrease in government subsidies
this year, according to an article by Peoples
Daily. Numerous companies have relied on the subsidies to offer lower
prices. The market is currently facing overcapacity.
Companies such as Sanan Optoelectronics which produces LED die and can offer
it at very low prices will be hardest hit. Other companies such as Elec-Tech
which produces LED production equipment will also suffer from the reduced
funding. Peoples Daily cited 21cbh.cn, which said that Sanan Optoelectronics received
government subsidies totaling 328 million yuan ($53.3 million) in 2012, 805
million yuan in 2011 and 2.53 million yuan in 2010. These subsidy amounts
reportedly accounted for 40.5 percent, 85 percent and 60.4 percent of its net
profits respectively during these years. According to People's Daily, Elec-Tech would likely have suffered
losses in 2010 and 2012 if it weren't for subsidies. One result of the reduced subsidies is that the pace of LED price drops is
expected to slow down. Taiwan-based LED chip makers noted that prices for LEDs
have fallen about 35 percent in the last two years, according to Digitimes. Sanan, a leader in China's LED industry, has reportedly chosen to be less
aggressive in its price cuts, likely because of the reduced subsidies. Digitimes noted that with prices stabilizing, TV backlighting
demand returning and the lighting market growing, Taiwan-based firms are likely
to see strong performance in the second and third quarter of 2013.
Our news features are reported
by the LIGHTimes staff writers.
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The Dream Bulb That LEDs Will Enable
Tom Griffiths - Publisher
May 16, 2013...As a result of a midnight premier of Star Trek - Into Darkness last night (this morning, technically), the forward-looking technology thoughts are flowing judiciously. Apparently I walked into the conclusion of the discussion on when and where the movie was happening, only to catch the part where I was being asked if I wanted to see it "when it opens". Lacking the context they thought I had overheard, I was inextricably offered the opportunity to earn the cool dad title (and it was indeed earned, while waiting to get in, as I showed the group of late teen to 20-somethings some tricks with the polarized lenses in the 3-D glasses). The movie is a must-see, by the way, for anyone clued-in to the backstory elements from the "Original" Star Trek movies' reality/timeline, of which this is a slight alternate. I did have to overlook what looked like a current generation swoopy T8 fluorescent fixture stuttering in the engineering section after the warp core was damaged in the treacherous attack... The solid state lighting in the 23rd century won't be re-striking as a result of the jolt, thank you very much. So from there I've been led to ponder what our LED "light bulb" should be doing for us in the future (and not the far future at that). The answer is "lots of stuff".
First, it will be important to set aside the fact that LED lighting visionaries insist that we'll simply "do light differently" and that we need to break out of the whole LED light bulb mentality. No doubt that is true, but no one is beaming our legacy technology away, so "differently" is more a matter of time, and it could be validly argued, a long time before light bulbs have been replaced by "something else" in both our homes and offices. We personally own table lamps that are probably 50 years old, and they aren't antiques, they are just "the lamps by the couch". Fresher ones in the house date back 15-20 years, with the newest fixtures (front porch, back porch) being the youngsters at 5 or so years. I believe the ceiling fan in our bedroom has been continuously spinning for 7 years, other than a 1 day period when it moved from the rental we installed it in over to the house we're in now. The point is that our indoor fixtures really don't wear out, and all are fresh enough to allow me to spin in at least one last bulb. If that has a nominal 25,000 hour life, I figure it's not going to be "driven" to change for the next 20 years or so (based on our 3 hours per night average use). Heck, given that the oldest floor lamp now has a Philips Hue installed, and with a recent iPhone update we have at least 3 devices in arms reach and available to control it, we actually are leaving the power switch on, greatly reducing the next most likely failure point. While our sockets will be disappearing at some point, that point will likely be a long time from now. Fluorescent sockets in many commercial spaces, especially T5's and T8's, will be similarly sticky, although the addition of more granular control capabilities that LED (aka "digital") lighting enables will provide retrofit opportunities ahead of simply waiting for the next interior renovation.
Residential markets - What do we want that bulb to do? Low power consumption, bright enough, good quality light, and useful for the variety of sockets that we have scattered around the house. That means dimmable on the ubiquitous TRIAC dimmer for the ceiling, as well as useful in a 3-way socket found in many table lamps. And there doesn't seem to be any reason that they can't also be fun, so something along the lines of a dimmable RGB-W configuration that also takes clues from the 3-way socket... and it communicates... to more than just "the controller" but with the big, wide world. There are examples of all the features out there now, most notably Philips aforementioned Hue for that communications and fun. Recent fun additions include "geo-fencing" so that your smartphone can trigger lights on or off as the residents come and go from the house, as well as support for If-This-Then-That (IFTT) to trigger events based on other events (our recent coverage here). Stock price hits a target, flash the office lights. Team wins, paint the house lighting the team colors). Cree, and probably a few lesser-known others, have recently hit that dimmable white part at a useful $10-ish price point, and at LIGHTFAIR we saw those 3-way and 75w to 100w replacement category "bright enough" introductions from Switch. Are we being unrealistic to envision a future that brings them all together into one affordable LED replacement lamp? That would be like expecting your cell phone to also take pictures, record movies, let you video conference, surf the web, watch movies and let you listen to music. I mean to be big dreamers, maybe we should also expect the phone to provide maps, point to point navigation as well as control your lights at home. So no, it's not unrealistic to expect the residential light bulb to handle the light, fun, dim, 3-way and communication, as well as adding in daylight or ambient light compensation and even other environmental sensing. My good old iPhone 3 had a stack of sensors and functions that were just waiting for apps to bring them to life, and there is no doubt our bulbs can and will do the same.
Commercial markets - Heavy on sensing, light on fun. It seems doubtful that the property operators are going to be very keen on creating the disco effect as the lighting color pulses to the music it "hears" through its microphone (just got that app for the Hue at home... hilarious fun to instigate a pillow fight with strobe mode on). But the tenants will be keen on the increased productivity that comes from more "effective" light. Whether it is better to be maintaining a constant ambient color temperature in spite of changing daylight, or modify the CCT as well as inject some additional "perky" wavelengths in those post-lunch sleepy times, we'll leave to the scientists to figure out. We will want the capabilities to be pretty much the same, whether retrofitting in a full LED-based luminaire, upgrading a troffer with a LED kit, or just swapping in LED tube. We'll expect them to integrate seamlessly into the control network, as well as operate with "coordinated autonomy", not needing to hear from "central control" that there is a particular amount of sunlight, or zero, one or a meeting's worth of bodies in the room. And since we need luminaires in every space, there is no reason that every kind of building-automation, environmental and security sensor that is practical should be integrated into the room's light. "A person-down sensor in every space" might be the battle cry (although one does have to wonder how it will respond when the boss starts doing his or her yoga... yes there will be unpredicted issues along the way).
Timing - Slower than desired, but faster than expected. It's inevitable, as technology advances often are. We expect a lot from our technology, and while we may want it pretty quickly, since we don't have it, we don't "miss it" for the lack. I still harken back to the year 2000 when I sat in a room of "normal" people here in high tech Austin, who were polled on how many had fast (broadband) internet in their homes. It was about 5-10% that had access of something other than dial-in, and at the then-blazing speed of 500K to 1Mbit data rates. A scant decade or so later, and someone without that data rate streaming into their pocket is considered the odd man out. Change is like that, and technical change is accelerating, not peaking by any means. We'll have our light bulb "egg-laying-wool-milk-pigs" before the end of this decade, with Grade AA quality on every feature. Need pictures of the strobing pillow fight? Just tell the light.
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