Internet Television, E-Science and Optical Monitoring of Structural Health at Optical Communications Conference.WASHINGTON -- Researchers will announce some of the latest breakthroughs and innovations in optics-based communications at OFC/NFOEC 2006--the largest and most comprehensive international event for optical communications. OFC/NFOEC (Optical Fiber Communication Conference and Exposition/National Fiber Optic Engineers Conference) will take place at the Anaheim Convention Center Anaheim Convention Center is a major convention center in Anaheim, California. It is located across from the Disneyland Resort on Katella Avenue. Much of the Anaheim Convention Center has been renovated in recent years with state-of-the-art facilities. between March 5 and 10, 2006. In addition to a technical conference that spans the whole meeting, there will be an exposition featuring the latest in optical technology from more than 600 of the industry's key companies. The meeting is sponsored by the IEEE Communications Society The IEEE Communications Society is a society of the Institute of Electrical and Electronics Engineers (IEEE). It is also known by it the abbreviation ComSoc. In the hierarchy of IEEE, the Communication Society is one of close to 40 technical societies organized under the , the IEEE Lasers and Electro-Optics Society The IEEE Lasers and Electro-Optics Society is a society of the Institute of Electrical and Electronics Engineers (IEEE). It is also known by its acronym LEOS. In the hierarchy of IEEE, the Lasers and Electro-Optics Society' is one of close to 40 technical societies organized under , and the Optical Society of America The Optical Society of America (OSA) is a scientific society dedicated to advancing the study of light—optics and photonics—in theory and application, by means of worldwide research, scientific publishing, conferences and exhibitions, partnership with industry, and the . TECHNICAL PRESENTATION HIGHLIGHTS The following represent some of the technical highlights at OFC/NFOEC 2006. Full papers and contact information for the authors may be obtained by contacting Colleen Morrison at 202.416.1437 or cmorri@osa.org.
1. Making Internet-Based Television Practical and Affordable
2. Pinpointing Structural Problems Earlier With Fiber Optics
3. Delivering Super-Broadband Wired and Wireless Services
Simultaneously
4. E-Science: The Future Of Sharing Data
5. Thinking Inside the Box
6. Producing Economically Important Light
7. Manufacturing Photonic Integrated Circuits En Masse
8. 10G Networks Help Broadband Services Grow Faster than Moore's Law
1. INTERNET-BASED TELEVISION: MAKING IT PRACTICAL AND AFFORDABLE Combine high-speed telecommunications networks with the flexible techniques for sending data over the Internet, and you get IPTV (Internet Protocol TV) Also called "TV over IP," IPTV delivers scheduled TV programs and video-on-demand (VOD) via the IP protocol and digital streaming techniques used to watch video on the Internet. , or Internet Protocol Television, a newly emerging method for delivering digital video to homes. Rather than broadcasting hundreds of channels at a time to every subscriber's home, IPTV provides individual content on demand, by efficiently storing both live broadcasts and stored video on a provider-wide network. IPTV can also blend in voice, Internet, and other services onto a single TV screen, while offering portability to subscribers to access the television channels to which they subscribe, on different user devices and/or locations (e.g., on their laptops and even in their friend's homes). Researchers at the meeting will describe techniques for implementing IPTV at affordable costs while leveraging existing infrastructure. Samrat Kulkarni and his fellow engineers at Lucent Technologies Bell Labs will present models and case studies for "transport networks" between a provider's regional office and individual subscribers. Such transport networks contain the hardware to deliver high-speed signals to the curb, while giving telecom providers the freedom to reuse their own infrastructure (even old-fashioned copper cable) to deliver IPTV the rest of the way to their subscribers' homes. The authors modeled Lucent's IPTV transport system in various trial scenarios. The scenarios involved real world situations in which Lucent worked with different telecommunications service providers (carriers) to support currently existing infrastructure, which utilize both old and new telecom technologies. The methods and examples explained by the authors suggest a superior system for existing and future customers that will bring a convenient and cost-effective solution to loyal carrier customers, while at the same time, helping carriers to achieve greater service options, with expanded bandwidth and higher speeds, for whatever telecommunications needs and advances may arise in the future. (Paper NWC NWC Network Computing (Magazine) NWC Northwest College (Powell, Wyoming) NWC Northwestern College (Orange City, IA, USA) NWC Northwestern College (St. 1, "Access Transport Network for IPTV Video Distribution") 2. PINPOINTING STRUCTURAL PROBLEMS EARLIER WITH FIBER OPTICS fiber optics, transmission of digitized messages or information by light pulses along hair-thin glass fibers. Each fiber is surrounded by a cladding having a high index of refractance so that the light is internally reflected and travels the length of the fiber University of Ottawa In one demonstration, conducted with civil engineers at the University of Ottawa, the researchers tested the DBS system on a concrete column encased en·case tr.v. en·cased, en·cas·ing, en·cas·es To enclose in or as if in a case. en·case  ment n. with fiber-reinforced rods and sheets.
Subjecting the column to simulated seismic forces such as those that
would occur in an earthquake or tsunami, the researchers could detect
signs of debonding (in which the concrete detached from the fiber
casing) and the crushing of concrete as a result of compression forces.
Unlike competing techniques, the system could readily tell the
difference between debonding and crushing.The Ottawa researchers say that DBS can prevent potentially life-threatening and environmentally damaging accidents and multimillion-dollar repairs. Unlike present structural health analysis, which is done on a spot-by-spot basis, DBS can detect problems over all points in the entire structure and pinpoint them to within 5 centimeters, while detecting mechanical strains as low as 20 micro-strains, exceeding the 1-meter resolution and 50 microstrain that the construction industry has wanted and expected. In addition, the technique can improve the testing of structures and materials by providing valuable information during the testing process. (Paper OTuL7, "Distributed Brillouin Sensor Based on Brillouin Scattering for Structural Health Monitoring Structural health monitoring (SHM) is an upcoming technology in civil, mechanical and aerospace engineering. In the last ten to fifteen years, SHM technologies have emerged creating an exciting new field within various branches of engineering. ") 3. DELIVERING SUPER-BROADBAND WIRED AND WIRELESS SERVICES SIMULTANEOUSLY Currently, telecommunications providers generally supply services that are either all-wireless (e.g. mobile phones) or all-wired (such as DSL DSL in full Digital Subscriber Line Broadband digital communications connection that operates over standard copper telephone wires. It requires a DSL modem, which splits transmissions into two frequency bands: the lower frequencies for voice (ordinary and cable). If a customer wants wireless access from a cable modem, for example, he or she must purchase additional equipment. Now, Gee-Kung Chang of the Georgia Institute of Technology Georgia Institute of Technology, in Atlanta, Ga.; coeducational; state supported; chartered 1885, opened 1888. It is a member school in the university system of Georgia. Significant among its facilities and programs are the Frank H. and colleagues have designed and experimentally demonstrated a network that telecommunications providers could potentially use to simultaneously provide high-speed wired and wireless super broadband services with the same optical signal. Using existing passive optical network (PON (Passive Optical Network) An optical point-to-multipoint access network. There are no optical repeaters or other active devices in a PON, hence the name "passive. ) infrastructure (which enables fiber-optics services to be delivered directly to homes) without the need for expensive electronic equipment, the design can simultaneously deliver broadband services such as high-definition television (HDTV (High Definition TV) A set of digital television (DTV) standards that offer the highest resolution and sharpest picture. Although some HDTV sets are available in standard (rather square) screen sizes, the overwhelming majority of sets are wide screen, which eliminates ) via an optical plug on a building wall and through a wireless network at a data rate of up to 2.5 Gigabits per second, significantly faster than the 100 Megabits per second (unit) megabits per second - (Mbps, Mb/s) Millions of bits per second. A unit of data rate. 1 Mb/s = 1,000,000 bits per second (not 1,048,576). E.g. Ethernet can carry 10 Mbps. in many current state-of-the-art Wi-Fi systems. This hybrid technique can be incorporated into all-optical-fiber networks (also known as fiber-to-the-home, or FTTH (Fiber To The Home) See FTTP. networks) that telecom providers are currently deploying in business and residential areas. In their network system, researchers first use standard techniques to "up-convert" a digitally modulated fiber-optic signal in the infrared range to one in the microwave or millimeter-wave range. This up-converted signal is split into two parts at the customer's premises, one that is detected by a high-speed receiver, then amplified before being transmitted as a wireless signal. The other part is sent directly to the plugs on a building wall via optical fibers. The key to this advance is the employment of low-cost optical receivers and amplifiers to provide the wired and wireless signals. Currently, the researchers are working with several service providers and equipment vendors to further develop their system into a product. (Paper OFM OFM abbr. Order of Friars Minor 1, "Novel Optical-Wireless Access Network Architecture for Simultaneously Providing Broadband Wireless and Wired Services") 4. E-SCIENCE: THE FUTURE OF SHARING DATA Advances in high performance networks are enabling new frontiers of discovery. Large-scale research, often referred to as e-science, typically involves collaborative teams of scientists and scientific equipment located around the world. National governments and research organizations are investing in multimillion-dollar technical instruments (such as high-voltage electron microscopes) and facilities to collect vast amounts of raw data. However, numerous steps are involved, such as time-consuming person-to-person data queries, before information can be visualized and analyzed by joint research teams situated across countries or across multiple continents. What if particle physics data from the Large Hadron Collider This article or section contains information about an expected future scientific facility. It is likely to contain information of a speculative nature and the content may change as the facility approaches completion. , at CERN CERN or European Organization for Nuclear Research, nuclear and particle physics research center straddling the French-Swiss border W of Geneva, Switzerland. near Geneva Geneva, canton and city, Switzerland Geneva (jənē`və), Fr. Genève, canton (1990 pop. 373,019), 109 sq mi (282 sq km), SW Switzerland, surrounding the southwest tip of the Lake of Geneva. , Switzerland, could be made available to researchers in Chicago, Bombay or Tokyo in real-time? Gigi Karmous-Edwards of MCNC MCNC Microelectronics Center of North Carolina in Research Triangle Park Research Triangle Park, research, business, medical, and educational complex situated in central North Carolina. It has an area of 6,900 acres (2,795 hectares) and is 8 × 2 mi (13 × 3 km) in size. Named for the triangle formed by Duke Univ. , NC, envisions easily connecting researchers to remote data through new optical-fiber network configurations. Network-transport protocols and dynamic optical network configurations will be as essential as high-performance computing resources in order to solve complex scientific problems. She works as part of the Global Lambda Integrated Facility, an international community that supports data-intensive scientific research and helps develop middleware to coordinate the resources that e-science requires. Her talk will discuss some of the optical networking challenges that need to be solved as global e-science collaboration evolves. (Paper OWU OWU Ohio Wesleyan University (Delaware, Ohio) OWU Oklahoma Wesleyan University (Bartlesville, Oklahoma) 3, Today's Optical Network Research Infrastructures for E-Science Applications) 5. THINKING INSIDE THE BOX: SQUARE-CORE FIBER PROMISES FASTER, MORE EFFICIENT MANUFACTURE OF FLAT-PANEL DISPLAYS John Hayes of the University of Southampton In the most recent RAE assessment (2001), it has the only engineering faculty in the country to receive the highest rating (5*) across all disciplines.[3] According to The Times Higher Education Supplement and his colleagues have designed, built and tested a new fiber with a square-shaped core rather than the traditional circle-shaped cross section. The square-core fiber may lead to faster, more cost-effective and more energy-efficient production of flat-panel display screens. The fiber may also be useful in medical procedures, device manufacturing and other industrial processes involving laser light. In the manufacture of flat-panel displays, one can use lasers to remove, or ablate ab·late v. To remove or destroy the function of. ablate to remove, especially by cutting. ablate verb To remove; excise , rectangular-shaped regions from an electrically conducting coating (typically indium tin oxide Indium tin oxide (ITO, or tin-doped indium oxide) is a mixture of indium(III) oxide (In2O3) and tin(IV) oxide (SnO2), typically 90% In2O3, 10% SnO2 by weight. , or ITO Ito, city (1990 pop. 71,223), Shizuoka prefecture, central Honshu, Japan, on the Izu Peninsula and the Sagami Sea. It is an important fishing port and hot spring resort. See indium. ) on a glass screen. The ITO regions that remain form the electrodes for the RGB (Red Green Blue) The computer's native color space, which is the color system for capturing and displaying images. RGB was derived from our own perception of color because human eyes are sensitive to red, green and blue (see trichromaticity). sub pixels. Presently, these electrodes are formed by expensive lithographic lith·o·graph n. A print produced by lithography. tr.v. lith·o·graphed, lith·o·graph·ing, lith·o·graphs To produce by lithography. processes involving resist coating, exposure, developing and etching steps. It is possible to replace this multi-step complex process by a single-step laser-based technique. Current technology utilizes circular-core beams which are passed through a series of expensive, complicated optics to make a square-shaped beam. The overall efficiency of such a system is quite low such that high power lasers are required. In contrast, the square-core fiber can directly deliver an intense square shaped beam of light to make the electrodes much more efficiently. This new fiber is a type of microstructured or "holey" fiber. Holey fibers have tiny holes running through them in a pattern that trap light in a solid core. In this carefully constructed fiber the holes are arranged in a square producing a very neat square beam of light. According to Hayes, the fiber can accept a wide variety of input beams but provides a uniform, square beam at the output end making it immediately useful in the manufacture of flat panel displays. This novel fiber design, with its well defined core geometry, extends the capabilities and precision of light manipulation in manufacturing and other fields. (Paper OThH3, "Square Core Jacketed Air-Clad Fiber") 6. PRODUCING LIGHT IN AN ECONOMICALLY IMPORTANT REGION Bismuth-doped fiber lasers can produce light nicely in the economically important wavelength region around 1.3 microns. This spectral region is sometimes referred to as a "second window" (the first being around 0.85 microns and a third at 1.55 microns) for data transmission since optical loss for light at 1.3 microns is only about 0.35 decibel decibel (dĕs`əbĕl', –bəl), abbr. dB, unit used to measure the loudness of sound. It is one tenth of a bel (named for A. G. Bell), but the larger unit is rarely used. per km and chromatic dispersion in silica-based glass is nearly zero. Research with fiber lasers in this region, however, has encountered some physical and technical obstacles. Consequently, there have been no effective silica-based fiber lasers and amplifiers at 1.3 microns. This changes now, with the work of E.M. Dianov of the Fiber Optics Research Center at the A.M. Prokhorov General Physics Institute of the Russian Academy of Sciences Russian Academy of Sciences (Russian: Росси́йская Акаде́мия Нау́к, and his colleagues. At the meeting, they will report the first bismuth-doped silica fiber laser, with up to 0.5 watts of power in the spectral range 1146-1300 microns. (Paper OTuH4, "Bi-Doped Silica Fibers: A New Active Medium for Tunable Fiber Lasers and Broadband Fiber Amplifiers") 7. MASS-PRODUCING PHOTONIC INTEGRATED CIRCUITS Photonic chips, the opto-electronic equivalent of electronic microchips, often come in pairs, one for transmitting photonic signals and one for receiving. At the meeting, Fred Kish of Infinera Corporation, will report that his company can manufacture integrated photonic chips in great volume. The overall data rate for these devices is 100 Gb/sec. The sending chip contains 10 lasers, 10 modulators (each capable of working at 10Gb/sec rates for a total rate of 100 Gb/s), a demultiplexer, and other devices, while the receiving chip contains complementary devices, such as photoreceivers, multiplexers, etc. This is in comparison with typical present industry performance data rates for long-haul telecom systems of 10 Gb/sec per chip; a few can go as high as 40 Gb/sec. (Paper OWL1, Kish et al., "Volume Manufacturing and Deployment of Large-Scale Photonic Integrated Circuits") 8. 10G NETWORKS HELP BROADBAND SERVICES GROW FASTER THAN MOORE'S LAW "The number of transistors and resistors on a chip doubles every 18 months." By Intel co-founder Gordon Moore regarding the pace of semiconductor technology. He made this famous comment in 1965 when there were approximately 60 devices on a chip. Bob Harris of Time Warner Cable This article or section needs sources or references that appear in reliable, third-party publications. Alone, primary sources and sources affiliated with the subject of this article are not sufficient for an accurate encyclopedia article. will discuss the architecture of large-scale fiber-optics-based 10G networks able to deliver such services as voice, video, and Internet service to regional, community, and government customers. High-bandwidth networks operating with multiple optical channels, where each channel is 10G-enabled, Harris says, offers compelling economics in the delivery of services across local, metropolitan, and regional networks. Providers are now able to offer new services and support the rising traffic demands that are increasing at a rate greater than Moore's law (i.e., more than doubling every 18 months). In addition to helping proliferate services such as VoIP (Internet telephone), 10G networks facilitate the economic delivery of telecom services to government organizations such as broadband access to K-12 grade students. Harris will point out the technological aspects of these networks that make them so powerful and flexible. For example, they transmit up to 40 wavelengths of light simultaneously through fiber lines, unlike previous generations, which would only transmit several wavelengths or less. In addition, crucial elements of a 10G system, such as routing and switching, are located at the edges of the network, rather than at its center, analogous to how the workers of many cities reside in the suburbs, rather than in the midst Adv. 1. in the midst - the middle or central part or point; "in the midst of the forest"; "could he walk out in the midst of his piece?" midmost of a metropolis. Multi-wavelength 10G networks build upon previous generations of network systems and fiber-optics technology. The open-ended architecture of 10G, Harris says, provides the ability to keep up with bandwidth demands and deliver new broadband services as they become available, helping people become better connected than ever before. (Paper OTuJ1, "10G-Enabled Optical Network Architecture Directions for Video, Voice and Data: An MSO (1) (Multiple System Operator) Typically refers to a cable TV organization that owns more than one cable system, but it may refer to an operator of only one system. Perspective") A press room will be located in the Anaheim Convention Center, room 208A. The press room will be open Sun., Mar. 5, 12 - 4 and Mon., Mar. 6 - Thurs., Mar. 9, 7:30 a.m. - 6 p.m. Those interested in obtaining a badge for the press room should contact OSA's Colleen Morrison at 202.416.1437, media@ofcconference.org or Melissa Norr, 202.416.1443, mnorr@osa.org. More information can be found online at http://www.ofcconference.org/media_center/, including exhibitor press releases and other materials. About OFC/NFOEC: Since 1985, the Optical Fiber Communication Conference and Exposition (OFC OFC Office OFC Officer OFC Of Course OFC Oxygen Free Copper OFC Oceania Football Confederation (soccer) OFC Optical Fiber Cable OFC Optical Fiber Communications OFC Optical Fiber Conference ) has provided an annual backdrop for the optical communications field to network and share research and innovations. In 2004, OFC joined forces with the National Fiber Optic Engineers Conference (NFOEC NFOEC National Fiber Optical Engineer Conference NFOEC National Fiber Optic Engineers Conference ) creating the largest and most comprehensive international event for optical communications. By combining an exposition of more than 600 companies, with a unique program of peer-reviewed technical programming and special focused educational sessions, OFC/NFOEC provides an unparalleled opportunity reaching every audience from service providers to optical equipment manufacturers and beyond. OFC/NFOEC, www.ofcnfoec.org, is managed by the Optical Society of America (OSA) and co-sponsored by OSA, the Institute of Electrical and Electronics Engineers/Communications Society (IEEE/ComSoc) and the Institute of Electrical and Electronics Engineers/Lasers and Electro-Optics Society (IEEE/LEOS). Acting as a non-financial technical co-sponsor is Telcordia Technologies, Inc. |
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