Sentences with phrase «in optical design»

I have 10 years experience in optical design using Zemax and another 3 years of experience with SolidWorks designing opto - mechanical hardware.

The Xbox console owners filed a proposed class action against Microsoft in federal court in 2011, saying the design of the console was defective and that its optical disc drive could not withstand even small vibrations.

But space posed a unique design constraint on Stearns: solar radiation and extreme environmental temperature shifts would melt and degrade the paint and ink he worked with, making them hazards to the delicate optical hardware in the satellites.

Initial experimental demonstration of the principles of a xenon gas shield designed to protect optical components from soft x-ray induced opacity (blanking) in high energy density experiments

The Sentinel II optical sorter is designed for sorting many food applications and will typically be found in the tomato, peach and potato processing industry.

This exhibit was designed as a replica of the first American Optical company «spectacle shop» in Southbridge, Massachusetts, where George Washington Wells, father of the founders of Old Sturbridge Village began manufacturing eyeglasses in the late 1800s.

«Leveraging our expertise in multi-layer film innovation and illustrating our prowess in optical science, we're able to work closely with financial institutions to enable a new generation of transaction cards with bold designs and style that appeal to consumers.»

The researchers believe that their results will be useful in the design and implementation of new kinds of optical components and characterization techniques that utilize unconventional optical fields.

The mouse is ergonomically designed to fit in the palm of your hand, and it features an excellent 10,000 DPI optical sensor for high sensitivity and quick reaction time.

Each of the two main components — the iris - like liquids and the deformable lens — can be designed to compensate for any aberrations in the other, resulting in better optical quality than would be expected if you were to consider the two components separately, Zappe said.

The beetle might not stand out against the brilliant blue of a butterfly, but «in terms of sheer design ingenuity, for me this is my favorite,» says optical physicist Pete Vukusic of Exeter University in England, who has studied the bright coloring of dragonflies and butterflies.

The pulses were designed to modify the fibre's optical properties, so as the laser pulse travelled along the fibre, the change in the fibre's properties moved along it at the same speed.

García - Garibay hopes to design crystals that take advantage of properties of light, and whose applications could include advances in communications technology, optical computing, sensing and the field of photonics, which takes advantage of the properties of light; light can have enough energy to break and make bonds in molecules.

Metamaterials are artificial composites of various materials designed to exhibit optical properties not anticipated in nature.

This allows testing of individual optical elements on the chip, a crucial step in the design optimisation to ensure its flawless operation.

His work on the design of miniature optical elements, «small lightweight instruments to be used for remote microscopy inside human beings,» became the basis for the microscope attachment that makes CMaRS useful in the field.

In the journal Optical Materials Express, the researchers show that their sensor design is nine times more sensitive than other tapered fiber refractive index sensors.

Photonic chip functionality is usually hard - wired by design, however reconfigurable optical elements would allow light to be routed flexibly, opening up new applications in programmable photonic circuits.

The Anglo - Australian Telescope at Siding Spring in New South Wales is being equipped with optical components and optical - fibre spectrographs designed to map the Universe on large scales.

«With modeling and optimization using our in - house code, we can design a silicon modulator with best - in - class performance,» says Lim, «which will facilitate the development of low - loss, high - speed optical data transmission systems.»

In order to qualify for participation in the Star Tiger programme, applicants should have experience in one or more of the following research areas: lithography, microelectromechanical systems fabrication, radio frequency (RF) system design, optical and RF photonic bandgap design, test and measurement, charge - coupled device imaging, packaging / micro / self - assembly, mechanical design, materials sciences, solid state physics, or general physicIn order to qualify for participation in the Star Tiger programme, applicants should have experience in one or more of the following research areas: lithography, microelectromechanical systems fabrication, radio frequency (RF) system design, optical and RF photonic bandgap design, test and measurement, charge - coupled device imaging, packaging / micro / self - assembly, mechanical design, materials sciences, solid state physics, or general physicin the Star Tiger programme, applicants should have experience in one or more of the following research areas: lithography, microelectromechanical systems fabrication, radio frequency (RF) system design, optical and RF photonic bandgap design, test and measurement, charge - coupled device imaging, packaging / micro / self - assembly, mechanical design, materials sciences, solid state physics, or general physicin one or more of the following research areas: lithography, microelectromechanical systems fabrication, radio frequency (RF) system design, optical and RF photonic bandgap design, test and measurement, charge - coupled device imaging, packaging / micro / self - assembly, mechanical design, materials sciences, solid state physics, or general physics.

One of the challenges in the design and development of optical circuits is their efficiency in terms of speed and energy consumption.

The researchers describe their innovative design in the premiere issue of The Optical Society's (OSA) new open - access journal Optica.

Part of it lies in the fact that it wasn't designed to be an optical illusion.

In the podcast Hofmann emphasizes the importance of not only pushing past current wireless bandwidth limitations — via small cells, optical antenna arrays and dynamic spectrum management — but also designing new networks in a way that can manage a variety of mobile uses, such as the explosion of smartphone and tablet apps or simply uploading / downloading video on the gIn the podcast Hofmann emphasizes the importance of not only pushing past current wireless bandwidth limitations — via small cells, optical antenna arrays and dynamic spectrum management — but also designing new networks in a way that can manage a variety of mobile uses, such as the explosion of smartphone and tablet apps or simply uploading / downloading video on the gin a way that can manage a variety of mobile uses, such as the explosion of smartphone and tablet apps or simply uploading / downloading video on the go.

The gradient optical force was first used in the 1970s, in «optical tweezers,» which were designed to manipulate molecules in a kind of optical microscope.

«Our results show that nonlinear scattering theory can be a valuable tool in the design of nonlinear metamaterials not only for second - order but also higher order nonlinear optical responses over a broad range of wavelengths,» O'Brien says.

What's more, results from Keck's vortex coronagraph will help with a planet imager planned for the future Thirty Meter Telescope and with proposed NASA space missions, such as the Habitable Exoplanet Imaging Mission (HabEx) and the Large UV / Optical / IR Surveyor (LUVOIR), which would use next - generation vortex coronagraphs currently being designed in Mawet's group at Caltech.

The Bio-Inspired Optics MURI's mission is to develop a better understanding of the relationship between structure and optical function in biological organisms and to design innovative bio-inspired optical structures.

The work in Gail's group involves the design, development and application of linear and nonlinear optical instrumentation for biomedical imaging, from the nanoscale to the whole organism.

IPIC Director and Head of Photonics Tyndall, Prof Paul Townsend highlighted: «The investment will not only advance IPIC's optical modulator and photonics integration technologies into products designed for volume production, but will also strongly position both IPIC and Rockley to take competitive advantage in the datacomms market which is expected to reach $ 6.4 Billion by 2023.

Throughout the course of this study, the teams compiled an extensive library of experimental and theoretical data including electronic, magnetic, optical, photoelectrochemical, and structural properties, which are now used as feedstock in material genome work and near - term development of superior PEC materials through materials - by - design techniques.

Group 1: Materials, Resonators, & Resonator Circuits A. Fundamental Properties of Materials B. Micro - and Macro-Fabrication Technology for Resonators and Filters C. Theory, Design, and Performance of Resonators and Filters, including BAW, FBAR, MEMS, NEMS, SAW, and others D. Reconfigurable Frequency Control Circuits, e.g., Arrays, Channelizers Group 2: Oscillators, Synthesizers, Noise, & Circuit Techniques A. Oscillators — BAW, MEMS, and SAW B. Oscillators - Microwave to Optical C. Heterogeneously Integrated Miniature Oscillators, e.g., Single - Chip D. Synthesizers, Multi-Resonator Oscillators, and Other Circuitry E. Noise Phenomena and Aging F. Measurements and Specifications G. Timing Error in Digital Systems and Applications Group 3: Microwave Frequency Standards A. Microwave Atomic Frequency Standards B. Atomic Clocks for Space Applications C. Miniature and Chip Scale Atomic Clocks and other instrumentation D. Fundamental Physics, Fundamental Constants, & Other Applications Group 4: Sensors & Transducers A. Resonant Chemical Sensors B. Resonant Physical Sensors C. Vibratory and Atomic Gyroscopes & Magnetometers D. BAW, SAW, FBAR, and MEMS Sensors E. Transducers F. Sensor Instrumentation Group 5: Timekeeping, Time and Frequency Transfer, GNSS Applications A. TAI and Time Scales, Time and Frequency Transfer, and Algorithms B. Satellite Navigation (Galileo, GPS,...) C.Telecommunications Network Synchronization, RF Fiber Frequency Distribution D. All - optical fiber frequency transfer E. Optical free - space frequency transfer F. Frequency and Time Distribution and Calibration Services Group 6: Optical Frequency Standards and Applications A. Optical Ion and Neutral Atom Clocks B. Optical Frequency Combs and Frequency Measurements C. Ultrastable Laser Sources and Optical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other AppliOptical C. Heterogeneously Integrated Miniature Oscillators, e.g., Single - Chip D. Synthesizers, Multi-Resonator Oscillators, and Other Circuitry E. Noise Phenomena and Aging F. Measurements and Specifications G. Timing Error in Digital Systems and Applications Group 3: Microwave Frequency Standards A. Microwave Atomic Frequency Standards B. Atomic Clocks for Space Applications C. Miniature and Chip Scale Atomic Clocks and other instrumentation D. Fundamental Physics, Fundamental Constants, & Other Applications Group 4: Sensors & Transducers A. Resonant Chemical Sensors B. Resonant Physical Sensors C. Vibratory and Atomic Gyroscopes & Magnetometers D. BAW, SAW, FBAR, and MEMS Sensors E. Transducers F. Sensor Instrumentation Group 5: Timekeeping, Time and Frequency Transfer, GNSS Applications A. TAI and Time Scales, Time and Frequency Transfer, and Algorithms B. Satellite Navigation (Galileo, GPS,...) C.Telecommunications Network Synchronization, RF Fiber Frequency Distribution D. All - optical fiber frequency transfer E. Optical free - space frequency transfer F. Frequency and Time Distribution and Calibration Services Group 6: Optical Frequency Standards and Applications A. Optical Ion and Neutral Atom Clocks B. Optical Frequency Combs and Frequency Measurements C. Ultrastable Laser Sources and Optical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other Applioptical fiber frequency transfer E. Optical free - space frequency transfer F. Frequency and Time Distribution and Calibration Services Group 6: Optical Frequency Standards and Applications A. Optical Ion and Neutral Atom Clocks B. Optical Frequency Combs and Frequency Measurements C. Ultrastable Laser Sources and Optical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other AppliOptical free - space frequency transfer F. Frequency and Time Distribution and Calibration Services Group 6: Optical Frequency Standards and Applications A. Optical Ion and Neutral Atom Clocks B. Optical Frequency Combs and Frequency Measurements C. Ultrastable Laser Sources and Optical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other AppliOptical Frequency Standards and Applications A. Optical Ion and Neutral Atom Clocks B. Optical Frequency Combs and Frequency Measurements C. Ultrastable Laser Sources and Optical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other AppliOptical Ion and Neutral Atom Clocks B. Optical Frequency Combs and Frequency Measurements C. Ultrastable Laser Sources and Optical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other AppliOptical Frequency Combs and Frequency Measurements C. Ultrastable Laser Sources and Optical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other AppliOptical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other AppliOptical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other Applications

Scientists from Hamburg University of Technology (TUHH), ITMO - University St. Petersburg, Menoufia Uni-versity, University of York, University of St. Andrews, Tyndall - Institute Cork, Sun Yat - sen University Guang - zhou, and Helmholtz - Zentrum Geesthacht realized a novel effect in silicon based optical waveguide chips which were particularly designed and fabricated for this nanophotonic experiment.

Dublin Institute of Technology, Electrical and Controls Engineering and Gaskatel, Kassel, Germany - Fuel Cells University of Applied Science - Germany, Fuel Cells and Nanocomposit Materials Trinity College - Dublin Physics - Nanotubes and Polymer Modified Carbon Nanotubes materials and Spectroscopic Characterization of Liganded Rare Earth Compounds (Chemistry) Our work has resulted inthe start up of two companies: Photonic Cleaning Technologies, LLC, Platteville, WI, USA - Manufacturer of First Contact Polymer, Sales in 62 Countries Xolve, Inc., Platteville, WI, USA Hamilton Group Past and Present Research and Development Projects: Design, Characterization and Synthesis of Chromone Laser Dyes Surface And Optical Characterization of Polymer Strip Coatings for Optics and Astronomy Double Resonance IR / VIS Fluorescence Detection using the National Free Electron Laser Facility in Newport News, Virginia

We design and build an extensive range of state of the art optical and electronic devices for use in fluorescence microscopy and advanced imaging research.

The optical design utilizes a dynamic z - stack to produce all - in - focus [1 — 3] information rich images enabling detailed analysis by generating in - depth images not previously seen with other techniques.

When used in conjunction with octagonal fibers, this device yields very high scrambling gains and greatly desensitizes the fibe... ▽ More We present the design and test results of a compact optical fiber double - scrambler for high - resolution Doppler radial velocity instruments.

This difference will allow HDST to utilize lower - cost optical materials, incur less thermal stress in the structures, simplify component and system design, manufacturing and qualification, and lower the costs of system integration and testing, much of which had to be done under cryogenic conditions for JWST.

A substantial portion of the COS improvement in sensitivity is due to an optical design that requires only a single reflection inside the instrument, reducing the losses due to imperfect reflectivity.

Beijing, China (October 16, 2017)-- Representatives from the Thirty Meter Telescope's (TMT's) Wide - Field Optical Spectrograph (WFOS) team and TMT's China partners gathered recently in China to discuss potential collaboration during the next stage of the conceptual design of WFOS.

In 2010, MSSS is completing two additional Mastcams with a zoom lens optical design; NASA will decide in late 2010 which pair of Mastcams will go to MarIn 2010, MSSS is completing two additional Mastcams with a zoom lens optical design; NASA will decide in late 2010 which pair of Mastcams will go to Marin late 2010 which pair of Mastcams will go to Mars.

Afternoon tea in the library is a real treat, but the Ham Yard Village is where the real indulgences are to be found: A specially curated group of shops in the hotel's courtyard includes specialist fragrance destination Brummels of London; uber - cool optical haven Eyewear Concierge; the divine Bloomsbury Flowers; and handcrafted housewares and jewelry store Dinosaur Designs.

On - the - road practically every week for the Crowne Plaza project, Weiland will be in San Francisco next week for a potential design collaboration with Zenni Optical, an e-commerce business for affordable eyewear that was launched by two scientists in 2003.

As the white, and purple fringe gradually becomes the skirt base in violet, and a geometric white design, the hem detailing artfully creates an optical illusion that makes the skirt appear to be being woven on the wearer — a befitting reference to the masterful artisanship of the cultures in which Lanvin was alluding to through designs such as this.

Students will also be able to «get creative» in designing the own Optical Illusion drawing (based on the Fairtrade mark).

«In this case, the design is based on a geometric optical effect pattern.

Taillights include new white design with fewer reflectors, plus red lines in the optical lenses

The rear lamps are of matching design, taking up the contour of the «Black Panel» and surrounded by an LED optical fibre in electric blue, which changes to red when the vehicle is moving and acts as a tail light.

It combines a high - resolution and highly responsive touch display with a highly tactile keyboard and a precise optical trackpad, but comes in a narrow design that is easy to carry and exceptionally comfortable to hold.