This is possible with sensor-based peripherals which are used by the device and are compatible with your mobile phone and by bringing in augmented reality.
The device was unveiled at the CES this year. You will be able to experience multiplayer games in the real world like never before.
The Lyter handheld device and the apps which are enabled with Lyteshot and used via the smartphone of the players.
A set of peripherals have been developed by Lyteshot which are attached to the Lyter so that it can then be 3d printed in the shape of a gun, staff, wand, bow,
The Lytepuck sensor and the Lyter, connect with your mobile device and helps in relaying game data to other players through the cloud.
On the basis of the game you play, the Lyteshot performs accordingly. For example, it can deliver a deadly blow to an enemy,
game stats and more as the command gets sent instantly to their mobile devices through the cloud.
This will allow the users to play in first person in the game using the smart glasses like Google glass, Epson Moverio, etc.
Right now, Lyteshot has teamed up with Epson to incorporate Lyteshot gaming with Moverio BT-200 smart glasses from Epson.
#CAP-XX Introduces Thinline Supercapacitors with Unique Nanotechnology Construction Examples include wearables (medical, fitness and health monitors, smart watches, drug delivery systems), portables (active
credit cards, smartphones, RFID tags), and connected electronics (smart homes and smart buildings, electronic shelf labels, wireless sensor networks).
and provide the backup needed for graceful shutdown and"last gasp"transmissions in mission-critical applications.
CAP-XX Thinline supercapacitors support power requirements in Iot devices including wireless communication (Bluetooth Bluetooth Smart, Zigbee, Z-Wave, Ant, active RFID), electronic paper and OLED displays, haptic or tactile feedback, vibration alerts, GPS acquisition,
and injection or inhalation system delivery. The Thinline idea was born while working with a customer designing a disposable insulin pump."
as well as inductive/wireless and cable/cradle fast-charging systems. Key features of Thinline include: CAP-XX Thinline supercapacitors are available in three footprints:
who headed the project at the Lab's Center for Functional Nanomaterials (CFN), a DOE Office of Science User Facility.
or manipulate light for telecommunications applications, or design novel catalysts for speeding up a variety of chemical reactions,"Gang said.
Our work demonstrates the versatility of this approach and opens up numerous exciting opportunities for high-yield precision assembly of tailored 3d building blocks in
the researchers need to subtract the data from the images and integrate the same by means of single particle 3d reconstruction
#CDTI Introduces Nanoscale BMARS Powder-Based Catalysts BMARS is one of CDTI's new, key enabling catalytic powder materials developed to reduce the dependence on the use of costly platinum group metals (PGMS) in vehicle emission control systems currently undergoing vehicle
Initial tests reveal that BMARS delivers superior oxides of nitrogen (NOX) reduction on modern turbo-charged gasoline direct injection (GDI) engines compared to OEM catalysts,
rhodium (Rh) is the key PGM used to drive NOX conversion in gasoline three-way catalysts.
Commercialization efforts for OEM and aftermarket applications of BMARS powder-based catalysts are well underway.
"We are presenting applications data at this week's ASMS Conference, and plan to commence shipments in Q3 2015."
#Fujifilm and imec Develop Full-Color Organic light-emitting diodes Organic EL displays are used increasingly for televisions, mobile devices including smartphones as well as wearable devices.
Since they can be made thin and flexible, while also offering excellent response time and contrast ratio.
It is said that today's products require organic EL displays of high pixel density, i e. around 200ppi for 4k televisions, 500ppi for full HD mobile devices and even higher density for compact displays for wearable devices.
There has been active R&d for organic semiconductors to develop a high-resolution patterning method for organic EL materials to be used in these products.
This research result is to be presented at the SID Display Week, one of the world's largest international exhibitions for information displays, held in San jose, California from May 31 to June 5, 2015.
Since the commencement of joint research in November 2012, Fujifilm and imec have broken through the boundary of conventional technology to contribute to the progress of technology associated with organic semiconductors, e g.,
It is capable of data storage of up to 790k with thermal and time-stable, long-range magnetic order.
This is likely to have a potential impact in the area of data storage. It was noticed that the newly created material displayed magnetic properties
and characterizing, at the single cell level, whole proteomes--data that shows globally within such a cell
The announcement coincides with the Display Week 2015 exhibition, organized by Society of Information Display,
where Canatu is exhibiting at booth#447. Canatu unique CNB#Flex Film has been utilized to create a complete One-Plastic-Solution,
which has been overlooked often in the first wave of wearable devices. ur message is our films are the best transparent, flexible, conductive films on the market,
and may also help the food industry screen against contamination with harmful pathogens, according to researchers at the Korea Advanced Institute of Science and Technology (KAIST) in Daejeon, South korea.
and computer software to analyze the images and identify them by comparing them to other, known bacteria.
The software uses a machine-learning algorithm the sort computers connected to security cameras might use for automated facial recognition.
They then applied software they designed to the analysis, which used a conventional approach to statistical classification known as machine learning a sorting strategy based on pattern similarities that has been used extensively in applications like facial recognition software.
This was the first time anyone had applied machine learning to Fourier Transform light scattering data, Park said. They are now looking to extend their initial work to see
if they can distinguish between several types of bacterial subgroups to identify the most drug resistant or virulent strains from the innocuous ones.
In principle, the approach could be scaled up to screen for contaminated food or suspicious packages i
#Injectable Nanoscale Electronic Scaffolds to Monitor Neural activity It sounds unlikely, until you visit Charles Lieber's lab. A team of international researchers, led by Lieber, the Mark Hyman, Jr.
Professor of Chemistry, an international team of researchers developed a method for fabricating nanoscale electronic scaffolds that can be injected via syringe.
what they call simple but efficient structural color printing platformat the nanometer scale level. They believe the process holds promise for future applications,
Unlike the printing process of an inkjet or laserjet printer, where mixed color pigments are used, there is no color ink used in our structural printing process only different hole sizes on a thin metallic layer,
pigment-free color printing and relevant applications such as security marking and information storage. ther co-authors of the Scientific Reports paper are Dr. Fei Cheng,
#Innovative Hand-held Tool and App to Monitor for Signs of Skin cancer Unveiled at World Dermatology Conference Sadeghi,
#and my company, Metaoptima Technology. olescope#comprises a mini-microscope that attaches to a smartphone, an app (ios, Android,
or web compatible) and a cloud-based analytical platform called Dermengine#.#Once people take high-quality, high-resolution images of suspicious moles or skin abnormalities,
as people can self-monitor their moles and track changes over time. Visual changes in skin often signal the possibility of skin cancer.
and to work tirelessly to make it a reality. adeghi won recognition during the research and development phase of Molescope#,winning Wavefront Wireless Prize package ($40, 000) in the BCIC-New Ventures Competition in 2013, plus
While a graduate student at SFU (she earned a Phd in computing science in 2012 under supervisor
or incorporated into clothing-are bringing science fiction gadgets closer to real life. Dr Madhu Bhaskaran, project leader
she said. he ability to monitor such gases in production facilities and coal fired power stations gives vital early warning of explosions,
which has paved the way for flexible mobile phones. Lead author, Phd researcher Philipp Gutruf, says the unbreakable,
they will be able to link to electronic devices to continuously monitor UV-levels and alert the user when radiation hits harmful levels.
Gutruf said the research used zinc oxide-present in most sunscreens as a fine powder mixed into a lotion-as the UV sensing material.
#Synchronous Computer Operates on Water Droplets Infused with Magnetic nanoparticles The computer is nearly a decade in the making,
The work combines his expertise in manipulating droplet fluid dynamics with a fundamental element of computer science an operating clock."
Because of its universal nature, the droplet computer can theoretically perform any operation that a conventional electronic computer can crunch,
or to operate word processors on this, "Prakash said.""Our goal is to build a completely new class of computers that can precisely control
and manipulate physical matter. Imagine if when you run a set of computations that not only information is processed
but physical matter is manipulated algorithmically as well. We have made just this possible at the mesoscale.""The ability to precisely control droplets using fluidic computation could have a number of applications in high-throughput biology and chemistry,
and possibly new applications in scalable digital manufacturing. The results are published in the current edition of Nature Physics.
Computer clocks are responsible for nearly every modern convenience. Smartphones, DVRS, airplanes, the Internet without a clock, none of these could operate without frequent and serious complications.
Nearly every computer program requires several simultaneous operations each conducted in a perfect step-by-step manner. A clock makes sure that these operations start
and stop at the same times, thus ensuring that the information synchronizes. The results are dire if a clock isn't present.
"The reason computers work so precisely is that every operation happens synchronously; it's what made digital logic so powerful in the first place,
A magnetic clockdeveloping a clock for a fluid-based computer required some creative thinking. It needed to be easy to manipulate,
allowing observation of computation as it occurs in real time. The presence or absence of a droplet represents the 1s and 0s of binary code
and the clock ensures that all the droplets move in perfect synchrony, and thus the system can run virtually forever without any errors."
and demonstrates building blocks for synchronous logic gates, feedback and cascadability hallmarks of scalable computation. A simple-state machine including 1-bit memory storage (known as"flip-flop")is demonstrated also using the above basic building blocks.
"Prakash said the most immediate application might involve turning the computer into a high-throughput chemistry and biology laboratory.
and the droplet computer offers unprecedented control over these interactions. From the perspective of basic science, part of why the work is so exciting,
is that it opens up a new way of thinking of computation in the physical world.
Although the physics of computation has been applied previously to understand the limits of computation the physical aspects of bits of information has never been exploited as a new way to manipulate matter at the mesoscale (10 microns to 1 millimeter.
Right now, anyone can put these circuits together to form a complex droplet processor with no external control something that was a very difficult challenge previously,
computation takes a special place. We are trying to bring the same kind of exponential scale up because of computation we saw in the digital world into the physical world."
"Source: http://www. stanford. edu n
#Ultracompact Highly sensitive Nanomechanical Sensor Can Detect Viral Disease Markers Two young researchers working at the MIPT Laboratory of Nanooptics and Plasmonics,
and miniature dimensions, allowing it to be used in all portable devices, such as smartphones, wearable electronics, etc.
and transparent displays, and graphene-based on-chip optical communications,"said Hone, Wang Fon-Jen Professor of Mechanical engineering at Columbia Engineering and co-author of the study.
titled'Bright visible light emission from graphene',was published in the Advance Online Publication (AOP) on Nature Nanotechnology's website.
based partly on data from simulations used by the medical community. They found that the gold-bonded iodine-125 emitted six times as many low energy electrons as plain iodine-125.
making it in some cases 3x smaller than other solutions on the market today for wearable devices.
Cube original family of motion sensors was designed for smartphones and tablets which have relatively large batteries,
Internet of Moving Things By 2020, analysts predict more than 50 billion1 devices will be connected to the Internet
From smartphones and tablets to smart clothing and wearables, mcube is enabling a new era called the nternet of Moving Things where the movement
generating valuable data and insights that will transform consumer experiences. n the highly competitive consumer market of inertial sensors,
President & CEO of Yole Développement. perfect fit for the promising market of wearable devices requiring extremely optimized chips in terms of size and power consumption.
Having successfully shipped over 100 million units in smartphones and tablets, mcube is now taking its proven technology
and developing products specifically optimized for the Internet of Moving Things. With the MC3600 product family
enable Iomt devices to power-down other components during user inactivity, dramatically extending battery life. The MC3610 is sampling now
while charging, different processes are at work in the two identical pieces of carbon pongewhich function as the electrodes in these devices, in contrast to earlier computer simulations.
They are used also in flashes in mobile phones and as a complementary technology to batteries in order to boost performance.
Previous theories had been made by computer simulations no one observed this in eal lifebefore. What the experiments showed is that the two electrodes behave differently.
#Keysight Technologies Introduces 9500 AFM With Integrated Software and Hardware for Ultrafast Scan Rates Keysight Technologies, Inc. NYSE:
The Keysight 9500 AFM system seamlessly integrates new software, a new high-bandwidth digital controller,
and a state-of-the-art mechanical design to provide unrivaled scan rates of up to 2 sec/frame (256x256 pixels).
Engineered with scientific and industrial R&d users in mind, the 9500 is the ideal system for an expansive range of advanced AFM applications associated with materials science, life science, polymer science and electrical characterization.
Available as a system option, Quick Scan is controlled through Nanonavigator, a powerful new imaging and analysis software package from Keysight.
In addition to supporting Quick Scan functionality, Nanonavigator software lets researchers save time by using a new Auto Drive feature that automatically and optimally sets all parameters for the 9500.
AFM novices and experts alike can appreciate Nanonavigator's efficient workflow-based GUI as it guides users step-by-step through system setup and operation via intuitive, eye-catching visuals.
For ultimate convenience, the Nanonavigator mobile app for smart phones and tablets allows remote monitoring of AFM experiments
and market leader helping to transform its customers'measurement experience through innovations in wireless, modular,
and software solutions. Keysight's electronic measurement instruments, systems software and services are used in the design, development, manufacture, installation, deployment and operation of electronic equipment.
or'CRYO EM'-imaging samples frozen to-180oc-to show the proteasome complex in such extraordinary detail that they could view a prototype drug bound to its active sites.
The results could help improve scientists'ability to build molecules that interlock very specifically with target sites on proteins-a fundamental part of designing new anticancer drugs.
The research could help other scientists to use CRYO EM in structure-based drug design studies-in which researchers build the best possible drugs starting from a molecule which already binds to the active site of a target protein.
An inhibitor molecule used by the researchers was shown to be visibly bound at each of its three target sites on the proteasome.
and generated images using complex image-processing software. Senior study author Dr Edward Morris, Team Leader in Structural Electron microscopy at The Institute of Cancer Research, London, said:"
we were able to clearly show the target site for potential cancer drugs -and could even show an inhibitor bound in place,
#OSU Scientists Use Microreactor to Create Silver nanoparticles at Room temperature for Printed Electronics There may be broad applications in microelectronics, sensors, energy devices, low emissivity coatings and even transparent displays.
Its highly versatile nature makes it applicable for use in numerous electronics gadgets such as wearables, flexible displays and other sophisticated electronic devices."
such vibrations produce a 300%improvement in the rate of water diffusion by using computers to simulate the flow of water molecules flowing through nanotubes.
Crowdsourcing the solutionthe project, initiated by IBM's World Community Grid, was an experiment in crowdsourced computing--carried out by over 150,
000 volunteers who contributed their own computing power to the research.""Our project won the privilege of using IBM's world community grid, an open platform of users from all around the world,
to run our program and obtain precise results, "said Prof. Urbakh.""This was the first project of this kind in Israel,
and we could never have managed with just four students in the lab. We would have required the equivalent of nearly 40,000 years of processing power on a single computer.
Instead we had the benefit of some 150,000 computing volunteers from all around the world,
who downloaded and ran the project on their laptops and desktop computers.""Crowdsourced computing is playing an increasingly major role in scientific breakthroughs,"Prof.
Urbakh continued.""As our research shows, the range of questions that can benefit from public participation is growing all the time."
"The computer simulations were designed by Ming Ma, who graduated from Tsinghua University and is doing his postdoctoral research in Prof.
Abbey Liebman 0 created a dress using conductive cotton threads capable of charging an iphone.
With ultrathin solar panels for trim and a USB charger tucked into the waist, the Southwest-inspired garment captured enough sunshine to charge cell phones
and other handheld devices allowing the wearer to stay plugged in. The technology may be embedded into shirts to measure heart rate
#Applied Nanotech Tests Ballistic, Blast-Resistant Armor Panels with Printed Electronic Antennas Applied Nanotech, Inc. ANI), a PEN Inc. company (PEN), announces successful completion
and test of fiberglass ballistic and blast-resistant armor panels that incorporate printed electronic antennas capable of sending
The armor-incased antennas also have jamming capability to block radio signals such as those used to remotely trigger explosives,
and bullet-resistant fiberglass panel products manufactured by Armortex.""Applied Nanotech and the university partners have made impressive technology strides to create new applications for our existing product line,
and other threats,"says Dr. Aly Fathy, Professor, Department of Electrical and Computer engineering at UT Knoxville."
modeling and testing,"says Dr. Ahmad Hoorfar, Professor and Director of Antenna Research Laboratory, Department of Electrical and Computer engineering, Villanova University y
From there, he went on to form a core team by hiring a CEO Jeff Draa
Technology areas of interest include cloud applications, analytics, social media, mobile, materials, medical devices, digital health, healthcare IT, instruments and cloud software infrastructure.
Some vertical markets of interest include Retail, Healthcare, Transportation, Insurance, Financial services and Telecommunications. Some technology areas of interest include:
analytical applications, cloud applications, mobile, vertical CRM, cybersecurity and software infrastructure. Vertical Venture Partners will invest at any stage of a company growth
now an NSF funded Iorps Site, has helped more than 200 innovator teams conduct proof of concept studies and market research through a combination of gap funding, expert mentorship and entrepreneurial education.
along with other researchers developed nanoscale particles that introduce silver antimicrobial potency to a biocompatible lignin core.
Upon disposal, the rest of the particles also degrade easily due to their biocompatible lignin core.
and environmentally responsible method to make effective antimicrobials with biomaterial cores. Velev, INVISTA Professor of Chemical and Biomolecular engineering at NC State.
It is a key technology to enable the next generation of portable electronics, such as smartphones and tablets,
The technology is used already in computer hard drives and many other applications and scientists believe it could eventually be used for quantum computers,
The power of this innovative instrument is to simultaneously process large amounts of data, thus addressing a major bottleneck in pharmaceutical research:
rapid, data-rich biomedical imaging. By merging data simultaneously collected by thousands of microlenses optical elements each smaller than the width of a human hair this new multispectral microscope is able to produce a continuous series of datasets that essentially reveal how much of multiple colors
are present at each point in a single biological sample. harmaceutical research is awash with cutting-edge equipment that tries to image
Multispectral Imaging Color and Data Combinemultispectral imaging is used for a variety of scientific and medical research applications.
it also provides data about specific colors, or frequencies, in that image. Medical researchers are able to study these frequencies to learn about the composition
however, is very data intensive and slow since current multispectral microscopes can only survey a single point at a time with few color channels,
Orth and his team took inspiration from modern computing, in which massive amounts of data and calculations are handled simultaneous by multicore processors.
In the case of imaging, however, the work of a single microscope lens is distributed among an entire array or microlenses,
each responsible for collecting multispectral data for a very narrow portion of each sample. To capture this data,
a laser is focused onto a small spot on the sample by each microlens. The laser light causes the sample to fluoresce,
200 by 200 pixels wide. These individual multicolor images were stitched then together into a large mosaic image.
By simultaneously imaging 13 separate colors bands, the dataset produced was nearly 17 billion pixels in size.
The Challenge of Big Datathis novel approach initially presented a challenge in the data pipeline.
The raw data is in the form of one megapixel images recorded at 200 frames per second a data rate much higher than current microscopes
and process a tremendous amount of data each second. Over time, the availability and prices of fast cameras and fast hard drives have come down considerably,
allowing for a much more affordable and efficient design. The current limiting factor is loading the recorded data from hard drives to active computer memory to produce an image.
The researchers estimate that an active memory of about 100 gigabytes to store the raw dataset would improve the entire process even further.
Impact of Big data on Multispectral Imagingthe goal of this technology is to speed up drug discovery.
the team would like to expand to live cell imaging in which billion-pixel, time-lapse movies of cells moving
and this can generate 3d computer models of individual nanoparticles using the movies captured. The movie clips, posted along with the publication, show the unprecedented details of the structure of two platinum nanoparticles.
Particle 1 in action Monash University Youtube. comthe field had expected cubical or at least highly symmetrical platinum nanocrystals. t was surprising to learn that they form asymmetrical multi-domain structures,
and wireless communications to transistors operating at very high speeds. A constantly increasing demand for telecommunication bandwidth requires an ever faster operation of electronic devices,
pushing their response times to be as short as a picosecond. he results of this study will help improve the performance of graphene-based nanoelectronic devices such as ultra-high speed transistors and photodetectorssays Professor Dmitry Turchinovich,
the scientists explain how they used Sticky-flares to quantify ß-actin mrna in Hela cells (the oldest and most commonly used human cell line) as well as to follow the real-time transport of ß-actin mrna in mouse embryonic
Nanoparticles made from these polymers have a hydrophobic core and a hydrophilic shell. Due to molecular-scale forces
BPA, another endocrine-disrupting synthetic compound widely used in plastic bottles and other resinous consumer goods, from thermal printing paper samples;
#Nano Cages Provide New Approach for Structuring Catalysts University of Wisconsin-Madison engineers have developed a new approach to structuring the catalysts used in essential reactions in the chemical and energy fields.
Mavrikakis sees the nano cage structure has opened up a whole new avenue of investigation in synthesizing new catalysts."
Researchers at the University of Wisconsin-Madison designed the system such that the etching of palladium from the core could be understood,
Rapid and Inexpensive Modulator for Future Data Tansmission In February 1880 in his laboratory in Washington the American inventor Alexander graham bell developed a device
which he himself called his greatest achievement, greater even than the telephone: the"photophone"."Bell's idea to transmit spoken words over large distances using light was the forerunner of a technology without
which the modern internet would be unthinkable. Today, huge amounts of data are sent incredibly fast through fibre optic-cables cables as light pulses.
For that purpose they first have to be converted from electrical signals, which are used by computers and telephones, into optical signals.
In Bell's days it was a simple, very thin mirror that turned sound waves into modulated light.
Modern telecommunications use laser light with a wavelength of one and a half micrometers, which accordingly is the lower limit for the size of a modulator.
and thus to create the pulses necessary for data transfer, the researchers use the working principle of an interferometer.
As such a modulator is much smaller than conventional devices it consumes very little energy-only a few thousandth of Watts at a data transmission rate of 70 Gigabits per second.
given that the amount of energy used worldwide for data transmission is considerable-after all, there are modulators in every single fibre optic line.
Every year increasing amounts of data need to be transmitted at ever higher speed, which leads to an increasing energy consumption.
A hundredfold energy saving would, therefore, be more than welcome.""Our modulator provides more communication with less energy,
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