Wednesday, June 29, 2011

Slyde HD3 Watch – Latest Technology

HD3 launches SLYDE, the latest creation by avant-garde designer Jorge Hysek. SLYDE takes the underlying principle of the touchscreen technology and allows you to slide on time with a luxury watch offering an infinity of components, movements and complications. SLYDE is a veritable Swiss-made luxury watch, placing all the technological savoir-faire developed for its conception at the service of universal Time. There are no telephone applications, games, or other accessories among the customized modules. All that matters is apprehending Time, whether latent or real.

Slyde HD3 Watch - Latest Technology (video)1

SLYDE watches are available with cases in black or grey titanium or in pink gold, in the purest tradition of Swiss watchmaking. Straps are in leather, printed alligator or rubber (5 colours). Every component of a SLYDE watch, complete with sapphire glass and water-resistant to a depth of 50m, derives from luxury watchmaking. Starting at €4000 (approx. US$5,300), this luxury timepiece is to say the least, expensive.

Slyde HD3 Watch - Latest Technology (video)2

Slyde HD3 Watch - Latest Technology (video)3

SLYDE watch



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Sateesh.smart

New five finger mouse – Amenbo concept!

Double Research & Development Co. has developed a five finger input device for complete hand recognition. Called "amenbo". This new five finger mouse has the capability of tracking each and every minute movements of fingers and thumbs along with the capacity to recognize the pressures exerted on mouse by fingers and sending the same to the computer.  Future technology amenbo 5 pynd

The fingers are all linked by a flexible printed mesh base, that is made stretchable to accommodate a variety of different sizes of hands. A special sensor is attached to each finger, so it can identify which finger on whose hand it is, and even if you lift your fingers off it can follow them from beginning to end. Amenbo enable us to utilize entire hand simplifying the process. One can integrate major operations and finish at one click of Amenbo.  Amenbo -  innovative  input device for sci-fi style computing.   Future technology amenbo 5 pyndFuture technology amenbo 5 pynd Future technology amenbo 5 pyndFuture technology amenbo 5 pyndFuture technology amenbo 5 pynd  Future technology amenbo 5 pynd Future technology amenbo 5 pynd Future technology amenbo 5 pynd



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Sateesh.smart

Digital watch Chro.mo!


Beautiful watch on his arm will always create the perfect mood and attract attention!
David Alejandro Gonzalez and Solis-developed digital watches that look super and dubbed them Chro.mo. It looks like a bacelet and has a very attractive facade. This digital watch would be made in stainless steel and powered with miniature photovoltaic cells. It was designed in Alias Studio Tools. The watch shows the hours in roman numerals and the minutes in a circle that fills as time passes. Future technology Digital watch Chro.mo

Reading time is as interesting as its styling. Hours are displayed in roman numbers on the left, while minutes will blink in a green colored circle placed on the right. As the time moves ahead the circle gets filled, just like the moon grows with each passing day. The timepiece has silver colored edges giving it a royal appeal. Adding to the whole appearance is the delicate design placed both above and below the time reading zone. Chro.mo digital watch is like a delicate piece of jewelry. Adorning one around your wrist is bound to fetch a lot of admiration. Future technology Digital watch Chro.mo Future technology Digital watch Chro.mo


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Sateesh.smart

Concept mobile phone P-Per!


Very good concept mobile phone. The Chocolate Agency released this a concept. A mobile phone is composed of four thin layers, a circuit board, lycarbonate, titanium, and one that is a wrap-around LED touch screen. It's the wrap-around screen that gives the manufacturer endless options for user choices  Future technology Concept mobile phone P-Per

Future technology Concept mobile phone P-PerFuture technology Concept mobile phone P-Per Future technology Concept mobile phone P-Per Future technology Concept mobile phone P-Per



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Sateesh.smart

Eco-friendly chair: uses our body to produce energy


'Go' by Rizki Tarisa is an all-in-one chair that has a desktop, lounge chair, workstation and an exercise machine all in one. Imagine sitting comfortably talking to your friends on MSN, sipping coffee and exercising at once—it's multi-tasking to a whole new level, I tell you. It can even access the Internet! The only catch is that you have to bike for the energy.

Eco-friendly chair - uses our body to produce energy1

The 'Go' by Rizki Tarisa uses a form of energy that we've had all along: it's the next big renewable energy source known to mankind. Well, it is mankind! Yes, that's right, Rizki Tarisa has come up with an idea that uses our body to produce energy. While this idea isn't completely new to the world, the prototype by Tarisa looks more comfortable than the ones I've seen before.

Eco-friendly chair - uses our body to produce energy2

Eco-friendly chair - uses our body to produce energy3

.....Smart.sateesh

Friday, June 10, 2011

Flex iPhone concept !


Designer Fabrice Bardon almost had us thinking that was an unusual iPhone, but then we spotted the Sony Ericsson branding on the device's pictures. Dubbed the Flex iPhone, this handset has nothing in common with Apple's cellphone, but a lot in common with the future and modern devices.

Future of technology Flex iPhone concept

We're dealing with a phone with modern design, thanks to a flexible body, a touch keypad, LCD screen and a shape that reminds us of the older communication devices. Well, the Flex iPhone looks nifty, but let's hope the material it's based on is not as fragile as the pics make it seem…

 Future of technology Flex iPhone concept


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satheesh

Innovate concept of Smartbook


And then I'm ready to go to Geek Heaven! One of the reasons why devices like iPad and other tablets exist is to satisfy this urge in us to stay connected to the web world. Latest touchscreen phone also carry the same incentive, but somehow both the devices have one flaw: tablets lack an external keyboard and phones lack the screen real estate. To bridge the gap we have the really innovative Smartbook; a Smartphone that flips open to become a QWRTY keyboard and syncs with its personalized PC Tablet.

Innovative concept Smartbook concept future technologies

Innovative concept Smartbook concept future Innovative-concept-Smartbook-3 Innovative Smartbook concept future technologies Innovative concept Smartbook concept  technologies Innovative Smartbook concept future technologies Innovative concept Smartbook  future technologies Innovative concept Smartbook future technologies
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satheesh

Coffee Hot Everywhere

iCup is an innovative concept specially designed for Apple that can heat up any drink inside the cup by connecting it with the user's notebook, as well as any device that supports USB connection, via a USB cable  anywhere. The key goal of the project is to ease life with more manageable features that ensure uninterrupted working opportunity, doesn't matter the user goes to the park, library or working in the office. The featured Apple logo of the cup is actually a heat indicator that shows the temperature of the inside content, blue for cool, orange for warm and pink for hot, while enhancing the aesthetics. Moreover, it incorporates a displaceable handle that offers convenient fit into any small area and the changeable upper portion allows easy washing.
Coffee hot everywhere-concept1

Coffee hot everywhere-concept2 Coffee hot everywhere-concept3 Coffee hot everywhere-concept4 Coffee hot everywhere-concept5

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satheesh

Future in 2020


Our Second Brain or "ThingBook"
In the future nearly every visible thing will be cataloged and indexed, ready to be instantly identified and described to us. Want to go shopping? In the future we won't need big retail stores with aisles of objects on display. We'll be able to shop out in the world (see image, above). Do you like that new car you saw drive by? Or those cool shoes on the woman sitting across the room? All you'll have to do is look at it and your mobile handset or AR-equipped eyeglasses will identify the object and look up the best price and retailer.

future tech Future in 2020

Bodynet
Like Google for our bodies, future technologies will allow us to monitor our body's vital conditions and compute the outcome of our actions on-the-fly. So you'll know right away what it's going to take to work off that Burger and Coke.

future in tech 2020

Whuffie Meter
Curious about the future of social networking? Whuffie is a conceptual social Metric based on what others think of you. In the future this Metric might actually be usable as real money. Why not? Celebrities are used to getting things for free based on their popularity. This is the same idea taken to its democratic extreme. Socializing will take on completely new dimensions when we can see everything public about a person right as we are talking with them. Think dating is difficult today? Imagine the hoops we'll have to jump through when everyone in the bar can see your complete dating history the minute you walk into the room.

The term "whuffie," by the way, is a word coined by author Cory Doctorow in his book Down And Out In the Magic Kingdom. It refers to the measurement of respect or karma a person gains or looses in their lives. In Doctorow's future, humans have implants in their brains that visually project their whuffie, which has replaced money as currency.

future of tech 2020


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satheesh

Streamlined rules for robots


New algorithms make it easier to write rules for distributed-computing systems, such as networks of sensors, servers or robots.

New techniques make it easier to calculate the optimal behaviors for fleets of autonomous robots, like these robot planes, working toward some common goal.
Photo: NASA

With the explosion of the Internet and the commoditization of autonomous robots (such as the Roomba) and small sensors (such as the ones in most cell phones), computer scientists have become more and more interested in distributed computing, or how disparate autonomous devices — whether servers in a network or robots investigating an underwater oil spill — can work together toward some common goal.

Distributed devices have to adjust their behavior to changing circumstances. Frequently, however, their understanding of their circumstances is based only on a few local observations — and even those could be slightly inaccurate. Behavior that is perfectly reasonable in one case could prove catastrophic in another that, to a device, looks identical. Device programmers thus have to find behavioral policies that strike a balance between advancing the common goal and minimizing the risk of something going badly wrong.

Optimizing that balance would mean weighing every possible option for each device against all other options for all other devices under all circumstances. For even simple distributed-computing systems, that calculation quickly becomes so complex that it's basically insoluble. But Frans Oliehoek, a postdoc in MIT's Computer Science and Artificial Intelligence Laboratory, is developing new techniques to calculate policies for distributed-computing systems. Although those techniques aren't guaranteed to find the perfect policy, they will usually come pretty close — and they won't take centuries to yield an answer.

To get a clearer idea of the problem, consider a very simple example. Companies such as Google or Facebook maintain server farms with tens of thousands of computers. There's a lot of redundant information on those computers, so that hordes of users can access the same information at the same time. If a given computer is falling behind in handling users' requests, how long should it let its queue of unanswered requests get before it fobs them off on another computer? Ten? Fifteen? A thousand? A million? The optimal answer has to strike a balance among cases where the other servers in the farm are idle, cases where the other servers have even longer queues, and everything in between. A given server may be able to infer something about traffic as a whole by glancing at the queues of the servers next to it. But if it were continually asking all the other servers in the farm about the length of their queues, it would choke the network with queries.

Historical perspective

Making the problem even more complicated, policy has to vary according to a device's history. It may be, for instance, that a robot helicopter trying to find a way into a burning building is much less likely to get itself incinerated if it makes two reconnaissance loops around the building before picking an entry point than if it makes just one. So its policy isn't as simple as, "If you've just completed a loop, fly through the window farthest from the flames." Sometimes it's, "If you've just completed a loop, make another loop." Moreover, if a squadron of helicopters is performing a collective task, the policy for any one of them has to account for all the possible histories of all the others.

In a series of papers presented at the International Conference on Autonomous Agents and Multiagent Systems, Oliehoek and colleagues at several other universities have described a variety of ways to reduce the scale of the policy-calculation problem. "What you want to do is try and decompose the whole big problem into a set of smaller problems that are connected," Oliehoek says. "We now have some methods that seem to work quite well in practice."

The key is to identify cases in which structural features of the problem mean that certain combinations of policies don't need to be evaluated separately. Suppose, for instance, that the goal is to find policies to prevent autonomous helicopters from colliding with each other while investigating a fire. It could be that after certain sequences of events, there's some possibility of helicopter A hitting helicopter B, and of helicopter B hitting helicopter C, but no chance of helicopter A hitting helicopter C. So preventing A from colliding with C doesn't have to factor in to the calculation of the optimal policy. In other cases, it's possible to lump histories together: Different histories can still point to the same result for the same action.

The mathematical model of decision making that Oliehoek has been investigating "is a very general model, so you can model all sorts of decision problems with it," says Francisco Melo, an assistant professor of computer science and engineering at Portugal's Universidade Técnica de Lisboa. "It's a very lively line of work right now." But, Melo, adds, "it's a very complex model. There's not much hope of computing an exact solution except for very, very, very small problems." Melo says that while other researchers have performed theoretical analyses of the complexity of the model, and still others have attempted to find practical algorithms that yield approximations of the ideal policy, Oliehoek's work combines the virtues of both lines of research. "I think that Frans' work is all trying to — from a theoretical point of view — understand, if we actually want to do planning, what sorts of structures can we explore?" Melo says. "And that is also useful when you're trying to make approximate algorithms. So I think that his contributions were important."
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Sateesh.smart

‘Artificial leaf’ moves closer to reality

MIT researchers develop a device that combines a solar cell with a catalyst to split water molecules and generate energy.


An important step toward realizing the dream of an inexpensive and simple "artificial leaf," a device to harness solar energy by splitting water molecules, has been accomplished by two separate teams of researchers at MIT. Both teams produced devices that combine a standard silicon solar cell with a catalyst developed three years ago by professor Daniel Nocera. When submerged in water and exposed to sunlight, the devices cause bubbles of oxygen to separate out of the water.

The next step to producing a full, usable artificial leaf, explains Nocera, the Henry Dreyfus Professor of Energy and professor of chemistry, will be to integrate the final ingredient: an additional catalyst to bubble out the water's hydrogen atoms. In the current devices, hydrogen atoms are simply dissociated into the solution as loose protons and electrons. If a catalyst could produce fully formed hydrogen molecules (H2), the molecules could be used to generate electricity or to make fuel for vehicles. Realization of that step, Nocera says, will be the subject of a forthcoming paper.

The reports by the two teams were published in the journals Energy & Environmental Science on May 12, and the Proceedings of the National Academy of Sciences on June 6. Nocera encouraged two different teams to work on the project so that each could bring their special expertise to addressing the problem, and says the fact that both succeeded "speaks to the versatility of the catalyst system."

Ultimately, Nocera wants to produce a low-cost device that could be used where electricity is unavailable or unreliable. It would consist of a glass container full of water, with a solar cell with the catalysts on its two sides attached to a divider separating the container into two sections. When exposed to the sun, the electrified catalysts would produce two streams of bubbles — hydrogen on one side, oxygen on the other — which could be collected in two tanks, and later recombined through a fuel cell or other device to generate electricity when needed.

"These papers are really important, to show that the catalyst works" when bonded to silicon to make a single device, Nocera says, thus enabling a unit that combines the functions of collecting sunlight and converting it to storable fuel. Silicon is an Earth-abundant and relatively inexpensive material that is widely used and well understood, and the materials used for the catalyst — cobalt and phosphorus — are also abundant and inexpensive.

Putting it together

Marrying the technologies of silicon solar cells with the catalyst material — dubbed Co-Pi for cobalt phosphate — was no trivial matter, explains Tonio Buonassisi, the SMA Assistant Professor of Mechanical Engineering and Manufacturing, who was a co-author of the PNAS paper. That's because the splitting of water by the catalyst creates a "very aggressive" chemical environment that would tend to rapidly degrade the silicon, destroying the device as it operates, he says.

In order to overcome this, both teams had to find ways to protect the silicon surface, while at the same time allowing it to receive the incoming sunlight and to interact with the catalyst.

Professor of Electrical Engineering Vladimir Bulović, who led the other team, says his team's approach was to form the Co-Pi material on the surface of the silicon cell, by first evaporating a layer of pure cobalt metal onto the cell electrode, and then exposing it to a phosphate buffer solution under an electrical charge to transform it into the Co-Pi catalyst. By using the layer of Co-Pi, now firmly bonded to the surface, "we were able to passivate the surface," says Elizabeth Young, a postdoc who was the lead author of the E&ES paper — in other words, it acts as a protective barrier that keeps the silicon from degrading in water.

"Most people have been staying away from silicon for water oxidation, because it forms silicon dioxide" when exposed to water, which is an insulator that would hinder the electrical conductivity of the material, says Ronny Costi, a postdoc on Bulović's team. "We had to find a way of solving that problem," which they did by using the cobalt coating.

Buonassisi's team used a different approach, coating the silicon with a protective layer. "We did it by putting a thin film of indium tin oxide on top," explains Joep Pijpers, a postdoc who was the lead author of the PNAS paper. Using its expertise in the design of silicon devices, that team then concentrated on matching the current output of the solar cell as closely as possible to the current consumption by the (catalyzed) water-splitting reaction. The system still needs to be optimized, Pijpers says, to improve the efficiency by a factor of 10 to bring it to a range comparable to conventional solar cells.

"It's really not trivial, integrating a low-cost, high-performance silicon device with the Co-Pi," Buonassisi says. "There's a substantial amount of innovation in both device processing and architecture."

Both teams had to add an extra power source to the system, because the voltage produced by a single-junction silicon cell is not high enough to use for powering the water-splitting catalyst. In later versions, two or three silicon solar cells will be used in series to provide the needed voltage without the need for any extra power source, the researchers say.

One interesting aspect of these collaborations, says postdoc Mark Winkler, who worked with Buonassisi's team, was that "materials scientists and chemists had to learn to talk to each other." That's trickier than it may sound, he explains, because the two disciplines, even when talking about the same phenomena, tend to use different terminology and even different ways of measuring and displaying certain characteristics.

Portable power?

Nocera's ultimate goal is to produce an "artificial leaf" so simple and so inexpensive that it could be made widely available to the billions of people in the world who lack access to adequate, reliable sources of electricity. What's needed to accomplish that, in addition to stepping up the voltage, is the addition of a second catalyst material to the other side of the silicon cell, Nocera says.

Although the two approaches to bonding the catalyst with a silicon cell appear to produce functioning, stable devices, so far they have only been tested over periods of a few days. The expectation is that they will be stable for long periods, but accelerated aging tests will need to be performed to confirm this.

Rajeshwar Krishnan, Distinguished University Professor of Chemistry and Biochemistry at the University of Texas at Arlington, says it remains to be seen "whether this 'self-healing' catalyst would hold up to several hours of current flow … under rather harsh oxidative conditions." But he adds that these papers "certainly move the science forward. The state of the science in water photo-oxidation uses rather expensive noble metal oxides," whereas this work uses Earth-abundant, low-cost materials. He adds that while there is still no good storage or distribution system in place for hydrogen, "it is likely that the solar photon-to-hydrogen technology will ultimately see the light of day — for transportation applications — with the hydrogen internal combustion engine."

Meanwhile, Nocera has founded a company called Sun Catalytix, which will initially be producing a first-generation system based on the Co-Pi catalyst material, connected by wires to conventional, separate solar cells.

The "leaf" system, by contrast, is "still a science project," Nocera says. "We haven't even gotten to what I would call an engineering design." He hopes, however, that the artificial leaf could become a reality within three years.

Bulović's team was funded partly by the Chesonis Family Foundation and the National Science Foundation. Buonassisi's team had support from the Netherlands Organization for Scientific Research (NOW-FOM), the National Science Foundation and the Chesonis Family Foundation. Nocera's work was funded by the Chesonis Family Foundation, the Air Force Office of Scientific Research and the National Science Foundation.

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Sateesh.smart

Natural gas can play major role in greenhouse gas reductio

The cleanest of fossil fuels, it is far more abundant than previously thought and can have significant impact at little cost, MIT study finds.



Natural gas is important in many sectors of the economy: for generating electricity, as a heat source for industry and buildings, and in chemical feedstock. Given the abundance of natural gas available through extensive global resources and the recent emergence of substantial unconventional supplies in the United States, worldwide usage of the fuel is likely to continue to grow considerably and contribute to significant reductions of greenhouse gas emissions for decades to come, according to a comprehensive, multidisciplinary study carried out over the last three years by MIT researchers.

The study — managed by the MIT Energy Initiative (MITEI) and carried out by a team of Institute faculty, staff and graduate students — examined the scale of U.S. natural gas resources and the potential of this fuel to reduce greenhouse gas emissions. Based on the work of the multidisciplinary team, with advice from a board of 18 leaders from industry, government and environmental groups, the report examines the future of natural gas through 2050 from the perspectives of technology, economics, politics, national security and the environment.

An interim report with some of the study's major findings and recommendations was released in June 2010. The full report, including additional data and extensive new analysis, was released by MITEI this week.

Because it has the lowest carbon content of all fossil fuels, natural gas can play a critical role as a bridge to a low-carbon future. The study's economic analysis of the effects of a national policy calling for a 50 percent reduction in greenhouse gas emissions shows that such a policy would result in widespread substitution of natural gas for coal in electricity generation. However, in order to achieve even greater reductions in carbon emissions — which may be mandated in coming decades — natural gas will in turn need to make way for other low- or zero-carbon sources of energy. It is in this sense that natural gas may be seen as a "bridge" rather than as the ultimate long-term solution itself.

The report says that it is important to continue a robust program of research and development on other energy alternatives, which can be used to take the place of natural gas later in the century if and when emissions regulations become stricter. Henry Jacoby, MIT professor of management and co-chair of the study, said that such research is crucial because "people speak of [natural] gas as a bridge to the future, but there had better be something at the other end of the bridge."

The study found that, contrary to best estimates of a decade or so ago, natural gas supplies are abundant and should be ample even for greatly expanded use of the fuel in coming decades. This is largely the result of the development of "unconventional" sources, such as shale gas. Because of its abundance, widespread distribution and advantages in cost and emissions, use of natural gas is expected to increase substantially under virtually all scenarios involving national policies, regulations and incentives, the study notes.

"Shale gas is transformative for the economy of the United States, and potentially on a global scale" because it has so dramatically increased the amount of gas that can be economically produced domestically, Anthony Meggs, a visiting engineer at the MIT Energy Initiative and co-chair of the study, said at Thursday's press conference introducing the report.

Concerns have been raised about the possible environmental effects of developing shale gas using a controversial process called "fracking" (for hydro-fracturing), which involves injecting fluids into deep horizontal wells under pressure. The ultimate disposal of those fluids after they are pumped back out, and the possibility that they could contaminate water supplies, have been the subject of lawsuits and legislative attempts to limit the practice. The study found that "the environmental impacts of shale development are challenging but manageable," and that some cases of the gas entering freshwater tables were "most likely the result of substandard well-completion practices by a few operators."

Meggs said that in the small number of cases where there has been contamination, the problem has stemmed from improper cementing of the well casings. "The quality of that cementing is the area where the industry, frankly, has to do a better job," he noted. But even so, he said, the study found only 42 documented incidents of such problems, out of tens of thousands of wells drilled. "It is not trivial," he said, "but neither is it all-encompassing." And, he added, even where there are problems, it is possible to go back and fix the well casings later.

The study recommends that to address these concerns, "it is essential that both large and small companies follow industry best practices; that water supply and disposal are coordinated on a regional basis and that improved methods are developed for recycling of returned fracture liquids." Government funding for research on such systems should be "greatly increased in scope and scale," the report says.

The robust supply situation enhances the opportunities for natural gas to substitute for other fuels. Using very efficient natural gas powerplants to replace coal-fired plants is "the most cost-effective way of reducing CO2 emissions in the power sector" over the next 25 to 30 years, the report says. Natural gas will also play a central role in integrating more intermittent renewable sources — wind and solar — into the electricity system because they can easily be brought in and out of service as needed.

The study also finds important opportunities for cost and emissions reduction in industry by switching to very high-efficiency natural gas boilers, and for more efficient energy use in commercial and residential buildings through new standards that would provide consumers information on end-to-end energy use of space- and water-heating alternatives. Furthermore, the current large price difference between oil and natural gas, if sustained, could lead to increased use of gas as a transportation fuel, either directly or through conversion to liquid fuel.

The study group suggests that U.S. national security interests will be served by policies that encourage integration of the presently fragmented global natural gas markets, and calls for better integration of such issues into foreign policy.

The report includes a set of specific proposals for legislative and regulatory policies, as well as recommendations for actions that the energy industry can pursue on its own, to maximize the fuel's impact on mitigating greenhouse gas.

In addressing public concerns about the environmental impact of natural gas drilling operations, the industry could be taking a much more active role, said Ernest Moniz, director of MITEI and chairman of the study. The study makes many specific recommendations for improving well-development procedures, including full disclosure of chemicals used in the hydro-fracturing process and regional coordination on water-use issues. "An endorsement [of these policy recommendations] by industry would be very welcome," Moniz said. "If industry actively promotes them, that can certainly help overcome" these public and legislative concerns.

Ironically, the study found that "public and public-private funding for natural gas research is down substantially," even as the fuel is being recognized as a major contributor to strategies for lowering greenhouse gas emissions, said Melanie Kenderdine, executive director of the MIT Energy Initiative. The study recommends a substantial increase in such research.

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Sateesh.smart

Thursday, June 2, 2011

WARP – concept urban landscape!

WARP – concept urban landscape!

WARP is visualization for clean and green spaces that are self sustainable. With its ingeniousness, it will cake concrete areas with a green coating, which will comprise of both recreational and nutritional vegetation. Urbanization has depleted forest areas, which has further given birth to a lot of problems. This is a sad situation and needs to be changed now. Deforestation adds to the pollution level. The ozone layer is getting thinner and glaciers are melting, which is not a good sign at all. WARP providing shadow, humidity and an aesthetic sense will act as medium that will alter the shape of urban lands in a positive and greener manner. It will also produce micro-climes that will support the green regions on both public and private islands.  Future technology WARP -           concept urban landscape

It is not easy to re-plan a city, as this will mean messing up with all the infrastructures like sewage systems, communication, electrical networks and sub-ways. Also, terrace gardens are not always a feasible option, for the condition of building needs to be analyzed before erecting one. The above conditions pose a great amount of difficulty in terms of planting trees for a better atmosphere. There is no land left, which will provide sol and viable conditions for trees to grow and spread their roots. Even if trees are planted, they will not attain a proper size, which can recover the atmosphere in an effective manner. Future technology WARP -           concept urban landscape

However, the artist has come up with small scale local systems, interconnected with vast networks, which don't have an ill-effect on the ecosystem. WARP has been designed in a way that consists of system of stations that are further coupled with water, sewage, electricity and communication networks. Every station individually harnesses the solar energy, rain water and atmospheric air to ensure cleaner and greener urban ambiance. The energy stored is exploited for lighting and powering the electric grid. On the other, carbon dioxide and nitrogen dioxide act as a nutrient for algae, which produce by-products that cleanse the air and release humidity. Biodiesel is produced by using their (algae) oil, while Ethanol and livestock feed is generated from components that are left behind. WARP also collects water, which can either be used in close-by regions or directed towards a reservoir. The designer has beautifully blended the best from nature and human technology to achieve this project.Future technology WARP -           concept urban landscape Future technology WARP -           concept urban landscape Future technology WARP -           concept urban landscape

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