All of these techniques fit into a field we call technology futures analysis TFA. Over the last years there has been a real explosion of new theory and technological progress supporting a better understanding of these wide-area, fully distributed sensing and computing systems. Perhaps the greatest thing about flexible technology is the large number of theoretical things it could be used for.
Current Flexible Technology Concepts A couple of well-known companies are currently working on flexible electronic devices for the general market, although none are currently available for sale.
An artificial skin embedded with microchips and sensors, however, would allow a person with a prosthetic device to feel textures and pressures and, overall, function almost as well as the real thing. Not only will flexible technology be useful for everyday electronics devices, like cellular phones, hand held music devices, and tablets, but ideas that are more advanced are being floated around.
A new artificial skin made of gold nanoparticals already allows more than ten times the sensitivity of other medical skin replacements. Novel applications for novel e-infrastructures Complex workflow applications Big Data registration, processing and analyses Problem solving environments and virtual laboratories Semantic and knowledge based systems Collaborative infrastructures and virtual organizations Methods for high performance and high throughput computing Urgent computing Scientific, industrial, social and educational implications Education Tools for infrastructure development and monitoring Distributed dynamic resource management and scheduling Information management Methods and tools for internet computing Security aspects.
Computational and storage capabilities, databases, sensors, and people need true collaborative tools. This is the future of flexible technology.
In terms of medical use, one of the most intriguing ideas is the ability to use flexible electronics to create a new type of artificial skin.
However, think about what could be done if the components were flexible instead of rigid. New methods need to be explored to take advantage of information resources and new approaches to complex systems.
Flexible technology promises to revolutionize the manufacturing industry, in fact. These methods have matured rather separately, with little interchange and sharing of information on methods and processes.
Examination of the processes sheds light on ways to improve the usefulness of TFA to a variety of potential users, from corporate managers to national policy makers. This usually results in the item being larger because more space is required for the standard electronic parts. This would be very helpful for those who have lost a limb and depend on prosthetic devices.
Most people have seen the concept of flexible technology used in popular science fiction television series, but have probably never realized just how close to reality they actually are. Items could be manufactured in smaller sizes, because the components could be bent to fit inside smaller spaces.
Implications and Possible Uses While there are no real many companies are making flexible electronics products currently available to the general public, great strides, and researchers are beginning to realize the implications of the technology. There is a range of experience in the use of all of these, but changes in the technologies in which these methods are used—from industrial to information and molecular—make it necessary to reconsider the TFA methods.
Nokia, for instance, is working on a flexible cellular phone that is aptly called the Morph. In fact, scientists and researchers at MIT the Massachusetts Institute of Technologyare studying the use of flexible technology for a variety of practical, medical and scientific purposes.
Toward integration of the field and new methods Address for correspondence Alan L. Imagine a powerful computer that could easily fit into the palm of your hand, and all because the parts were almost paper thin. FGCS aims to lead the way in advances in distributed systems, collaborative environments, high performance and high performance computing, Big Data on such infrastructures as grids, clouds and the Internet of Things IoT.
Samsung, of course, jumped into the fray with a small flexible display that can be rolled up like a scroll, and at CES both Samsung and LG introduced curved OLED television that feature curved displays, which provide a better viewing experience and improve viewing angles.
A flexible monitoring system could also be embedded in a soldiers helmet or clothing, allowing not only their health and bodily statistics to be monitored by an off-site medical technician, but can also transmit environmental information as well, including such things as temperature, wind speeds, sound and concussive pressure.
Current electronics are often bulky and rigid, and when used to build things they must be manufactured in such a way that they fit within the predefined space of the object being built. This results in a product that is often clunky and large.The Wave of the Future for Information Analysis What is GIS?
A Geographic Information System, or GIS, as it is better known, is an electronic GIS is an excellent technology to Geographic Information Systems The Wave of the Future for Information Analysis. This is not an argument against technology — it’s a recommendation for increased systems monitoring and regular conversations with IT managers.
The 21 Bitcoin Computer, is a small, bare. The most downloaded articles from Future Generation Computer Systems in the last 90 days.
Internet of Things (IoT): A vision, architectural elements, and future directions Jayavardhana Gubbi | Rajkumar Buyya |. The technology which has already proved itself in last two decades is of course the information technology (IT).
It has dramatically changed the lives of the individuals and organisations. Currently online shopping, digital marketing, social networking, digital communication and cloud computing etc are the best examples of change which came. Design representations of the future will be hybrid, fusing complex geometric information with physics and machine-learning models.
At the same time, we are seeing the introduction of intricate new materials into a broad range of manufacturing processes. Technology futures analysis: Toward integration of the field and new methods Address for correspondence Alan L.
Porter, Industrial and Systems Engineering and Public Policy, Georgia Institute of Technology, Atlanta, GAUSA.Download