AMD Geode GX S Best processors

The AMD Geode™ GX Single Board Computer (SBC) Reference Design Kit (RDK) is a compact, low-power, high-performance tool developed to enable the next generation of single-board computing and network appliances. Virtually manufacture-ready, the RDK is designed to deliver low total cost of ownership and provide a complete system design package that gives designers flexibility, versatility, and enhanced capabilities in a small-sized package (approximately 5.5" x 5"). The RDK is driven by the AMD Geode GX 466@0.9W processor and complemented by the CS5536 companion chip which provides general I/O support, including USB 2.0, audio, and ATA 100. The RDK is supported by General Software's industry leading Embedded BIOS® with StrongFrame™ Technology.Embedded BIOS® with StrongFrame™ Technology, provides maximum configurability with high-level firmware tools and full source code for the core BIOS. With modular architecture, custom adaptations of the BIOS can be made with ease, speed, and power.Embedded BIOS® with StrongFrame™ Technology FEATURES:· Over 850 configuration options· Advanced firmware applications, available as options, provide boot security, high availability and platform updates· USB: USB 2.0, Legacy keyboard and mouse, USB boot (optional)

Amd Opteron Model IBM Processor

This AMD Opteron processor option provides a highly scalable architecture that delivers next-generation performance as well as a flexible upgrade path from 32- to 64-bit computing. With a single architecture designed to meet current and future business needs, the AMD Opteron processor can help to minimize the integration complexities presented by current business environments and answer future business growth needs. This evolutionary processor provides a dramatic leap forward in compatibility, performance and investment protection and can help significantly reduce the total cost of ownership (TCO) variable. The AMD Opteron processor is offered in three models, the 244, 246 and the 248, ranging in processor speeds and is supported by 1MB of L2 cache on all modelsSupports large memory addressability for data-intensive applications, allowing for optimal performance and improved productivity in your work environments. Flexibility Minimizes integration complexities by providing simultaneous high performance 32- and 64-bit computing Provides the flexibility and scalability for demanding enterprise-class applications. Provides flexibility with a scalable design, delivering the headroom needed for future applications. Investment Protection Provides lower cost of ownership, helping with long-term IT investment protection Provides an investment with a long-span potential thanks to the performance upgrade capabilities inherent in the AMD Opteron processor Allows you to better manage the transition cost and timing of your application suite's 64-bit migration

Processors - AMD DURON 650 MHz

AMD presents Duron processor, once again setting the standard for business and home users in the value PC space. Optimized for the value-conscious user, the AMD Duron processor reinforces AMD's leadership position in delivering better computing solutions to the value PC space.??The AMD Duron processor offers value conscious buyers access to technology and performance that stands out among other processors in its class. Employing an innovative design, the AMD Duron processor features sophisticated cache architecture, a high-speed front-side bus, and a super-scalar floating-point unit with enhanced 3DNow! technology. Designed to help prolong the life of a buyer's investment, the AMD Duron processor provides the capability and flexibility to meet the computing needs of value conscious users today and tomorrow. AMD Duron processor-based systems are ideal for applications typically employed by such users, including surfing the Internet, business and personal productivity suites.

what is Nanotechnology

A basic definition:- Nanotechnology is the engineering of functional systems at the molecular scale. This covers both current work and concepts that are more advanced.
In its original sense, 'nanotechnology' refers to the projected ability to construct items from the bottom up, using techniques and tools being developed today to make complete, high performance products.

The Meaning of Nanotechnology :- When K. Eric Drexler popularized the word 'nanotechnology' in the 1980's, he was talking about building machines on the scale of molecules, a few nanometers wide—motors, robot arms, and even whole computers, far smaller than a cell. Drexler spent the next ten years describing and analyzing these incredible devices, and responding to accusations of science fiction. Meanwhile, mundane technology was developing the ability to build simple structures on a molecular scale. As nanotechnology became an accepted concept, the meaning of the word shifted to encompass the simpler kinds of nanometer-scale technology. The U.S. National Nanotechnology Initiative was created to fund this kind of nanotech: their definition includes anything smaller than 100 nanometers with novel properties.
Much of the work being done today that carries the name 'nanotechnology' is not nanotechnology in the original meaning of the word. Nanotechnology, in its traditional sense, means building things from the bottom up, with atomic precision. This theoretical capability was envisioned as early as 1959 by the renowned physicist Richard Feynman.
I want to build a billion tiny factories, models of each other, which are manufacturing simultaneously. . . The principles of physics, as far as I can see, do not speak against the possibility of maneuvering things atom by atom. It is not an attempt to violate any laws; it is something, in principle, that can be done; but in practice, it has not been done because we are too big. — Richard Feynman, Nobel Prize winner in physics
Based on Feynman's vision of miniature factories using nanomachines to build complex products, advanced nanotechnology (sometimes referred to as molecular manufacturing) will make use of positionally-controlled mechanochemistry guided by molecular machine systems. Formulating a roadmap for development of this kind of nanotechnology is now an objective of a broadly based technology roadmap project led by Battelle (the manager of several U.S. National Laboratories) and the Foresight Nanotech Institute.
Shortly after this envisioned molecular machinery is created, it will result in a manufacturing revolution, probably causing severe disruption. It also has serious economic, social, environmental, and military implications.
Four Generations Mihail (Mike) Roco of the U.S. National Nanotechnology Initiative has described four generations of nanotechnology development (see chart below). The current era, as Roco depicts it, is that of passive nanostructures, materials designed to perform one task. The second phase, which we are just entering, introduces active nanostructures for multitasking; for example, actuators, drug delivery devices, and sensors. The third generation is expected to begin emerging around 2010 and will feature nanosystems with thousands of interacting components. A few years after that, the first integrated nanosystems, functioning (according to Roco) much like a mammalian cell with hierarchical systems within systems, are expected to be developed.

Some experts may still insist that nanotechnology can refer to measurement or visualization at the scale of 1-100 nanometers, but a consensus seems to be forming around the idea (put forward by the NNI's Mike Roco) that control and restructuring of matter at the nanoscale is a necessary element. CRN's definition is a bit more precise than that, but as work progresses through the four generations of nanotechnology leading up to molecular nanosystems, which will include molecular manufacturing, we think it will become increasingly obvious that "engineering of functional systems at the molecular scale" is what nanotech is really all about.