ATTOBahn MOLECULAR NETWORK Brings new
HIGH CAPACITY MOBILE INTERNET
Dr. Rob Longwell
1/5/16
The ATTOBahn is developing a new concept known as Viral
Molecular Network. The Attobahn (pun
intended) is a high speed, high capacity terabits per second (Tbps) wireless
network that has an adoptive mobile backbone and access levels. The network
access nodes are devices installed in transportation vehicles; carried in a
person's pocket on smartphones and tablets or at a corporate office
location.
The access nodes are attracted to each other and form a
molecular networking structure. This molecular network structure is created by
each access device being bonded to their closest neighbor's protonic switch
device, similar to covalent bonds between atoms. The access nodal device
recognizes each other as the vehicle, person, or location enters the local
network molecular theater.
The objective of the ATTOBahn network is to move computing
data, voice, video, movie streaming, high resolution graphics, kinetic
information and interactivity, and virtual reality information on a
terabits per second nationwide wireless network.
terabits per second nationwide wireless network.
The Company offers the first wireless and fibreless
mobile broadband content delivery system capable of scale via a self-healing
architecture. This design provides an alternative ramp to access the
Internet; instead of the legacy quarter of a century old Internet Transport
Protocol (TCP/IP) based system.
Next-generation genomics Next-generation genomics marries
advances in the science of sequencing and modifying genetic material with the
latest big data analytics capabilities. Today, a human genome can be sequenced
in a few hours and for a few thousand dollars, a task that took 13 years
and $2.7 billion to accomplish during the Human Genome Project. With rapid
sequencing and advanced computing power, scientists can systematically test how
genetic variations can bring about specific traits and diseases, rather than
using trial and error. Relatively low-cost desktop sequencing machines could be
used in routine diagnostics, potentially significantly improving treatments by
matching treatments to patients. The next step is synthetic biology—the ability
to precisely customize organisms by “writing” DNA. These advances in the power
and availability of genetic science could have profound impact on medicine,
agriculture, and even the production of high-value substances such as
biofuels—as well as speed up the process of drug discovery. Autonomous and
near-autonomous vehicles It is now possible to create cars, trucks, aircraft,
and boats that are completely or partly autonomous. From drone aircraft on the
battlefield to Google’s selfdriving car, the technologies of machine vision,
artificial intelligence, sensors, and actuators that make these machines
possible is rapidly improving. Over the coming decade, low-cost, commercially
available drones and submersibles could be used for a range of applications.
Autonomous cars and trucks could enable a revolution in ground
transportation—regulations and public acceptance permitting. Short of that,
there is also substantial value in systems that assist drivers in steering,
braking, and collision avoidance. The potential benefits of autonomous cars and
trucks include increased safety, reduced CO2 emissions, more leisure or work
time for motorists (with hands-off driving), and increased productivity in the
trucking industry
ƒ Combinations of technologies
could multiply impact. We see that certain emerging technologies could be used
in combination, reinforcing each other and potentially driving far greater
impact. For example, the combination of next-generation genomics with advances
in nanotechnology has the potential to bring about new forms of targeted cancer
drugs. It is possible that the first commercially available
nano-electromechanical machines (NEMS), molecule-sized machines, could be used
to create very advanced sensors for wearable mobile Internet devices or
Internet of Things applications. And automated knowledge work capabilities
could help drive dramatic advances across many areas, including next-generation
genomics. Another example of symbiotic development exists between advances in
energy storage and renewable energy sources; the ability to store electricity
created by solar or wind helps to integrate renewables into the power grid. The
advances in energy storage that make this possible could benefit, in turn, from
advances in nanomaterials for batteries. Similarly, the mobile Internet might
never live up to its enormous potential without important advances in cloud
computing to enable applications—including tools for automating knowledge
work—on mobile devices
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