The Dawn of a New Spectrum, Part 2

Intellectual Property of Mark Lewellyn Lindsey

  The AirWaves Hyper-Narrow-band, Cloud-Enabled, Spread-Spectrum, Quantum-Optical
(RF) Traffic Managagement Command and Control System (AWSUM) utilizes state of
the art Quantum Linear Optics Technology, which, up until aproximately one year
ago, was purely theoretical. Within the passage of a few short months Universal
Linear Optics has become a fact and the ground breaking creation of the first 
chip based Quatum Optical Circut incorporating a number of Quatnum Technologies
is also a fact (Credit: Ultrafast Optical Processing Group, Institut National de 
la Recherche Scientifique). Quantum entangled photons are the heart of the AWSUM
system allowing virtually unprecidented quantum computations in hybrid communica-
tions and encryption systems, and, system of systems. The Quantum Optical Chip is 
made of glass and silicon utilizing standard semiconductor technology. The single
integrated chip is compatible with existing fiber optic and semiconductor appli-
cations and provides the means to design and deploy quantum circuits directly 
into the AWSUM module.

   The AWSUM module is a small-form-factor, portable plug-and-play eco-system 
which has been designed to connect to existing communications systems via the
modules Full Duplex Async/Sync, switch selectable data-rate, multi-mode fiber
optic to Thunderbolt v3/USB 3.1 gen.2 interface. The AWSUM module encorporates 
intelligent fiber optic distrobution management which increases network perfor-
mance, ensures reliability, provides traffic switching, load balancing, network 
backup and dark fiber restore services. The cloud enabled quantum processing and
universal linear optical chipset utilizing photonic circuitry is capable of a
host of processes and quantum computations simultaniously. The AWSUM mudule will 
operate in 6 modes and 15 cascaded Mach-Zehnder Inteferometers with 30 thermally
driven phaseshifters set arbitrarily and monitored via photon detection sensor 
arrays.

    The heralded quantum logic, entangling gate enabled, boson sampling with 6
complex hadamards boasting 100 Harr random unitaries implementation with an
average fidelity of 0.999 +/- 0.001 and is capable of implementing any linear 
optical protocol, including parsing quantum noise. The chip is fully reprogra-
mable and can encode and manipulate photons. 6 waveguides for linear optical 
transformation and integrated interferometers superimpose one photon beam over
another to detect anomalies in the phase or intensity, which, allows a range of
quantum processor operations to be conducted simultaneously. the stability and 
rapid reprogramability of the chip is accomplished through direct software code
dynamic pipeline capable of scaling up or down and/or increaseing or decreasing
capacity on-the-fly, in real-time. Additionally, the chip has the ability to
perform arbitrary classical digital computations.

    The AWSUM modules narrow-band (RF) radio signal conversion architecture can
convert a single information bearing radio signal into 400 sub-noise mircro-
threads which are the same frequency and carry the same signal but at an enlarged
spectrum of 10 ghz, all of which travel in a single fiber optic thread. The
Hybrid Spectral Optic key technique encodes each micro-thread with the original
information bearing signal on the spread-spectrum analog front end and then
returns the sub-noise micro-threads to their original information bearing signal
upon transmition to the back-end. At virtually no power consumption the overall 
spread spectrum micro-threads are immune to jamming, electronic countermeasures
and power modifications. With no "Snap-Back' the spread of the spectrum stays
spread and is seen as filterable ordinary radio frequency noise. The sub-noise 
micro-threads are recieved even when electronic countermeasures attempt a 100,000
times more powerfull jam. The technique creates a interference resistant and jam
proof system. The micro-threads inside a single fiber optic thread can perform 
more high speed signal processes than our fastest super computers.

    Imagine being able to isolate the sound of a snapping twig during a 140 mph 
category 5 hurricane, or detecting the strike of a match during the detonation of
a thermal nuclear device. Virtually all audio detection devices and transcievers
are incapable of detecting the sub-noise spread-spectrum micro-thread signals, 
including advanced military foundational technologies. The system links are 
designed without signal interfearence folters due to the fact that the sub-noise
spread-spectrum micro-thread signals are so weak only the hybrid AWSUM module can
detect and decode them. As stated in part 1 of this series of articles the AWSUM
system is a deep-learning intelligent system which leverages and optimizes the
intersection between Quantum Computing, Classical Computing and Artificial 
Intelligence. The data, which is the product of different languages operating on
various platforms, in diverse geographic locations and across numerous domains,
is called the unified stream of intelligence. The enviroment which the unified
stream of intelligence is a by-product of, is as dynamic and complex as any 
system that occurs naturally without human intervention. The advanced mapping and
realtime awareness of the unified stream of intelligence dynamically determines
the load that at any time is being applied to the electromagnetic spectrum, that
load, or usage, across frequencies, geography and time, creates an accurate
picture of the spectrum in a complex enviroment. The AWSUM module automatically
allocates the spectrum usage via the off-band spectrum monitor which utilizes
physical layer optical fiber matrix switch technology producing a highly reliable
architecture with no single point of failure.

    The AWSUM module supports Otical, Wireless, DSL, Ethernet and TCP/IP tech-
nologies with voice, data, video, private line, internet and cloud services. the 
system supports the use of vast quantities of under-utilized electromagnetic
spectrum with a high level of security and privacy which allows free and
effective use of the spectrum on a global basis. The AWSUM system makes HTTPS
wireless services available to everyone, everywhere without cost. A critical
element required for international infrastructure collaboration and integration
of commerce, banking, telecommunications, power distrobutions, signal sequence
synchronization and satellite system utilization is the entire timing network.
The AWSUM module incorporates a hybrid atomic clock chip which enables
enhanced collaborative capabilities, resiliency to disruptions in timing synchro-
nization networks and reduces reliance on less advanced atomic clock technologies
which suffer from temperature sensativity, long term frequency aging and retrace
bugs. The atomic clock chip is very low power, heat resistant, anti-aging and
is critical to precise timing. All of the AWSUM module chip sets are micro-
architecture, low power optical circuit enabled hybrids residing on a small form-
factor motherboard.

    The most novel aspect of the AWSUM system is that the very low frequency
transmitions hide, or are hidden, inside naturally occuring radio interference
noise created by the enviroment we live in. While interference does not affect
the sub-noise spread spectrum micro-thread's signal it does affect virtually all
other electronic devices, which have built in filters to isolate and dispose of
the noise. The AWSUM module redirects the filter output of the electronic devices
and seperates the actual noise from the sub-noise spread spectrum micro-thread
information bearing signal and then reconverts it to its original information
bearing signal. This approach acomplishes two important functions. The first is
that it relies on the electronic device to seperate the signal noise from the
broadcast signal and secondly it allows the electronic device to utilize its
own filtering architecture to redirect the signal noise to the AWSUM module. The 
same aproach, only in reverse, applies to encoding the micro-threads into sub-
noise from the broadcast signal. The micro-thread spread spectrum sub-noise is
is broacast from a ground station, as noise, that is piggybacked on controlled
data flow from a satellite uplink station to the satellite services platform in
the Galileo Satellite Constelation. There the transmition is seperated and re-
attached to piggyback onto the satellites downlink broadcast DSSS signal which is
recieved by every satellite navigation system globaly. Dark Fiber restore service
utilizes the same approach using the COPAS/SARSAT Satellite System which recently
became feedback enabled. The COPAS/SARSAT signals are broadcast and recieved by
every transponder in every aircraft and ship on the planet.

    Military communications and radar systems, civilian aviation communication
and radar systems, governmental weather radar systems and governmental emergency
broadcast systems are exempt from the system and continue to utilize the much
more available and hopefully less contested prime frequency ranges between 2 Mhz
and 6 Mhz. The use of the Galileo satelite Contelations will bring world wide
coverage, with limited exceptions, to areas of the planet which were previously
so remote that no service of any nature was available except through traffic
relay stations operated in military theaters during hostilities.