An Inter-Disciplinary Resource Website to Effects on Human Electrodynamic Physiology
www.uncg.edu/~t_hunter/sound.html |
Site Map |
Patent No. 6669094 Method of embedding and recovering encoded item identification information in an emulsion by means of radiant energy (Hodges, Dec 30, 2003)
Abstract
This process and apparatus induces an artificial quantity of a number of sequentially tuned discreet frequencies, in specific bandwidths and timeframes, into an encoded composition target of a number of receptive elemental resonators, not present in natural formations, which respond in kind, with programmed user formulation, by emitting combinations of intelligent pulses at corresponding specific frequencies and time periods. These pulses are detected, from the medium, and are converted to registered combinations of data that are associated with the target identification, providing a better, more comprehensive and cost effective means for the encoding and decoding of individual item identification data, without the use of existing passive identification methods, for collection and management, within existing Supply Chain and Asset Management tracking infrastructures.
Notes:
FIELD
OF THE INVENTION
The present invention relates generally to the field of INVISIBLE RADIANT ENERGY
RESPONSIVE ELECTRIC SIGNALING. This process and apparatus induces an artificial
quantity of sequentially tuned frequencies, in and above, the Near Infrared
bandwidth, at specific time frames, into an encoded composition target of receptive
elemental resonators, not present in natural formations, which respond in kind,
with programmed user formulation, by emitting combinations of intelligent pulses.
These pulses are received, by a Collector, and converted to data, specifying
the target signature and/or identification.
BACKGROUND
The need to identify an item forms the roots of all languages and enables societies
to formulate growth and stability, based on this information. However, the multitude
of languages and the various designations, of a specific item, had often created
difficulties in cross-linguistic exchanges.
In commerce, a common language of numerical indicators was applied, leading
to UPC bar-coding methods and improved methods of categorization for every item
on earth. Managing these categories has become a significant task. Supply Chain
Management has become a substantial industry, focusing on the simple question,
"Where is that item?" The latest entry, into the solution suite of techniques
used to identify and track items, is Radio Frequency Identification (RFID).
Through the use of a microchip, placed upon an item, a radio transponder is
able to `read` the digital information, programmed into the chip that identifies
the host item and relay this information back to an infrastructure of data correlation
and reporting. Vast, worldwide infrastructures have been created to `track`
these RFID tags. The use of RFID to track Conveyance (container) devices has
proven to be the most beneficial, technical and economically sound application
to date.
The major drawback to current RFID tagging technology: The Conveyance may arrive,
but the individual items, contained within, may not. RFID microchips are unable
to be produced economically low enough, and are unable to overcome limitations
in the upper bandwidths of the electromagnetic spectrum, to be applied at the
`item level`.
This invention addresses the need for an `item level` identification medium,
that will be able to interface with existing supply chain infrastructures and
provide the next level in item identification technology.
To begin the explanation of how this invention (SMEAR) functions, an overview
of why it is possible, should be presented.
A photon is an elementary particle, traveling at the speed of light. In itself,
it does not carry energy and energy properties cannot be assigned to it, either
in a single photon or a wave. The exchange rate, of the photon's less potential
energy perimeter, inward to the highest potential energy concentration, produces
resonant properties at a specific rate or frequency, identifying the particle
properties. Imparted energy output, equated to each particle, is a result of
an encounter with a mass of dissimilar (from the particle) constituent particles,
resonating at a state of dynamic equilibrium.
During, and resulting from, the dissimilar particle encounter, hereunder known
as a Photon Event (FIG. 2), each particle exchange has an energy output of 2
eV during the 10E.sup.-27 second event (202), thus producing `noise`, in a number
of beat and superposition bandwidths.
This is the period at which Light properties are exhibited and energy outputs
are registered.
For categorizing, the base frequency of a single photon, determines the model
and properties of the element, to which the photon is associated (FIG. 4).
Presently, there are two ways to detect these residual photon emissions in the
lower wavelengths; a) through radio-reception techniques, in a bandwidth from
30 MHz to 1 Thz. (Present day heterodyne receivers, used in the upper frequencies,
are pushing the quantum limit of the superconductor-insulator-superconductor
(SIS) material used in the receivers at 700 GHz). And b) Optically, by use of
conventional telescopes and image enhancement systems and spectrometry techniques,
to graphically interpret the frequencies of photons, providing specific signatures
to their origins. However, with these present day radio and spectroscopic technologies,
limits have been reached in the application of these particles.
The inspiration, behind this invention, was to utilize existing infrastructures
of data collection processes and incorporate quantum mechanisms into the area
of `item-level` data detection and collection, through the down-conversion of
the above mentioned photon event properties, originating above the 700 nm bandwidth,
and resonating downward, to the Near Infrared (1 .mu.m-100 .mu.m) bandwidth
of the electromagnetic spectrum (FIG. 5).
SUMMARY OF THE INVENTION
The present invention is directed to a method of embedding and recovering encoded
item identification information in a multi-element emulsion (Smear) which comprises
(a) item specific data in a predetermined item identification code format, in
a substrate, with a polymer marking material having multiple states corresponding
to a specific series of absorption spectrums, changing to multiple second states
corresponding to a specific series of emitted frequency spectrums; and (b) thereafter
effecting multiple specific reactive frequency changes of the encoded polymer
marking material from the first state to multiple second states (c) producing
binary data radiant emissions which can be detected in the Near Infrared, and
above, bandwidth and associated to individual items.