CA2688869A1 - Electro-magnetic oil extraction - Google Patents

Abstract

This invention provides method(s) and system(s) of applying combinations of electromagnetic energy waves to improve and extend the tasks of extracting or purifying desired substance(s) that co-exist as component(s) of more complex 'carrier' material(s). Other uses could be to more precisely control extraction-purification of substance(s) from material(s) (such as, but not limited to, chemical compounds, organic mixtures, etcetera ) at places such as, but not limited to: medical laboratories, pharmaceutical labs, etcetera.
Composite electromagnetic waves are projected into the target material(s) to heat and/or cool the target substance(s) molecules, thereby facilitating extraction-purification for any number of, and any types of Substance(s) and/or any number of, and any type of Material(s).

Description

Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 1 of 30 Inventor: Daniel W. Onischuk, 9628-1 OOA St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.
INVENTION TITLE

Electro-Magnetic Oil Extraction Process DESCRIPTION
Purpose of Invention: Oil Extraction &/or Purification Technical Problems Resolved:

1. improved energy efficiency over conventional method(s);

2. improve purity of substance(s) recovered from target material(s);

3. reduce emissions of greenhouse gases such as CO, C02;

4. reduce pollutants produced /extracted by alternative methods;
Invention Uses:

1. Oilsands extraction processing;
2. Oil purification at refineries;

3. Laboratory extraction and/or purification of substance(s) or material(s);
4. Any process of extraction or purification involving heating;

Background of Invention:

This invention was originally conceived without reference to existing patents -see attached non-published email to witnesses from government, academic and media. Lacking the resources and facilities to do any research, I have waited for some verifiable proof that this concept is viable before filing this patent. A few days ago, I found the recent work of Dr. A.
Kumar at http://www.mwrf.com/Articles/Index.cfm?ArticlelD=22024 which does state this concept is feasible. My patent concept differs and improves significantly from Dr. Kumar's proposal by my methods of energy delivery, process control and analysis. This invention is unique from any of the 21 existing CIPO patents, which I have searched per attached page.

Page 1 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 2 of 30 Inventor: Daniel W. Onischuk, 9628-1 OOA St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.

The purpose of this patent is to overcome the following disadvantages and limitations of any potentially similar patents by defining:

a. more efficient, more effective delivery of Electro-Magnetic (EM) energy to material(s), desired substance(s);

b. enables controllable, variable and greater depth of penetration of EM
energy - enabling higher rate and higher quality of extraction-purification of the desired substance(s);

c. optional concurrent extraction-purification of multiple desired substance(s);

d. compensative feedback to control extraction-purification of desired substances(s);

e. enabling prioritized sequenced or concurrent extraction-purification of substance(s);
f. reducing and/or controlling the related emissions of greenhouse gas(es) production relative to the extraction-purification of the desired substance(s);

g. controlling the production of any other non-desirable substance(s) or materials;

h. improved quality monitoring and feedback control to improve energy efficiency, speed and quality of desired substance extraction-purification, reduction of greenhouse gas(es) and/or other non-desirable substance(s), and overall process effectiveness;

i. fundamental concepts of vital data storage, retrieval, analysis, and utilization that are characteristic of some of the basic requirements to fulfill implementation of this invention;
Page 2 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 3 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.
Summary of Invention The present invention provides method(s) and system(s) of applying combinations of electro-magnetic energy waves to improve and extend the tasks of extracting or purifying desired substance(s) that co-exist as component(s) of more complex `carrier' material(s).
An example of this is oil 'bitumen tar' soaked into the sands of the Athabasca Oilsands, found near Ft. McMurray, Alberta, Canada (near where I live).

Other uses could be to more precisely control extraction-purification of substance(s) from material(s) (such as, but not limited to: chemical compounds, organic mixtures, etcetera) at places such as, but not limited to: medical laboratories, pharmaceutical labs, etcetera.

However, the particular systems discussed herein are given as some of the illustrations of particular embodiments of the invention (to be presented at a later date).
Other embodiments of the invention are expected to employ differing degrees of process automation, material and substance analysis and characteristics profiling, AI-KE, data handling, etcetera. The systems taught and described herein are not intended to limit the application of the method claimed. The method of the invention must involve instrumentalities and combinations having different manifestations of representation or characteristics to suit the many corresponding physical limitations, capabilities, or requirements that bear on any particular extraction-purification process or the currently available technology and any advances in scientific or technical knowledge used to achieve the same or similar purposes of this invention. The spirit of this invention will be fulfilled as long as the principles of ensuring safe, reliable, energy efficient, lower pollution extraction or purification of substances or materials via EM wave heating and/or cooling by the methods of this invention.

Accordingly, it is an object of the present invention to provide methods and processes of EM wave heating and/or EM wave cooling that allows legal entities or their proxies or their agents or their representatives to perform tasks such as, but not limited to: extraction Page 3 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 4 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.
and/or purification of hydrocarbon liquid(s) and/or hydrocarbon gas(es) and/or hydrocarbon plasma(s) derived or obtained from the oilsands or any other sources - by applying any number of combinations of EM wave heating and/or EM wave cooling of materials and/or substances, according to the claims, steps and methods of this invention and any future derivations or enhancements of this invention.

It is a further object of the invention to to provide methods and processes of EM wave heating and/or EM wave cooling that allows legal entities or their proxies or their agents or their representatives to perform tasks such as, but not limited to:
purification-refinement of any solids, liquid(s), gas(es) and/or plasma(s) from derived from any sources -by applying any number of combinations of EM wave heating and/or EM wave cooling of materials and/or substances, to the claims, steps and methods of this invention and any future derivations or enhancements of this invention.

It is a further object of the invention to provide process controls, quality controls, energy controls, safety controls, analytical controls, and pollutant controls capabilities in this invention that utilizes any physical, mechanical, electronic, optical, quantum mechanics, chemical, biological or any other means of reliably and accurately performing, recording, retrieving and/or transmitting signals and information to achieve optimal results of any objects of this invention and any future derivations or enhancements of this invention.

It is evident that those skilled in the art may now make numerous other uses and modifications of and departures from the specific embodiments described herein without departing from the inventive concepts - such as, but not limited to the extraction and/or purification of other substances. Consequently, this invention is to be construed as embracing each novel feature or novel combination of novel features present in or possessed by the methods and techniques herein disclosed, and so this invention is NOT
to be limited by the spirit or scope of any or all of the appended claims.

Page 4 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 5 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.

In addition to the foregoing, further, objects, features, and advantages of the present invention should become more readily apparent to those skilled in the art upon a reading of the following detailed description, in conjunction with the (future) drawings, wherein there will be shown and illustrated examples of embodiments of the invention.

There are NO drawings for this invention at this time.
Detailed Description of Invention Preamble All methods within the broad scope of data processing may be applied to this invention; in particular this invention includes the means and methods of acquiring data from any remote or local data source, or of any type that relates to the specifications of this inventions Extraction-Purification (EP) process; furthermore these methods include:

a.) The steps such as, but not limited to: locating, detecting, testing, reading, receiving, interpreting, evaluating, translating, correcting, reporting and transmitting;
of any number, any quantity, and any combination of data such as but not limited to: symbolic codes, alpha-numeric data, voice data, electronic data, such as, but not limited to:
physical characteristics and properties, electro-magnetic characteristics and properties; chemical characteristics and properties, physical structures, optical structures, optical devices, electronic devices, electronic structures, magnetic fields, magnetic devices, organic chemicals, inorganic chemicals, organic compounds, inorganic compounds, biological materials, genetic materials or genetic structures or genetic sequences, special materials, crystal structures, plastics, metals, gas emissions, electromagnetic radiation, radioactive materials, optical emissions, for any type and any number of, and any combination of natural or synthetic Material, Substance or a plurality of Materials and/or Substances Page 5 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 6 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright (D 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.

b.) whereby the aforementioned tasks of a) above are performed by any combination of :
b.1.) any number of persons, or other legal entities;

b.2.) any number of data acquisition, and data transmission devices;
b.3.) any number of electronic, optical or biological computing devices;
b.4.) any number of communication devices and communication networks;
b.5.) any number of any type of man-made device or plurality of devices;

the methods of locating, receiving, detecting, interpreting, translating, reporting, and transmitting error free data, and the further steps of locating, receiving, detecting, interpreting, translating, reporting transmitting, and correcting compromised data, erroneous data, duplicate data or duplicate transmissions; and the correlated steps and methods of transmitting data to, and receiving data from, any number of humans, computers, man-made devices, telephones, the Internet or any other communications networks; including the methods of translating human and device readable codes to modes, protocols or methods of communication and transmission.

Disclosure of Invention The methods and steps involved in the extraction-purification of any number of DESIRED
SUBSTANCE(s) ( DS ) from at least one TARGET MATERIAL (TM ). The steps and methods described herein are claimed to be unique and are the first of many of my improvements to any existing patents within this scope of invention.

1. Through the use of Electro-Magnetic waves being applied to the carrier material (CM), a highly efficient method of heating the molecules of the desired substance(s) (DS) results in improved ability to extract the DS from the carrier material which may be further supplemented by methods such as, but not limited to: pumping, suction, filtering, repeated application of this invention, etcetera.

Page 6 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 7 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.

2. People gather at least one set of carrier material samples, along with their original location coordinates, from a proposed target area; and then manually determine and use any number of analytical devices and any number of computers running software programs, to determine, assemble and organize a list of desired substances and undesired substances in the carrier material sample; and for any number and any type of substancesõ thereafter perform calculations such as, but not limited to:
absolute concentrations, purity, mass yield, volume yields, potentially resulting by applying the steps and methods of this invention.

3. Desired substances (DS) are agitated to higher energy states by imparting the energy of Electro-Magnetic (EM) waves emitted from transmitter(s) adjusted by people and/or computers running software programs and/or micro-processors that are running software programs, and any other related devices, so as to emit EM waves at one (or more) frequencies, so as to be at or near the RESONANT FREQUENCY (EM RESONANT
WAVE(s)) (or any other other effective frequency) of the DS(s) molecular bonds.

An example of this is a microwave oven exciting water molecules to heat/boil water.
The water molecules are comprised of O(+) and OH(-) ions that are polarized, having a bonding angle of about 103.4 degrees which enables the molecules to be agitated easily by microwave energy that is specifically tuned to heat water molecules.
The temperature of any substance can be determined by using devices such as a pyrometer or an infrared spectrometer which can record the absorption bands for water vapor at EM wavelengths such as 1.4 and 1.85 microns to determine the presence of water vapour. Other spectrometers can detect ultraviolet emissions at 309 nanometers, a telltale sign of hydroxyl (OH) radicals created when water molecules break apart from EM waves in the UltraViolet region of light. This gives us methods of detecting the heating effects of this invention when water vapour is present. Similarly, the extraction-purification of polarized Desired Substances (DS) Page 7 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 8 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5K0V8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.

can be done by matching EM wave frequency(s) to match the DS's EM wave sensitive properties, and similar detection methods may also be applied to the DS
emissions.
In addition, or alternatively, other substances in the carrier material, such as water, can be agitated by EM waves tuned to their specific EM sensitive properties, and so also heat a DS to enable its co-extraction and later separation by this or other means.
(c) For this invention, I also hypothesize and claim the reverse concept of heating by EM waves - since we can heat substances by imparting energy at or near their resonant frequency, we can also effectively lower temperatures of substances or inhibit heating by applying energy at anti-resonant frequencies that will slow the molecular vibrations, and therefore inhibit the heating of unDesired Substances (UDS).
Thereby further maximizing the production and/or purity of the Desired Substance(s).

4. (a) A unique claim of this invention is to combine or "piggyback" the RESONANT EM
wave described in the previous item 2 above, onto a "carrier" wave to enable deeper and variable controlled depth penetration into the target material. This piggybacking is known as "modulation" in electronics terminology - more specifically as frequency modulation that is used commonly in radio broadcasting ( e.g. FM radio ) whereby the intelligence or music is effectively broadcast or "carried" on another frequency.
Similarly, in this invention, we can piggyback the extraction-purification EM
wave(s) onto another EM wave 'carrier' signal to enable deeper penetration into the material.
For example, the principles and frequencies employed by GROUND PENETRATING
RADAR ( GPR) are ideally suited for and were an inspirational basis for this invention (as is are my advanced education training in Electronics, Instrumentation Controls, Computer & Software Engineering. However, I will not bog this patent application in formulas, but will instead focus on general descriptions for refinement later.

Page 8 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 9 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.

(b) That this invention shall also include methods of process control such as, but not limited to: Proportional-Integral -Derivative Feedback Control, predictive controls;
and the further steps and methods of signal processing such as, but not limited to:
Companding, Modulation, de-Modulation; frequency phase-shifting, frequency phase-splitting, filtering, echo-suppression, etcetera - and any other steps and methods of electro-magnetic energy wave transmission, processing and controls.

5. A key component of this invention is acquiring, analyzing and quickly applying information from process analytical devices, process control devices, computer software, computer databases, human decisions, human research, and other sources to organize and construct locally-relevant information that expedites efficient extraction-purification processing. Systems referred to generally, or taught herein for accomplishing these tasks in several ways, such as, but not limited to:

A.) PRE-PROCESS tasks such as analyzing the location, position, composition and concentration of carrier material(s), desired substance(s), and undesired substance(s) so as to provide informative, timely feedback to optimize this inventions related processes such as, but not limited to:

(i) specify the EM energy delivery to target material(s) and desired substance(s);
(ii) identification and/or analysis of carrier material(s) and desired substance(s);

(iii) identification and/or analysis of greenhouse gases and/or undesired substance(s);
(iv) data acquisition, communication, storage, retrieval, analysis, implementation;

(v) overall process(es) safety and effectiveness;
Page 9 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 10 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright @ 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.

B.) IN-PROCESS, real-time steps and methods of actively and concurrently analyzing carrier material(s) and desired substance(s) so as to provide effective, timely feedback to optimize processes such as, but not limited to:

(i) specifying and controlling EM wave(s) which have data such as, but not limited to:
1) EM waves types A,B,C,D having correlated:(i) frequencies, (ii) peak amplitude(s), (iii) nominal amplitude(s), (iv) peak power (v) average power (vi) duty cycle(s);

2) EM wave(s) direction(s) and target depth - such as, but not limited to:

(i) range - linear direction(s); (ii) domain - surface area(s) to apply EM
wave(s);
(iii) target volume(s) - beneath/behind domain position (ii) at depth range(s).
such as, but not limited to:

(i) linear direction(s) - NW 20 degrees at a distance of 300 meters;

(ii) surface area(s) of coverage - such as, but not limited to: specified EM
waves A,B,C
having correlated emission pattern type(s) F,G are to cover a square area having top-left corner starting at 45.1234 deg North, 110.1234 deg West and bottom right corner ending at 45.5555 deg N and 110.5555 deg West - an area of 4000 sq meters to be covered in an overlapping, interleaved pattern type(s) F,G. Pattern F
uses EM
wave type A operating at 2.45 GHz with a maximum peak energy of 45MW, and a nominal energy of 5 MW on overlap with EM wave type B (...) etcetera.

(iii) positional volume(s) - e.g. target volume at given position and at given depth Target volume located beneath surface area pattern noted in (ii) above, and is located at depths ranging from 120m-300m. Based on cross-sectional analysis of cover materials above target volume yields conductivity profile "Alpha 150" for a relatively uniform conductivity averaging 1 50 milli-Siemens per meter. Ground penetrating radar ( EM wave type C ) is to be the primary carrier wave with the transmitter Page 10 of 30 Electro--Magnetic Oil Extraction Process (version 2009Nov22) Page 1 1 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5K0V8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.
adjusted to operate at 220-245MHz for 1 20-200m penetration. Secondary GPR
carrier EM wave D is to operate at 200-219 MHz for deeper 200-300m penetration.
(ii) target material & substances properties analysis 1) covering and target material - variances and anomalies that affect GPR
(Ground Penetrating Radar) & HEPF (Heating Extraction-Purification Process Frequency) signal attenuation, signal propagation depth, signal strength in target material(s) (TM ) and desired substance(s) ( DS );

2) DS actual composition - affects HEPF; substance recovery rate;

3) Material (CM, TM) anomalies analysis and adaptive correction methods;
4) Intermediate Dielectric analysis and management methods to maximize energy transfer through CM layer(s) and within TM, DS ( and optionally unDS).

(iii) data - acquisition, communication, storage, retrieval, analysis, implementation;
(iv) regulating processes of safety monitoring and controls, optionally linked to concurrent analysis to reduce greenhouse gases and/or any undesirable substances.
C.) POST-PROCESS steps and methods of actively analyzing carrier material(s) and the actual recovered desired substance(s) and any other data such as, but not limited to:
recovered quantities, input energy, variances, anomalies, etcetera so as to provide effective, timely feedback to optimize future analysis and recovery processes.
The historical models of material and substance characteristics that form "material profiles" and "substance profiles" will greatly enhance this inventions real-time processing speed and efficiency. Developing "Artificial Intelligence Knowledge &
Experiences" (Al-KE) and then later drawing upon those data models, in combination with IN-PROCESS methods above that use real-time composition analysis equipment (DS, CM, TM, co-related emissions, etc. ) will quickly detect the presence, volume, mass and composition of evolved substances, and thereby enable the process control Page 11 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 12 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.
devices and related software ( such as, but not limited to: real-time process control feedback dynamic tuning ) to minimize the energy expended for carrier material(s) penetration to the target material, minimize the energy expended to excite DS
molecules, and enable feedback compensation with respect to maximizing purity and rate of recovery of DS and related co-DS extracts - thereby mitigating unwanted greenhouse gas production and extraction of any unwanted substances (which are also monitored, measured & calculated for optimal controlling methods) .

6. To facilitate tracking, and record keeping mentioned in preceding sections, a unique identification of materials, substances, samples, extraction-purification products and wastes, is implemented by generating a unique Random Symbolic Identifier (RSID) and an optional Barcode representation of the RSID is correlated and recorded for the respective material, substance, sample, product or waste. This RSID is further defined in Canadian (2004) Patent Application 2,469,598 - Computerized Voting System, to which I claim those prior invention rights for this invention also.

Additional Security Elements (also defined in Canadian (2004) Patent Application 2,469,598 - Computerized Voting System, to which I claim those prior invention rights for this invention also ) are designed and attached or otherwise correlated to assist with authentication of any material, substance, sample, product or waste;
whereby the Security Elements are items such as, but not limited to any number of:
Random Symbolic Identifier codes of this step shall include, but not be limited to:
physical characteristics or devices, optical structures or devices, electronic devices or structures, magnetic fields or devices, organic or inorganic chemicals, biological materials, genetic materials or genetic structures or genetic sequences, special materials, crystal structures, plastics, metals, gas emissions, electromagnetic radiation, radioactive materials, optical emissions, natural fibers, man-made fibers, microfilm dots, microscopic writing, embossing, impressions, watermarks, seals of Page 12 of 30 Electro--Magnetic Oil Extraction Process (version 2009Nov22) Page 13 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.
authenticity affixed or associated, and any other physical structures, or any other properties associated with any material, substance, sample, product or waste-and any derivative or recombination thereof.

7. After identifying the desired and undesired substances, the further steps and methods, such as, but not limited to calculating the exact locations, necessary energy, frequencies, and durations required to extract the desired substances from the target material(s).

8. The steps and methods of modulating any number of GPR carrier waves, operating at any number of frequencies, with any number of Extraction-Purification (EP) EM
waves, operating at any number of frequencies; and the further steps and methods of monitoring and controlling the total energy and direction(s) of individual GPR-EM
waves and EP EM- waves, as well as each combined projected EM-GPR EM waves.

9. The steps and methods whereby intermediate and target material(s), substances products and wastes parameters such as, but not limited to: temperature, pressure, viscosity, turbidity, electrical conductivity, are monitored, recorded and used to control the projected EP-GPR EM waves; and thereby modify parameters such as power level and frequencies of the input EM waves (GPR, EP) using any number of the methods of process controls and signal manipulation previously mentioned.

10. People or computers provide at least one method, and at least one opportunity, to verify or correct the accuracy of the samples, test results and any other data, anytime.
Using any number of communication devices, any number people and any number of of computers or microprocessors running computer software programs, employ any number of devices and methods of communication to apply steps and methods such as, Page 13 of 30 Electro-Magnetic Oil Extraction Process (version 2009Nov22) Page 14 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc.
This application claims full legal International Paris Convention Treaty Rights.

but not limited to: monitor, record, verify, error detect, error correct, reject, transmit, interpret, analyze evaluate, summarize, tally, calculate, amend, report on any number of, and any combination of the data associated with this invention.

1 1. As various material levels are penetrated, the repeated steps and method of optimizing GPR EM wave(s) penetration, such as, but not limited to: altering GPR EM
waves frequency, inserting any number of intermediate dielectric material(s), altering the electromagnetic properties of intermediate materials and/or target materials by adding new substances or altering the properties of existing substances ( for example, such as but not limited to: the steps and methods of projecting a group of GPR carrier waves with the piggyback GPR Property-Altering (GPR-PA) EM waves tuned and optionally cyclically projected so as to favourably alter intermediate and/or target materials properties such as, but not limited to: electrical conductivity(s), thereby optimizing depth of penetration for the primary or any other Extraction-Purification EP-EM waves).

12. As various desired and undesired substances are being evolved and extracted, the the steps and method of optimizing EP-EM wave(s) penetration and effectiveness to produce desired results, such as, but not limited to: altering EP-EM waves frequency, inserting any number of intermediate dielectric material(s), altering the electromagnetic properties of intermediate materials and/or target materials and/or desired substances, and/or undesired substances, by adding new substances or altering the properties of existing substances ( for example, such as but not limited to: the steps and methods of projecting any number of Extraction-Purification EM waves with EP Property-Altering (EP-PA) EM waves tuned and optionally cyclically projected so as to favourably alter desired or undesired or target materials properties (such as, but not limited to:
electrical conductivity ), thereby optimizing the primary Extraction-Purification EP-EM
wave(s) effectiveness in the target material(s) ) Other EM waves are used to provide information Page 14 of 30 Electro--Magnetic Oil Extraction Process (version 2009Nov22) Page 1 5 of 30 Inventor: Daniel W. Onischuk, 9628-100A St. Edmonton, AB. T5KOV8 All Rights Reserved -Copyright 2007, 2009 Dan & Therese Onischuk, World Park Foto Inc. _l This application claims full legal International Paris Convention Treaty Rights. 11 about the Materials and Substances, while other waves are used to modify any number of properties of the Materials or Substances so as to optimize energy savings, enhance extraction-purification processes, reduce unwanted substance production, etcetera.

1 3. People, computers running software programs and/or any number of other analytical and process control devices, repeatedly measure, monitor, analyze and communicate the products and operating conditions all of the processes of this invention.

14. People, computers running software programs and/or any number of other analytical and process control devices determine the optimal yield of the desired substance(s) has been obtained, or, that an unsafe or undesired level of wastes other emissions are being produced and therefore act to stop all further EP-EM and GPR EM wave emissions.

------------- end of general declaration section ------------------

Claims (20)

1. Claim 1. The steps and methods to identify, research, record, store, retrieve and communicate any relevant information as to the physical, chemical and electro-magnetic properties of any number of SUBSTANCES and any number of MATERIALS; and the further step to assign each unique SUBSTANCE to any number of Substances Data List(s) ( a.k.a.
   SDL ) ( such as, but not limited to: the Periodic Table of Elements, Organic Compounds, as substance data list(s) ); and the further step whereby each Substance within an SDL is assigned one unique identification symbol or groups of symbols known as a Substance Data List Identifier ( SDL-ID ) to distinguish each substance from any other substances of the same SDL; and the further steps and methods of correlating each SDL-ID to each respective SDL; and the further step whereby each type of SDL is assigned a unique symbol or group of symbols to distinguish it from other types of SDL's; and the further steps and methods whereby each unique Substance is assigned a unique SDL Master-Identifier ( SDL-MID ) that is unique among all Substance Data Lists of this invention; and the further steps and methods of correlating each SDL-MID to at least one Master Substance Data List (MSDL) of this invention; and the further steps and methods to identify, research, obtain, and record any relevant information as to the physical, chemical and electro-magnetic properties of any number of MATERIALS; and the further step to assign each MATERIAL to any number of Material Data List(s) ( a.k.a. MDL ) ( such as, but not limited to: Geological Survey material data list ) ; and the further step whereby each Material within a MDL is assigned one unique identification symbol or groups of symbols known as a Material Data List Identifier ( MDL-ID
   ) to distinguish each material from any other materials of the same MDL; and the further steps and methods of correlating each MDL-ID to each respective MDL; and the further step whereby each type of MDL is assigned a unique symbol or group of symbols to distinguish it from other types of MDL's; and the further steps and methods whereby each unique Material is assigned a unique MDL Master-Identifier ( MDL-MID ) that is unique among all Material Data Lists of this invention; and the further steps and methods of correlating each MDL-MID to at least one Master Material Data List (MMDL) of this invention;
   and the further steps and methods whereby any number of Substances from any number of Substance Data Lists are correlated to any number of Materials and any number of Material Data Lists of this invention; and the further steps and methods whereby all such information is logically gathered and recorded in a computer systems operating software to enable the integrity of data & communication system data acquisition, data entry, data storage, data retrieval, error detection, error correction, data amendments, encryption, decryption, encoding, decoding, accuracy and longevity for data and communication systems of this invention.
2. Claim 2. The steps and methods whereby any number of legal entities (LE's) conducting any number of Extraction-Purification (EP) processes, whereby any number of LE's use the information of claim 1, along with detailed analysis of local materials ( such, but not limited to geological formation studies, material and substance analysis from drilling core samples ) to determine optimal Extraction-Purification (EP) process parameters such as, but not limited to: Target Material and Target Substances - location(s), depth(s), expected concentrations, optimal GPR (ground penetrating radar) carrier frequency range(s), optimal Heating-Extraction Frequencies (HEF's), and Cooling-Extraction Frequencies (CEF's); and the further steps and methods whereby any number of legal entities take any number of preparatory activities such as, but not limited to: gathering at least one set of carrier material samples, along with their original location coordinates, from a proposed target area; using any number of analytical devices and any number of computers running software programs, take steps to determine, assemble and organize a correlated list of Target Substances designating Desired Substances and unDesired Substances in the Carrier Material sample(s); and for any number and any type of substances, thereafter perform calculations relevant to the Carrier Material samples such as, but not limited to Desired Substances and unDesired Substances: absolute concentrations, purity, mass yield, volume yields, that will potentially result from applying the steps and methods of this invention;
   and the further PRE-PROCESS steps and methods such as, but not limited to:
   
   (i) calculate each EM energy needed to affect target material(s), desired substance(s);
   
   (ii) determine optimal EM waves combinations, distribution patterns and duty cycles;
   
   (iii) estimate EM wave power usage(s), potential yield rates of desired substance(s), greenhouse gases, undesired substance(s);
   
   (v) initialize data acquisition, communication, storage, retrieval, analysis systems;
   
   (vi) identify real and potential safety or production issues and viable solutions;
3. Claim 3. The steps and methods according to claims 1,2 of this invention, whereby the steps and methods of using computers and/or microprocessors running software programs that use input data from any number of, and any type of man-made devices and any number of people, and the further steps and methods of applying any number of mathematical formulas, and any information in preceding claims 1,2 so as to rapidly and accurately calculate and determine the optimal range(s) of frequencies for the Ground Penetrating Radar (GPR) EM wave(s) to optimally penetrate to the Target Material(s) ( TM ) that contain the Target Substances (Desired or undesired Substances); and the further steps and methods of using computers and/or microprocessors running software programs that use input data from any number of, and any type of man-made devices and any number of people, and the further steps and methods of applying any number of mathematical formulas, and any information in preceding claims 1,2 so as to rapidly and accurately calculate and determine the optimal range(s) of frequencies for the Extraction-Purification (EP) EM wave(s) to optimally penetrate to and agitate (using HEF waves according to claim 2) the molecules of the Target Substance(s) (Desired or unDesired Substances), or, alternatively, or, to simultaneously, for the EP EM waves to slow (using CEF
   waves according to claim 2) the molecules of the Target Substances (Desired or unDesired Substances); and the further steps and methods according to this claim whereby at least one Desired Substance(s) and/or any number of unDesired Substances ( unDS ) are correlated and recorded as corresponding to any number of EP-HEF EM wave(s), or, any number of EP-CEF
   EM wave(s); and the further steps and methods whereby each Desired Substance(s) (DS) and each unDesired Substances ( unDS ) are correlated to a correctly corresponding Target Substance; and the further steps and methods whereby each aforementioned correlated DS
   and each unDS is uses an appropriate identifier of claim 1 that is then correlated to a specific Target Substance of this claim, and that the correlated Target Substance now identified and correlated to claim 1 is further given an unique Random Symbolic Identifier (RSID) or Sequential Symbolic Identifier (SSID) to enable tracking and correlation to its respective, correlated EP-HEF or EP-CEF EM wave(s); and the further steps and methods whereby each aforementioned correlated EP-HEF or EP-CEF EM wave(s) are further recorded as having a prefix to the RSID or SSID as being such as, but not limited to:
   "EPH" or "EPC";
   
   and the further steps and methods of correlating and recording each EP-HEF and each EP-CEF EM wave to any number of GPR-EM wave(s) of this invention; and the further steps and methods whereby the GPR-EM waves are also given a unique RSID or SSID with a prefix such as, but not limited to "GPR" so as to distinguish them from EP waves; and the further steps and methods of the preceding steps of this claim so as to properly identify and correlate any other EM waves, such as, but not limited to: any number of, and any combinations of:
   Material Property Altering EM wave(s), Substance Property Altering EM wave(s), Material Telemetry EM Wave(s), Substance Telemetry EM wave(s) of this invention.
4. Claim 4. The steps and methods, such as, but not limited to: electronically, electro-magnetically, magnetically, digitally, optically and/or plasmatically, or any combination thereof, so as to generate and then selectively combine the GPR-EM waves of claim 3 with the correlated EP-HEF and/or EP-CEF EM waves of claim 3; and the further steps and methods of generating and combining any number of, and any type of, and any combination of EM waves of claim 3; by applying steps and methods of any number of, any type of, and any combination(s) of EM wave modification(s), such as, but not limited to:
   Frequency Modulation ( Mixing ), Frequency de-Modulation; Amplitude Modulation, frequency phase-shifting, frequency phase-splitting, frequency shifting, companding, filtering, amplification, aliasing - by using any number of, and any type of electro-magnetic, electro-optical, digital devices and any number of combinations of electro-magnetic, electro-optical, digital devices devices such as, but not limited to: variable frequency oscillators, amplifiers, tuning capacitors, diodes, analog to digital converters, electro-optical infr-red detector devices; and the further steps and methods of EM wave digitization, error-correcting, and any other steps and methods or mathematical principles or formulas of electro-magnetic, digital, and energy wave transmission, mixing, processing and controls; and the further steps and methods such as, but not limited to:
   applying signal transmission formulas using computers and/or microprocessors running computer software programs, performing and applying mathematical calculations and process control formulas and methods to enable, activate, control, modify and deactivate - the generation or modification of any type of, and any number of EM wave(s), and/or, the combining of any type of, and any number of combinations of GPR-EM waves with EP-EM waves;
   and/or the combining of any type of, and any number of combinations of GPR-EM waves with TELEMETRY-EM waves of claim 8; and the further steps and methods of modification of any type of, and any number of individual EM waves; and the further steps and methods of modification of any type of, and any number of combined EM waves of this invention.
5. Claim 5. The steps and methods of employing antennas and electro-magnetic waveguides, and GPR-EP EM transmission and control systems to project any number of GPR-EM
   waves of claim 4, and to any number of EP-EM waves of claim 4 so as to accurately and safely control the direction(s) towards any number of, and any combinations of Target Material(s) of claim 4, and any number of Target Substance(s) of claim 4 - by applying any number of types of controlling parameters such as, but not limited to: length of duration(s), (duty cycle(s)), power level(s), phase-splitting, amplitude modulation, frequency-key shifting - so as to achieve the objects of optimally penetrating any number of GPR-EM waves through any number of intermediate Materials to each Target Material(s) - thereby also accurately projecting each correlated heating (EP-HEF's) or cooling (EP-CEF's) EM wave(s) to their Target Substance(s); and the further steps and methods whereby any number of Target Substances are agitated to higher energy state(s) or, alternatively, to lower energy state(s), by imparting the energy of Electro-Magnetic (EM) waves emitted from at least one transmitter(s) adjusted by people and/or computers running software programs and/or micro-processors that are running software programs, and any other related devices, so as to emit EP-HEF and/or EP-CEF EM waves of at least one frequency, that can be at any frequency, so as to be at or near the RESONANT FREQUENCY (EM RESONANT WAVE(s)) (or any other effective frequency or range of frequencies) of the Target Substance(s) individual or aggregate combined molecules, molecular bonds, and/or constituent atoms or atomic bonds; and the further steps and methods of claims 3 to uniquely identify and correlate each generated GPR-EM wave of claim 4 to at least one material(s) of claims 1,2 and the further steps and methods of claims 3 to uniquely identify and correlate each generated EP-EM wave of claim 4 to at least one Substance of claims 1,2.
6. Claim 6. The further steps and methods according to claim 5 of measuring, monitoring and controlling the direction(s), distribution patterns, and EM wave parameters such as, but not limited to: total energy, frequency, duty cycle of: each individual GPR-EM
   waves of claims 4,5 each EP EM- waves of claims 4,5; and the further steps and methods of measuring, monitoring and controlling the total energy of each combined projected GPR-EP
   EM waves of claims 4,5 by additional steps and methods such as, but not limited to:
   monitoring, analyzing, recording and adjusting to compensate for the intermediate and target material(s), substance(s) products and wastes parameters such as, but not limited to:
   temperature, pressure, viscosity, turbidity, electrical conductivity, spectrographic emissions - which are then used to calculate and apply control parameters to any number of devices controlling activities such as, but not limited to the generation, combination, modifications, and projections of any number of GPR-EM waves and EP-EM waves and any number of their correlated parameters such as, but not limited to: power level, frequency, duty cycle. -using any number of the methods of process controls and signal manipulation mentioned in this invention, such as but not limited to: the steps and methods whereby the GPR-EM
   waves and/or their correlated application patterns are adjusted or tuned by any number of computers or microprocessors running software programs that perform calculations based on mathematical formulas, input data from any number of people and/or any number of devices of this invention, so as to tune the GPR-EM wave emitters to a frequency or range of frequencies to optimize penetration by taking into account Intermediate Material(s) and Target (Carrier) Material properties such as, but not limited to: electrical conductivity, moisture content, Intermediate Material(s) dielectric permittivity; and the further steps and methods of performing any type of processing such as, but not limited to optimizing modulating any number of GPR carrier waves (operating at any frequency), with any number of Extraction-Purification (EP) EM waves ( operating at any frequency ); and the further steps and methods to thereafter perform EM wave(s) effectiveness monitoring and additional computations and corresponding controlled EM wave adjustments to optimize GPR-EM penetration to each Target Material(s), as well as EP-HEF heating-agitation EM
   waves and/or EP-CEF cooling-slowing EM waves for each or any Target Substance(s) for this Primary Process and/or for any other EM waves of claims 3-12 of this invention.
7. Claim 7. The steps and methods according to claim 4,5,6 whereby devices such as, but not limited to: signal transmitters, signal detectors, process control devices, composition analyzers, chemical properties analyzers, infra-red spectrometers, gas chromatographs, pyrometers, safety devices, waste analyzers, greenhouse gas monitors, computers running software programs using input data from people, information databases of claims 1, 2, and using mathematical formulas according to claims 3, 4, 5,6 - are all used to further calculate the most recent optimal, safe GPR-EP (HEF and/or CEF) EM wave combinations for optimal, safe effective GPR penetration frequencies, EP (HEF and/or CEF) EM
   frequencies, and their optimal EM wave(s) combining according to claims 1-12;
8. Claim 8. The steps and methods according to claims 3-7, whereby the steps and methods such as, but not limited to: IN-PROCESS, real-time steps and methods of actively and concurrently analyzing carrier material(s) and desired substance(s), GPR
   and EP EM
   waves transmission powers, and transmission coverage patterns, so as to provide effective, timely feedback to optimize processes such as, but not limited to:
   
   (A) specifying and controlling EM wave(s) A,B (primary, secondary GPR) and C
   primary EP-HEF ) and D ( secondary EP-CEF ) with data such as, but not limited to:
   
   1) EM waves A,B,C,D having correlated:(i) frequencies, (ii) peak amplitude(s), (iii) nominal amplitude(s), (iv) peak power (v) average power (vi) duty cycle(s);
   2) EM wave(s) A,B,C,D direction(s) and target depth - such as, but not limited to:
   (i) range - linear direction(s); (ii) domain - surface area(s) to apply EM
   wave(s);
   (iii) target volume(s) - beneath/behind domain position (ii) at depth range(s);
   (iv) evaluate and selectively apply any number and any combination of process control methods such as, but not limited to those of claims 3-8, 12;
   (B) According to claims 3-8, the further steps and methods such as, but not limited to: generating, applying and controlling any number of GPR and correlated Telemetry EM waves, which are used to gather information about the Materials and Substances of claims 1-12; using any number of electronic devices, such as, but not limited to:
   infra-red pyrometers, EM wave detectors, gas chromatographs, radio receivers, transducers, computers - to determine the effectiveness of the overall process for claims 1-12; and the further steps and methods of analyzing target material &
   substances properties analysis such as but not limited to:
   
   1) intermediate material and target material analysis - such, as but not limited to: variances and anomalies of Materials that affect EM waves properties such as, but not limited to: attenuation, dispersion pattern, propagation depth, to target material(s)( TM ) and target substance(s)( TS );
   
   2) Target Substance(s) analysis - ( affects recovery rate, EM wave controls );
   
   3) Intermediate Material and Target Material adaptive correction methods to maximize energy transfer THROUGH any number of Material layer(s);
   
   4) Intermediate Material and Target Material analysis and adaptive correction methods to maximize energy transfer WITHIN the Target Material(s), so as to optimize production of any number of Desired Substances and/or minimize any number of unDesired Substances, greenhouse gases, and/or waste materials (5) evaluate and selectively apply any number of historical material and/or substance profiles of claims 1-12;
9. Claim 9. The steps and methods whereby as various material levels are penetrated, the steps and methods of optimizing GPR EM wave(s) penetration, such as, but not limited to:
   altering GPR EM waves frequency, inserting any number of intermediate dielectric material(s), altering the electromagnetic properties of intermediate materials and/or target materials by adding new substances or altering the properties of existing substances ( for example, such as but not limited to: the steps and methods of calculating, generating, combing and projecting a group of GPR carrier waves with any number of "piggybacked"
   GPR Material Property-Altering (GPR-MPA) EM waves and/or any number of GPR
   Substance Property-Altering (GPR-SPA) EM waves are tuned and projected in any number of ways so as to favorably alter properties of the Intermediate Materials and/or Target Materials properties such as, but not limited to: EM wave conductivity(s), EM wave permittivity(s) - to optimize the effectiveness of any number, and of any combination of GPR-EM
   waves and/or any number of EP-EM waves, in any Material(s) or Substance(s) of this invention; and the further steps and methods evaluate and selectively apply any number of historical material and/or substance profiles of claims 1-12;
10. Claim 10. The steps and methods whereby as various Desired Substances and unDesired Substances are evolved and extracted from the Target Material(s), the further steps and methods of optimizing EP-EM wave(s) penetration and effectiveness within the Target Material(s) so as to optimize producing desired results - such as, but not limited to: altering any number of EP-EM waves to be SUBSTANCE ALTERING (SA) SA-EM waves frequency(s), inserting any number of intermediate dielectric material(s), altering the electromagnetic properties of intermediate materials and/or target materials and/or desired substances, and/or undesired substances, by adding new substances or altering the properties of existing substances ( for example, such as but not limited to: the steps and methods of projecting any number of, and any combination of Substance Property Altering SPA-EM
    waves are combined according to claims 3-6 with GPR-SPA EM waves of claim 8, that are tuned and projected according to claims 3-12, so as to favorably alter desired or undesired or Target Substance(s) properties (such as, but not limited to: EM wave conductivity, EM
    wave permittivity ), so as to optimize the effectiveness of any number of Extraction-Purification EP-EM wave(s) and/or any number of GPR-EM waves, or any other EM
    waves of claims 3-12, in any Material(s) or Substance(s) of this invention; and the further steps and methods to evaluate and selectively apply any number and any combination of process control methods such as, but not limited to those of claims 3-12; ).
11. Claim 11. The further steps and methods according to claims 1-10 of supplementing the methods of this invention with any number of, and any combination of, other processes and methods such as, but not limited to: pumping, suction, mechanical filtering, magnetic filtering, acoustic wave filtering, acoustic wave agitation, steam injection, intermediate dielectric insertion, intermediate materials dielectric properties manipulation, etcetera.
12. Claim 12. According to claims 1-11, the steps and methods to implement additional POST-PROCESS steps and methods such as, but not limited to: actively analyzing carrier material(s); actual composition of recovered desired substance(s); and any other data such as, but not limited to: recovered quantities, input energy, variances, anomalies, etcetera so as to provide effective, timely feedback to optimize future analysis and recovery processes;
    and the further steps and methods of using computers running software programs such as, but not limited to: database software, that is used for recording and storing the historical models of material and substance characteristics that form "material profiles"
    and "substance profiles" of claim 1 and this claim, so as to enhance this inventions real-time processing speed and efficiency in future uses - developing "Artificial Intelligence Knowledge & Experiences" (Al-KE) and then later drawing upon those data models, in combination with IN-PROCESS methods of claims 3-11 that uses real-time composition analysis equipment (DS, CM, TM, co-related emissions, etc. ) used in conjunction with process control devices and related software ( such as, but not limited to:
    real-time process control feedback dynamic tuning ) that will minimize the energy expended for carrier material(s) penetration to the target material, minimize the energy expended to excite DS
    molecules, and enable feedback compensation with respect to purity and rate of recovery of DS and related co-DS extracts - thereby mitigating unwanted greenhouse gas production and extraction of any unwanted substances.
13. Claim 13. The steps and methods to facilitate tracking, and record keeping mentioned in claims 1-20, a unique identification of materials, substances, samples, extraction-purification products and wastes, is implemented by generating a unique Random Symbolic Identifier (RSID) and an optional Barcode representation of the RSID is correlated and recorded for the respective material, substance, sample, product or waste.
    This RSID is further defined in Canadian (2004) Patent Application 2,469,598 - Computerized Voting System, to which I claim those prior invention rights for this invention also;
    and the further steps and methods of "Additional Security Elements" (also defined in Canadian (2004) Patent Application 2,469,598 - Computerized Voting System, to which I claim those prior invention rights for this invention also) are designed and attached or otherwise correlated to assist with authentication of any material, substance, sample, product or waste;
    whereby the Security Elements are items such as, but not limited to any number of: Random Symbolic Identifier codes of this step shall include, but not be limited to: physical characteristics or devices, optical structures or devices, electronic devices or structures, magnetic fields or devices, organic or inorganic chemicals, biological materials, genetic materials or genetic structures or genetic sequences, special materials, crystal structures, plastics, metals, gas emissions, electromagnetic radiation, radioactive materials, optical emissions, natural
14. Claim 14. According to claims 1-20, the steps and methods whereby people and/or computers running software programs provide at least one method, and at least one opportunity, to verify or correct the accuracy of the samples, test results and any other data, anytime for all claims of this invention; and the further steps and methods whereby any number of people or computers running software, or any number of other devices, use any number of communication devices, any number people and any number of computers or microprocessors running computer software programs, to employ any number of devices and methods of communication to apply steps and methods such as, but not limited to:
    monitor, record, verify, error detect, error correct, reject, transmit, interpret, analyze evaluate, summarize, tally, calculate, amend, report on any number of, and any combination of the data associated with this invention.
15. Claim 15. The steps and methods of according to claims 1-20 whereby various systems and equipment of this invention, such as, but no limited to information data systems, analytical equipment, process control systems, emergency shutdown systems, data communications systems, rely upon, utilize and/or comprise of the steps and methods of, but not limited to: researching, identifying, defining, designing, verifying, correlating, authenticating, amending, certifying, preparing, organizing, sorting, assembling, recording, storing, printing, publishing, distributing, receiving, creating, assigning, attaching, linking, embedding, encoding, decoding, encrypting, decrypting, compressing, decompressing, converting, accepting, receiving, recording, electronic scanning, optically scanning, recording, enhancing, storing, creating any number of identical duplicate backup copies, correlating, tallying, counting, calculating, correlating, associating, searching, sorting, organizing, marking, labeling, tagging, identifying, acknowledging, error identification, error recording, error correction, error transmission, error reception, error reporting, authenticating, verifying, validating, certifying, summarizing, reporting, communicating, printing, publishing, transmitting, receiving, compressing, decompressing, encrypting, decrypting, interpreting, converting, locating, detecting, reading, receiving, interpreting, translating, transmitting data to, and receiving data from, any number of -humans, legal entities, computers, electronic, mechanical or optical devices, telephones, communications networks and is to include all steps and methods of translating human and device readable codes to modes, protocols or methods of communication, transmission, reception, decryption, encryption, compression, decompression, as well as the steps and methods of locating, receiving, detecting, interpreting, translating, reporting, and transmitting error free data, and the further steps of locating, receiving, detecting, interpreting, translating, reporting transmitting, and correcting compromised data, erroneous data, duplicate data or duplicate transmissions; and the further steps and methods, whereby the aforementioned functions, operations amd processing of this claim are performed by ( but not limited to ) any combination and any number of either singularly or any plurality of -persons, designated agents, computers running software programs, legal entities, data acquisition devices, electronic, electromagnetic, optical or biological or other computing or analytical devices, communication networks, any other man-made devices, computers, microprocessors, computer software programs, telephones, facsimile (fax) machines, fax software, optical scanners, audio recording equipment, audio playback systems, video recording equipment, video playback systems, communication networks, cable television systems, electronic mail, data encryption methods, data decryption methods, data conversion methods, data reconstruction methods, data compression methods, data decompression methods, data inventory software, data organization software, data tracking software, data retrieval software, printing software, printers, package labeling software and
16. Claim 16. According to claims 1-15, the steps and methods whereby any number of, and any combination(s) of people and man-devices such as, but not limited to:
    computers running software programs and/or any number of other analytical and/or process control devices, repeatedly measure, monitor, analyze, evaluate and communicate any number of parameters of the operating conditions and products of all the processes of this invention.
17. Claim 17. According to claims 1-16, the steps and methods whereby any number of, and any combination(s) of people and man-devices such as, but not limited to:
    computers running software programs and/or any number of other analytical and process control devices determine that any number of limiting operating conditions has been reached, such as, but not limited to: the optimal yield of the desired substance(s) has been obtained, and/or, that an unsafe or undesired level of wastes or any other emissions are being produced, - and therefore take any number of actions to safely stop all EP-EM
    and GPR EM
    wave emissions until a later time and/or date when there prevails more favorable conditions such as, but not limited to: a new target material location is determined, or safer process conditions prevail, or greenhouse gas emissions decline to safe levels.
18. Claim 18. The further steps and methods of repeating steps 1-16 any number of times, in any safe logical sequence or safe, logical combinations to achieve optimal desired result(s).
19. Claim 19. Any other claims, steps or methods described, expressed or implied -intrinsically or extrinsically relevant to any other sections of this patent application, or any related, or directly referenced patent application (such as, but not limited to: RSID of Canada patent application 2,469,598 ).
20. Claim 20. The right to add or amend any claim(s) and/or any drawing(s) at a later date.