1. The document describes a method for remote sensing of the Earth using satellite imagery to detect minerals. Infrared signals from minerals are captured in satellite images and then processed.
2. Images are resonance processed using test wafers that are exposed to radiation along with the satellite images. This allows signals from specific minerals to be filtered and visualized.
3. Objects are then detected on x-ray film after chemical processing and visualized on a map. Deposit parameters like coordinates, depths and sizes are then analyzed and included in a report for the customer.
1. 1
Innovative technology of remote sounding of the Earth
General Idea
A large number of different signals is obtained in the process of shooting. Signals
that are of interest to us representing the molecular structure of minerals are in the
infrared (IR) range. Their level is very low and can be captured only by analogue
images.
In line with this, our task is to filter useful infrared range signals with the help of
resonance and, further, to subsequently visualize them (transfer of IR range signals into
the visible frequency range). The general diagram of this approach is shown in fig. 1
and fig. 2.
Fig. 1
Fig. 2
Satellite
Fig. 2
Radiation of
the sough-for
mineral
Analogue
satellite photo
сamera
1. Satellite
Optical filtration
Radio
waves
Ultraviolet
radiation
Optical
Range
Infrared
range
30 kHz 200 THz 400 THz 800 THz
3. Image visualization
1 - 2
The required
lens
Оptical Filters
2. Resonance processing
of image
4. Transfer of data onto a map
Analogue infrared
satellite images
The required
frequency range
Photographic film
2. 2
Sequence of Works on Remote
Survey of Areas
1. Preparatory works
Fig. 3
Fig. 4
Fig. 5
Further the test wafers are used as a resonator during radiation-chemical processing of analogue
satellite images of the territory obtained in the infrared range.
1.2. Laboratory manufacture
of test gel wafers
2
.
Base № 1
Vacuum
sputtering of gels
and reference
materials
1
.
N
1
1.1. Ordering and receiving
analog infrared satellite
imagery survey territory
Reprinter
Test wafer
№ 1
B
Test wafer
№ N
Base
3. 3
Resonancе
Isotrope α + γ
radiation
Satellite image Test wafer X-ray film Location map
Result
2. Identification of the Sought-for Objects
2.1. Radiation-chemical processing of satellite images in the presence of test gel wafers
in accordance with the patented technology
Fig. 6
2.2. Chemical processing of exposed X-ray film
2.3. Visualization of the detected objects in high-tension impulse field
High-tension impulse voltage
Fig. 7
Radiation and chemical
processing of analogue
satellite images
Combined in a “sandwich” and placed in the IR-100 reactor zone
Radiation and chemical processing of analogue
satellite images
Visualization and
transfer of contours
of deposits onto a
map
Computer
with
Visualization and
transfer of contours
of deposits onto
a map
4. 4
2.4. Detected object snap (fixation)
Contouring Depth calculation
Outcome – direction visualization of ground contours of deposits and calculation of
occurrence depths of their horizons.
3. Analytic data processing
Obtainment of deposit parameters:
- coordinates of ground contours of the detected deposits,
- number of horizons,
- occurrence depths of horizons and their thickness,
- reservoir rocks,
- inundation of horizons
- presence of gas caps and pressure in them.
4. Preparation and submission of report to the Customer
Location map making, contouring of deposits, calculation of expected reserves of
hydrocarbons, preparation of explanatory part of the report.
Technical implementation
Deposit of oil
Used physical effects
- Nuclear magnetic and paramagnetic resonance,
- Transfer of own spectral characteristics of samples of minerals onto test wafers,
- Electromagnetic object visualization.
Equipment and materials
- Special chemical laboratory,
- Isotrope source of α and γ radiation,
- Analogue satellite images of a survey territory
in infrared range,
- High-purity chemical reagents,
- High-sensitivity X-ray film.
Transfer contours on the map