Use of RSS and NMR for exploration in oil and gas industry but also for refur...Fands-llc
In a period of severe recession in the oil industry and the reduction of companies' employees only NMR technology will allow to preserve the exploration programs of the companies planned for 2020 for a symbolic price. The NMR technology provides absolute field data with efficiency in 2.5 -3.0 times higher than indirect seismic data, and at a price ten times lower than 2D/3D seismic data. And most importantly, we are operating remotely, we are not afraid of the coronavirus pandemic all over the world!!!
If you have planned exploration surveys of the field (blocks) in 2020, NMR technology will perform remotely and provide the following:
Ground contours of oil, gas and oil & gas reservoirs.
Limits for extension of traps,
The number of horizons in each reservoir,
The depth of horizons,
The presence of a gas cap over the oil horizon,
Indicative of gas pressure in the gas cap (reservoir pressure),
The presence of water under the oil horizon,
Vertical scan data column,
Vertical sections of hydrocarbon reservoirs,
Roof structural maps for individual layers,
Calculated volume of layers, filled with gas and oil,
Preliminary calculation of forecasted oil and gas resources in all deposits,
Mapping the maximum signal response in each reservoir
Identification of the optimum drilling points.
The survey period is 1.0-1.5months
If you have exploratory (appraisal) wells planned and to exclude dry holes, please give us the drilling points (coordinates) and your company will receive the following data before drilling:
Determination of the presence of hydrocarbons in the survey point to in a given depth interval,
Identification of the type of hydrocarbons (oil, natural gas),
A map of the terrain with contours of the identified deposit and fault zones within a radius of 1 to 3 km around the drilling point,
Determine the zones of maximum response of signals on the contours of identified deposit,
Determining the number of useful horizons,
Determining depth of occurrence of each horizon,
The gas pressure in the horizons,
Flooding of horizon and the thickness of the water layer,
Building deep column at the drilling point,
Identify the presence of hydrocarbons in the vicinity of the control point in the absence of hydrocarbons at a given point.
The survey period is 30 days
The NMR technology is based on the phenomenon of resonance, which allows direct detection and contouring of hydrocarbon deposits, as well as deep sounding and obtaining data on the occurrence of horizons, the presence of gas caps, gas pressure in them, watering of horizons, to choose the optimal points for drilling, and also to calculate the forecast hydrocarbon resources.
This document summarizes research using multi-scale spectral data to investigate hydrocarbon plays. It describes:
1) Controlled experiments using hyperspectral data from aircraft and ground sensors to map hydrocarbon mixtures in soils. Hydrocarbon detections were most successful with increasing mixture amounts.
2) A case study of a Brazilian tar sand deposit where hyperspectral data from hand samples, outcrop faces, and aircraft were analyzed. The degree of bitumen impregnation in sandstone was estimated from absorption feature depths which correlated to total bitumen content.
3) Preliminary analysis of WorldView-3 satellite data over the study area found it could detect hydrocarbon signatures at a scale of 7.5m, though with lower
The document discusses applications of multi-scale spectral sensing techniques for mineral and hydrocarbon exploration and production. It provides examples of using field and laboratory-based spectrometers and hyperspectral imaging to map minerals in drill cores and mine faces. Specific cases examine iron, gold, and rare earth element deposits. Spectroscopic data is used to identify mineral distributions and compositions for ore control and process optimization.
09h10 stv2 paulo vasconcelos 22 08 flamengoslides-mci
This document provides an overview of 40Ar/39Ar geochronology methods, challenges, and applications. It discusses:
- Justifications for using 40Ar/39Ar to date mafic igneous rocks given suitable minerals and sample size requirements.
- Methodological approaches including sample preparation, irradiation, mass spectrometry, and testing results using standards.
- Difficulties posed by alteration and approaches to overcome them such as comparing untreated and acid-treated aliquots.
- Successful studies dating mafic magmatism in Australia, Brazil, and altered volcanic rocks both onshore and offshore.
- Current projects and developments including improving dating of hydrothermally altered samples.
- The document discusses using hyperspectral remote sensing for mineral mapping. It provides background on how minerals have unique spectral signatures and defines hyperspectral imagery as image cubes with spatial and spectral data.
- Two case studies are summarized that demonstrate using techniques like atmospheric correction, MNF transformation, and spectral analysis tools like SAM and MTMF on Hyperion satellite imagery to map minerals in areas of India and Pakistan. Key minerals identified include grossularite, calcite, pyrite, andradite, and dolomite.
- The methodology involves preprocessing the hyperspectral cube, identifying endmembers, and then classifying and mapping minerals present based on their spectral properties and signatures in the imagery.
This slide is all about proximal sensing of soil properties including lab techniques and proximal remote sensing. Hope it will help soil science scholars and acade
Use of RSS and NMR for exploration in oil and gas industry but also for refur...Fands-llc
In a period of severe recession in the oil industry and the reduction of companies' employees only NMR technology will allow to preserve the exploration programs of the companies planned for 2020 for a symbolic price. The NMR technology provides absolute field data with efficiency in 2.5 -3.0 times higher than indirect seismic data, and at a price ten times lower than 2D/3D seismic data. And most importantly, we are operating remotely, we are not afraid of the coronavirus pandemic all over the world!!!
If you have planned exploration surveys of the field (blocks) in 2020, NMR technology will perform remotely and provide the following:
Ground contours of oil, gas and oil & gas reservoirs.
Limits for extension of traps,
The number of horizons in each reservoir,
The depth of horizons,
The presence of a gas cap over the oil horizon,
Indicative of gas pressure in the gas cap (reservoir pressure),
The presence of water under the oil horizon,
Vertical scan data column,
Vertical sections of hydrocarbon reservoirs,
Roof structural maps for individual layers,
Calculated volume of layers, filled with gas and oil,
Preliminary calculation of forecasted oil and gas resources in all deposits,
Mapping the maximum signal response in each reservoir
Identification of the optimum drilling points.
The survey period is 1.0-1.5months
If you have exploratory (appraisal) wells planned and to exclude dry holes, please give us the drilling points (coordinates) and your company will receive the following data before drilling:
Determination of the presence of hydrocarbons in the survey point to in a given depth interval,
Identification of the type of hydrocarbons (oil, natural gas),
A map of the terrain with contours of the identified deposit and fault zones within a radius of 1 to 3 km around the drilling point,
Determine the zones of maximum response of signals on the contours of identified deposit,
Determining the number of useful horizons,
Determining depth of occurrence of each horizon,
The gas pressure in the horizons,
Flooding of horizon and the thickness of the water layer,
Building deep column at the drilling point,
Identify the presence of hydrocarbons in the vicinity of the control point in the absence of hydrocarbons at a given point.
The survey period is 30 days
The NMR technology is based on the phenomenon of resonance, which allows direct detection and contouring of hydrocarbon deposits, as well as deep sounding and obtaining data on the occurrence of horizons, the presence of gas caps, gas pressure in them, watering of horizons, to choose the optimal points for drilling, and also to calculate the forecast hydrocarbon resources.
This document summarizes research using multi-scale spectral data to investigate hydrocarbon plays. It describes:
1) Controlled experiments using hyperspectral data from aircraft and ground sensors to map hydrocarbon mixtures in soils. Hydrocarbon detections were most successful with increasing mixture amounts.
2) A case study of a Brazilian tar sand deposit where hyperspectral data from hand samples, outcrop faces, and aircraft were analyzed. The degree of bitumen impregnation in sandstone was estimated from absorption feature depths which correlated to total bitumen content.
3) Preliminary analysis of WorldView-3 satellite data over the study area found it could detect hydrocarbon signatures at a scale of 7.5m, though with lower
The document discusses applications of multi-scale spectral sensing techniques for mineral and hydrocarbon exploration and production. It provides examples of using field and laboratory-based spectrometers and hyperspectral imaging to map minerals in drill cores and mine faces. Specific cases examine iron, gold, and rare earth element deposits. Spectroscopic data is used to identify mineral distributions and compositions for ore control and process optimization.
09h10 stv2 paulo vasconcelos 22 08 flamengoslides-mci
This document provides an overview of 40Ar/39Ar geochronology methods, challenges, and applications. It discusses:
- Justifications for using 40Ar/39Ar to date mafic igneous rocks given suitable minerals and sample size requirements.
- Methodological approaches including sample preparation, irradiation, mass spectrometry, and testing results using standards.
- Difficulties posed by alteration and approaches to overcome them such as comparing untreated and acid-treated aliquots.
- Successful studies dating mafic magmatism in Australia, Brazil, and altered volcanic rocks both onshore and offshore.
- Current projects and developments including improving dating of hydrothermally altered samples.
- The document discusses using hyperspectral remote sensing for mineral mapping. It provides background on how minerals have unique spectral signatures and defines hyperspectral imagery as image cubes with spatial and spectral data.
- Two case studies are summarized that demonstrate using techniques like atmospheric correction, MNF transformation, and spectral analysis tools like SAM and MTMF on Hyperion satellite imagery to map minerals in areas of India and Pakistan. Key minerals identified include grossularite, calcite, pyrite, andradite, and dolomite.
- The methodology involves preprocessing the hyperspectral cube, identifying endmembers, and then classifying and mapping minerals present based on their spectral properties and signatures in the imagery.
This slide is all about proximal sensing of soil properties including lab techniques and proximal remote sensing. Hope it will help soil science scholars and acade
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
Brief information for use nmr in geophysics1Fands-llc
This document summarizes an NMR technique for identifying hydrocarbon deposits from the surface to depths of 5 km without drilling or interpretation. It detects the presence of hydrocarbons directly by transmitting signals tuned to their resonance frequencies and detecting the re-radiated signals. Surveys can map deposits over tens of thousands of square km and determine depth, thickness, and pressure of horizons with over 90% accuracy. The technique exceeds seismic in precision and can reduce exploration costs.
referencia de trabajos hechos en el mundo tanto en petróleo y gas, que aguas, mineral, gemas y otros problemas
1.2. ¿Cómo funciona la tecnología RSS-NMR?
1. El transmisor envía una señal estrechamente direccional típica solo de la sustancia que se busca (petróleo, gas), es decir, se incluye información sobre el petróleo o el gas en la señal.
2. Una vez que la señal llega al petróleo o al gas, la señal informativa penetra en el interior de la sustancia buscada y de inmediato revela este depósito (petróleo, gas, minerales, etc.) vuelve a emerger y percibimos la información sobre el petróleo o el gas y con confianza en la superficie sabemos que hemos alcanzado al objetivo.
A esto se le llama resonancia del material que se busca, por lo tanto, no necesitamos interpretación, este es el descubrimiento directo de un depósito. La precisión es del 90-95%, por este motivo la exploración con esta tecnología es realiza en un tiempo muy corto de 15 a 30 días.
1.2.1. Alcance del Proyecto RSS-NMR
Se tienen dos etapas:
• ETAPA 1: Es el método RSS, que es remoto; recibimos datos de resonancia de imágenes espaciales en un reactor nuclear en Ucrania. La precisión es del 85-90%, que es tres veces mayor en comparación con la sísmica.
• Todo se hace a Kiev, Ucrania, por eso y de forma remota, no se gasta tiempo y energía en la parte administrativa y para la captura de los datos en el bloque a explorar. Se hace de una forma discreta sin crear alborotes en la zona y protestas cualquiera
• ETAPA 2: Es un estudio de campo de NMR que se realiza con un equipo reducido. La precisión del trabajo es del 95%. ver el siguiente video https://youtu.be/EsITieoHDSQ etapa dos de campos y conclusiones.
Con este trabajo se tiene reducción de costos además de una precisión que supera los 90 %.
This document summarizes a seminar presentation on ground penetrating radar systems. It discusses how GPR works by emitting radar pulses that reflect off underground objects and interfaces between materials, allowing buried objects and soil layers to be detected. The key components of a GPR system are described, including transmitting and receiving antennas that control resolution, and a control unit, display, and power supplies. Factors like soil type and antenna frequency determine maximum penetration depth. GPR provides accurate, non-destructive imaging of the subsurface and has applications in archaeology, geology, utility detection, and more.
Uk rss technology, comparison with conventional methodsFands-llc
The document describes an innovative RSS-NMR technology for directly identifying minerals remotely and on the ground. It compares RSS-NMR to conventional 3D seismic surveys, Earth Remote Sensing (ERS), and magnetic resonance systems (MRS). RSS-NMR can identify any type of mineral anywhere, has virtually no limitations, and works faster, more efficiently, and at lower cost than other methods. It directly detects desired minerals and provides detailed characterization of deposits, unlike indirect interpretation required by other geophysical methods.
The document discusses using NMR (nuclear magnetic resonance) technology for hydrocarbon exploration. Specifically:
1. NMR can identify hydrocarbon deposits like oil and gas to depths of up to 5 km without drilling or interpretation, unlike traditional NMR well logging which only reaches 200m.
2. NMR works by emitting a directional signal tuned to the resonance frequency of the desired substance (e.g. oil, gas) and detecting the re-emitted signal on the surface.
3. NMR surveys can identify and delineate deposits over tens of thousands of square km with over 90% accuracy, significantly exceeding the capabilities of modern seismography. This allows reducing exploration costs.
The use of geoinformatics in mineral exploration and exploitationMarguerite Walsh
The document discusses the use of geoinformatics, including remote sensing techniques, in mineral exploration and exploitation. It provides several case studies demonstrating how different remote sensing data and techniques can be used to map surface geology and identify potential mineral deposits. These include using Landsat and ASTER satellite imagery to map surficial mineralogy across large areas, detect hydrothermal alteration zones indicating gold mineralization, and identify geothermal anomalies. Integrating remote sensing data with other spatial datasets in a GIS provides additional insights. Future opportunities discussed include the increasing use of unmanned aerial vehicles and the upcoming Sentinel-2 satellite mission.
This document describes RSS-NMR (Remote Search and Prospecting of Minerals Deposits) technology. The technology uses nuclear magnetic resonance to remotely detect and characterize underground mineral deposits up to 7km deep, including oil, gas, and water. It works by exciting resonance responses in target substances using frequency spectra tuned to their molecular makeup. Survey results are obtained within 1-2 months and include deposit locations, depths, sizes, and estimated reserves. The technology offers remote and on-site surveying options to efficiently evaluate large areas and drilling sites for mineral exploration.
Ground Penetrating Radar (GPR) has the ability to map subsurface geological structures and detect variations in moisture that could help understand geothermal exploration. However, GPR is limited to shallow depths of less than 50 meters, where most geothermal reservoirs are located. This study uses GPR data from Beijing to create digital models of the subsurface and identify potential geothermal indicators like quartz sinters. The results demonstrate GPR's capability to detect geochemical markers associated with geothermal activity and map prospective geothermal reservoir locations. While GPR has limitations for deep exploration, it shows potential as a new efficient tool for initial geothermal prospecting.
The document discusses using computer vision for analyzing underwater and remote sensing data. It describes using deep learning models to automatically detect and classify objects in sonar imagery to map the seafloor and detect anomalies. Satellite and aerial imagery can be used to monitor ice conditions, detect litter, and aid shipping. Seismic data analysis can identify horizons, layers, faults and other geological features. Computer vision shows potential for automated analysis that reduces time and improves accuracy compared to manual analysis. Examples demonstrate detecting polygons on Mars that may indicate past water activity.
Role of Geophysics in the Oil and Gas IndustryMusisi Norbert
Geophysics plays an important role in the oil and gas industry by using non-invasive methods to investigate subsurface conditions. Various geophysical survey methods measure physical properties of the subsurface to aid in exploration, mapping resources, and identifying geohazards. Planning geophysical surveys requires selecting the appropriate methods, equipment, and acquisition parameters to meet project objectives and site conditions. Acquired data then undergoes processing and interpretation to develop an understanding of the subsurface.
This document introduces the TechnoTectonics methodology for identifying prospective mineral and hydrocarbon targets. It analyzes satellite images, maps, and other geospatial data to identify lineaments and intersections that often indicate mineralization. The methodology was successfully tested on blind areas, locating known deposits. Customers have been impressed with results that identified new prospective zones. The methodology integrates lineament analysis with geological, geophysical and geochemical data to create prospective maps and recommend highest priority targets for exploration.
Geophysical survey for the risk managementMario Naldi
This document discusses managing risk through geophysical survey methods for due diligence assessments. It describes how non-invasive geophysical surveys such as electromagnetic, ground penetrating radar, and electrical resistivity tomography can identify subsurface hazards cost effectively by mapping buried utilities, tanks, waste, and other underground anomalies before invasive investigations. Large scale surveys identify potential risks while small scale surveys characterize identified anomalies to better inform follow up actions.
Geophysical survey for the risk managementMario Naldi
This document discusses managing risk through geophysical survey methods for due diligence assessments. It describes how non-invasive geophysical surveys such as electromagnetic, ground penetrating radar, and electrical resistivity tomography can identify subsurface hazards cost effectively by mapping buried utilities, tanks, waste, and other underground anomalies before invasive investigations. Large scale surveys identify potential risks while small scale surveys characterize identified anomalies to better inform follow up actions.
Research Inventy : International Journal of Engineering and Science is published by the group of young academic and industrial researchers with 12 Issues per year. It is an online as well as print version open access journal that provides rapid publication (monthly) of articles in all areas of the subject such as: civil, mechanical, chemical, electronic and computer engineering as well as production and information technology. The Journal welcomes the submission of manuscripts that meet the general criteria of significance and scientific excellence. Papers will be published by rapid process within 20 days after acceptance and peer review process takes only 7 days. All articles published in Research Inventy will be peer-reviewed.
Ground penetrating radar (GPR) scanning has revolutionized subsurface exploration by utilizing electromagnetic waves to image underground structures and objects. GPR systems consist of a control unit, antenna, and data processing unit. The antenna transmits and receives signals that reflect off underground materials, allowing detailed subsurface images to be constructed. GPR has many applications, including archaeology, infrastructure assessment, environmental studies, forensics, and utility detection. Advancements aim to improve resolution, depth penetration, integration with other technologies, and autonomous data collection. GPR scanning has transformed fields ranging from archaeology to engineering by providing a non-destructive method to explore what lies beneath the earth's surface.
Here are the lab assignments of Geophysical Exploration. It includes introduction of different geophysical equipments, seismic survey, GPR, magnetic survey, Gravity survey and resistivity survey. All applications of survey is listed in the document.
The document describes the NuraghEO project which uses aerial and satellite data to study Sardinian Nuragic archaeological sites. The project aims to develop a methodology using remote sensing to identify areas of interest for excavation and monitor sites for subsidence or other changes. Researchers are analyzing interferometric radar data to detect ground motions and optical data to map vegetation and temperature anomalies that could indicate buried structures. The Planetek Rheticus Platform is providing multi-temporal aerial and satellite imagery which is analyzed using algorithms to identify areas needing further study and monitoring to help archaeological research.
Communications Mining Series - Zero to Hero - Session 1DianaGray10
This session provides introduction to UiPath Communication Mining, importance and platform overview. You will acquire a good understand of the phases in Communication Mining as we go over the platform with you. Topics covered:
• Communication Mining Overview
• Why is it important?
• How can it help today’s business and the benefits
• Phases in Communication Mining
• Demo on Platform overview
• Q/A
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
Brief information for use nmr in geophysics1Fands-llc
This document summarizes an NMR technique for identifying hydrocarbon deposits from the surface to depths of 5 km without drilling or interpretation. It detects the presence of hydrocarbons directly by transmitting signals tuned to their resonance frequencies and detecting the re-radiated signals. Surveys can map deposits over tens of thousands of square km and determine depth, thickness, and pressure of horizons with over 90% accuracy. The technique exceeds seismic in precision and can reduce exploration costs.
referencia de trabajos hechos en el mundo tanto en petróleo y gas, que aguas, mineral, gemas y otros problemas
1.2. ¿Cómo funciona la tecnología RSS-NMR?
1. El transmisor envía una señal estrechamente direccional típica solo de la sustancia que se busca (petróleo, gas), es decir, se incluye información sobre el petróleo o el gas en la señal.
2. Una vez que la señal llega al petróleo o al gas, la señal informativa penetra en el interior de la sustancia buscada y de inmediato revela este depósito (petróleo, gas, minerales, etc.) vuelve a emerger y percibimos la información sobre el petróleo o el gas y con confianza en la superficie sabemos que hemos alcanzado al objetivo.
A esto se le llama resonancia del material que se busca, por lo tanto, no necesitamos interpretación, este es el descubrimiento directo de un depósito. La precisión es del 90-95%, por este motivo la exploración con esta tecnología es realiza en un tiempo muy corto de 15 a 30 días.
1.2.1. Alcance del Proyecto RSS-NMR
Se tienen dos etapas:
• ETAPA 1: Es el método RSS, que es remoto; recibimos datos de resonancia de imágenes espaciales en un reactor nuclear en Ucrania. La precisión es del 85-90%, que es tres veces mayor en comparación con la sísmica.
• Todo se hace a Kiev, Ucrania, por eso y de forma remota, no se gasta tiempo y energía en la parte administrativa y para la captura de los datos en el bloque a explorar. Se hace de una forma discreta sin crear alborotes en la zona y protestas cualquiera
• ETAPA 2: Es un estudio de campo de NMR que se realiza con un equipo reducido. La precisión del trabajo es del 95%. ver el siguiente video https://youtu.be/EsITieoHDSQ etapa dos de campos y conclusiones.
Con este trabajo se tiene reducción de costos además de una precisión que supera los 90 %.
This document summarizes a seminar presentation on ground penetrating radar systems. It discusses how GPR works by emitting radar pulses that reflect off underground objects and interfaces between materials, allowing buried objects and soil layers to be detected. The key components of a GPR system are described, including transmitting and receiving antennas that control resolution, and a control unit, display, and power supplies. Factors like soil type and antenna frequency determine maximum penetration depth. GPR provides accurate, non-destructive imaging of the subsurface and has applications in archaeology, geology, utility detection, and more.
Uk rss technology, comparison with conventional methodsFands-llc
The document describes an innovative RSS-NMR technology for directly identifying minerals remotely and on the ground. It compares RSS-NMR to conventional 3D seismic surveys, Earth Remote Sensing (ERS), and magnetic resonance systems (MRS). RSS-NMR can identify any type of mineral anywhere, has virtually no limitations, and works faster, more efficiently, and at lower cost than other methods. It directly detects desired minerals and provides detailed characterization of deposits, unlike indirect interpretation required by other geophysical methods.
The document discusses using NMR (nuclear magnetic resonance) technology for hydrocarbon exploration. Specifically:
1. NMR can identify hydrocarbon deposits like oil and gas to depths of up to 5 km without drilling or interpretation, unlike traditional NMR well logging which only reaches 200m.
2. NMR works by emitting a directional signal tuned to the resonance frequency of the desired substance (e.g. oil, gas) and detecting the re-emitted signal on the surface.
3. NMR surveys can identify and delineate deposits over tens of thousands of square km with over 90% accuracy, significantly exceeding the capabilities of modern seismography. This allows reducing exploration costs.
The use of geoinformatics in mineral exploration and exploitationMarguerite Walsh
The document discusses the use of geoinformatics, including remote sensing techniques, in mineral exploration and exploitation. It provides several case studies demonstrating how different remote sensing data and techniques can be used to map surface geology and identify potential mineral deposits. These include using Landsat and ASTER satellite imagery to map surficial mineralogy across large areas, detect hydrothermal alteration zones indicating gold mineralization, and identify geothermal anomalies. Integrating remote sensing data with other spatial datasets in a GIS provides additional insights. Future opportunities discussed include the increasing use of unmanned aerial vehicles and the upcoming Sentinel-2 satellite mission.
This document describes RSS-NMR (Remote Search and Prospecting of Minerals Deposits) technology. The technology uses nuclear magnetic resonance to remotely detect and characterize underground mineral deposits up to 7km deep, including oil, gas, and water. It works by exciting resonance responses in target substances using frequency spectra tuned to their molecular makeup. Survey results are obtained within 1-2 months and include deposit locations, depths, sizes, and estimated reserves. The technology offers remote and on-site surveying options to efficiently evaluate large areas and drilling sites for mineral exploration.
Ground Penetrating Radar (GPR) has the ability to map subsurface geological structures and detect variations in moisture that could help understand geothermal exploration. However, GPR is limited to shallow depths of less than 50 meters, where most geothermal reservoirs are located. This study uses GPR data from Beijing to create digital models of the subsurface and identify potential geothermal indicators like quartz sinters. The results demonstrate GPR's capability to detect geochemical markers associated with geothermal activity and map prospective geothermal reservoir locations. While GPR has limitations for deep exploration, it shows potential as a new efficient tool for initial geothermal prospecting.
The document discusses using computer vision for analyzing underwater and remote sensing data. It describes using deep learning models to automatically detect and classify objects in sonar imagery to map the seafloor and detect anomalies. Satellite and aerial imagery can be used to monitor ice conditions, detect litter, and aid shipping. Seismic data analysis can identify horizons, layers, faults and other geological features. Computer vision shows potential for automated analysis that reduces time and improves accuracy compared to manual analysis. Examples demonstrate detecting polygons on Mars that may indicate past water activity.
Role of Geophysics in the Oil and Gas IndustryMusisi Norbert
Geophysics plays an important role in the oil and gas industry by using non-invasive methods to investigate subsurface conditions. Various geophysical survey methods measure physical properties of the subsurface to aid in exploration, mapping resources, and identifying geohazards. Planning geophysical surveys requires selecting the appropriate methods, equipment, and acquisition parameters to meet project objectives and site conditions. Acquired data then undergoes processing and interpretation to develop an understanding of the subsurface.
This document introduces the TechnoTectonics methodology for identifying prospective mineral and hydrocarbon targets. It analyzes satellite images, maps, and other geospatial data to identify lineaments and intersections that often indicate mineralization. The methodology was successfully tested on blind areas, locating known deposits. Customers have been impressed with results that identified new prospective zones. The methodology integrates lineament analysis with geological, geophysical and geochemical data to create prospective maps and recommend highest priority targets for exploration.
Geophysical survey for the risk managementMario Naldi
This document discusses managing risk through geophysical survey methods for due diligence assessments. It describes how non-invasive geophysical surveys such as electromagnetic, ground penetrating radar, and electrical resistivity tomography can identify subsurface hazards cost effectively by mapping buried utilities, tanks, waste, and other underground anomalies before invasive investigations. Large scale surveys identify potential risks while small scale surveys characterize identified anomalies to better inform follow up actions.
Geophysical survey for the risk managementMario Naldi
This document discusses managing risk through geophysical survey methods for due diligence assessments. It describes how non-invasive geophysical surveys such as electromagnetic, ground penetrating radar, and electrical resistivity tomography can identify subsurface hazards cost effectively by mapping buried utilities, tanks, waste, and other underground anomalies before invasive investigations. Large scale surveys identify potential risks while small scale surveys characterize identified anomalies to better inform follow up actions.
Research Inventy : International Journal of Engineering and Science is published by the group of young academic and industrial researchers with 12 Issues per year. It is an online as well as print version open access journal that provides rapid publication (monthly) of articles in all areas of the subject such as: civil, mechanical, chemical, electronic and computer engineering as well as production and information technology. The Journal welcomes the submission of manuscripts that meet the general criteria of significance and scientific excellence. Papers will be published by rapid process within 20 days after acceptance and peer review process takes only 7 days. All articles published in Research Inventy will be peer-reviewed.
Ground penetrating radar (GPR) scanning has revolutionized subsurface exploration by utilizing electromagnetic waves to image underground structures and objects. GPR systems consist of a control unit, antenna, and data processing unit. The antenna transmits and receives signals that reflect off underground materials, allowing detailed subsurface images to be constructed. GPR has many applications, including archaeology, infrastructure assessment, environmental studies, forensics, and utility detection. Advancements aim to improve resolution, depth penetration, integration with other technologies, and autonomous data collection. GPR scanning has transformed fields ranging from archaeology to engineering by providing a non-destructive method to explore what lies beneath the earth's surface.
Here are the lab assignments of Geophysical Exploration. It includes introduction of different geophysical equipments, seismic survey, GPR, magnetic survey, Gravity survey and resistivity survey. All applications of survey is listed in the document.
The document describes the NuraghEO project which uses aerial and satellite data to study Sardinian Nuragic archaeological sites. The project aims to develop a methodology using remote sensing to identify areas of interest for excavation and monitor sites for subsidence or other changes. Researchers are analyzing interferometric radar data to detect ground motions and optical data to map vegetation and temperature anomalies that could indicate buried structures. The Planetek Rheticus Platform is providing multi-temporal aerial and satellite imagery which is analyzed using algorithms to identify areas needing further study and monitoring to help archaeological research.
Communications Mining Series - Zero to Hero - Session 1DianaGray10
This session provides introduction to UiPath Communication Mining, importance and platform overview. You will acquire a good understand of the phases in Communication Mining as we go over the platform with you. Topics covered:
• Communication Mining Overview
• Why is it important?
• How can it help today’s business and the benefits
• Phases in Communication Mining
• Demo on Platform overview
• Q/A
Unlock the Future of Search with MongoDB Atlas_ Vector Search Unleashed.pdfMalak Abu Hammad
Discover how MongoDB Atlas and vector search technology can revolutionize your application's search capabilities. This comprehensive presentation covers:
* What is Vector Search?
* Importance and benefits of vector search
* Practical use cases across various industries
* Step-by-step implementation guide
* Live demos with code snippets
* Enhancing LLM capabilities with vector search
* Best practices and optimization strategies
Perfect for developers, AI enthusiasts, and tech leaders. Learn how to leverage MongoDB Atlas to deliver highly relevant, context-aware search results, transforming your data retrieval process. Stay ahead in tech innovation and maximize the potential of your applications.
#MongoDB #VectorSearch #AI #SemanticSearch #TechInnovation #DataScience #LLM #MachineLearning #SearchTechnology
Enchancing adoption of Open Source Libraries. A case study on Albumentations.AIVladimir Iglovikov, Ph.D.
Presented by Vladimir Iglovikov:
- https://www.linkedin.com/in/iglovikov/
- https://x.com/viglovikov
- https://www.instagram.com/ternaus/
This presentation delves into the journey of Albumentations.ai, a highly successful open-source library for data augmentation.
Created out of a necessity for superior performance in Kaggle competitions, Albumentations has grown to become a widely used tool among data scientists and machine learning practitioners.
This case study covers various aspects, including:
People: The contributors and community that have supported Albumentations.
Metrics: The success indicators such as downloads, daily active users, GitHub stars, and financial contributions.
Challenges: The hurdles in monetizing open-source projects and measuring user engagement.
Development Practices: Best practices for creating, maintaining, and scaling open-source libraries, including code hygiene, CI/CD, and fast iteration.
Community Building: Strategies for making adoption easy, iterating quickly, and fostering a vibrant, engaged community.
Marketing: Both online and offline marketing tactics, focusing on real, impactful interactions and collaborations.
Mental Health: Maintaining balance and not feeling pressured by user demands.
Key insights include the importance of automation, making the adoption process seamless, and leveraging offline interactions for marketing. The presentation also emphasizes the need for continuous small improvements and building a friendly, inclusive community that contributes to the project's growth.
Vladimir Iglovikov brings his extensive experience as a Kaggle Grandmaster, ex-Staff ML Engineer at Lyft, sharing valuable lessons and practical advice for anyone looking to enhance the adoption of their open-source projects.
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1. Genesis Corporation
Institute of Geophysics and Problems of the Earth Limited
GeoNMR
Geophysical technology
for remote search and prospecting
of mineral deposits
2. Five from the six
of wild cat wells
is dry*
*From data of Russian State Institute of Oil and Gas
2
3. Three – five years
term of opening
of new deposit
by traditional methods
3
4. Probability of opening
of new deposit by
traditional method
not exceed 30%
From data Utah Division of Oil, Gas and Mining, 2007-2010 years
From data Kansas Geological Survey (www.kgs.ku.edu), 2008 year
4
5. It is required
1 To accelerate terms of the search
2 Increase credibility of the search
3 Decrease costs of the search
Is it possible?
5
6. Technology of “direct” search of mineral deposits
GeoNMR
We developed technology “GeoNMR” for the search of
oil, gas, water, geothermal water, gold and other mineral
deposits.
Superweak NMR interactions lies in the base of technology.
6
7. Possibilities of the “GeoNMR” technology
Territorial applicability – no limitations (any in-land or shelf area)
Sounding depth – from 0 to 6 km underground
Detectable minerals – water (also geothermal), oil, gas,
different metals in ore bed
Success ratio – for hydrocarbons and water reserves >90%
Duration of work – typically 4 months
Safety – the method is environment - friendly
and completely safe for people
7
8. For ensuring of quality and efficiency of search
we use two stages:
Remote investigations – search mineral
deposits by means of analog satellite photo.
Prospecting stage – expedition directly on
site and prospecting by means of mobile
equipment.
8
9. Services on base of “GeoNMR” technology
Service Description Term
Testing of Presence or absence of mineral deposits on a
1 month
territory territory
Revelation of deposits on the inspected
Remote
territory, drawing of their ground contours 2 months
investigation
and calculation of their occurrence depths
Measurement of exact parameters of
deposits, obtainment of 3D shape of real
Prospecting
deposits, choice of optimum points for 2 months
of deposit
effective drilling, calculation of extractable
reserves
9
10. Comparative Efficiency
Results (for an area ~1000 sq. km)
Methods Conducted works
Wells for
Effectiveness Duration opening
Space survey
Geological survey < 60 % 3–5 6*
Traditional years
Geophysical survey
Searching boring
Remote
GeoNMR investigations 4–6 1
Prospecting on > 90 % months
site
*From data of Russian State Institute of Oil and Gas
10
11. Results of work
Map of investigated area with contours of found deposits
Detailed information about deposits
Square of deposits
Extractable volume of minerals (oil, gas or water)
Depths of bedding
Optimal points for productive drillings
Thickness of productive horizons
3D model of deposits with cuts
For water deposits approximate inflow will be calculated
For geothermal deposits information about temperature
of water will be additionally shown
11
12. How does “GeoNMR” technology work?
At the first part of our work analog satellite space picture of the territory
is used, which will be activated inside of research nuclear reactor. It is
necessary for “revelation” of “hidden” information about searched
substance.
12
13. How does “GeoNMR” technology work?
After treatment inside of reactor, transferring of hidden images by
means of special wave scanner occurs and mathematic
calculation of results is conducted.
Duration of first part of work is near 2 months
13
14. How does “GeoNMR” technology work?
Second part of work is conducted directly on site by means of
group of specialists with using of mobile equipment. The tasks of
second part of work are more accurate definition of borders and
depths of deposit, choosing the optimal points for drilling
Duration of second part of work is near 2 months
14
15. How does “GeoNMR” technology work?
«GeoNMR» mobile equipment use:
- superweak NMR interactions
- electric-resonance sounding
NMR and electric methods supplement each other
and can give more additional information, which
allows to describe mineral deposits with more
accuracy.
15
16. How does “GeoNMR” technology work?
Examples of data of electrical investigations
16
17. How does “GeoNMR” technology work?
Definition of depths of bedding by means of mobile complex equipment (NMR)
17
18. Patented in Ukraine
METHOD OF IDENTIFICATION
OF SUBSTANCE BY MEANS OF
INDUCED NUCLEAR MAGNETIC
RESONANCE
Patent’s number: 58504
Inventor: Oleksandr Tarnovskyi (UA)
Patent’s formula:
1. Method of identification of substance with using
of nuclear magnetic resonance, which includes
recording of characteristics of substance by the
instrumentality of scan a substance electromagnetic
waves with frequencies …..
18
19. Genesis Corporation
Institute of Geophysics and Problems of the Earth Limited
We will be glad to see YOU as our client!!!
v.kholodov@gmail.com
www.GeoNMR.com
19
Editor's Notes
№ 1
Юта Field Type 2011 2010 2009 2008 Development 362 713 558 1091 Extension 84 151 41 84 Wildcat 37 32 35 61 Dry hole 29 32 61 По данным Kansas Geological Survey (www.kgs.ku.edu) в 2008 г. в штате Канзас было открыто 102 новых ме- сторождения и расширены (разведаны) другие поля, при этом было пробурено 1690 нефтяных и 1620 газо- вых скважин. Несложный расчет показывает, что для открытия одного месторождения бурилось 32,5 сква- жины, а коэффициент успешности составил 3,1 %.