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4D GeoSEIS Project:
Uniqueness of 4D GeoSEIS Tomography technology is determined by algorithms that transforms digital images of physical fields into volumetric space-time models which reflects not only an internal structure, but also evolution of field`s structures.
The author will review any serious proposals on purchasing and the further development, on testing and application 4D GeoSEIS technologies in NASA/ESA/USGS and in your Projects.
Using 4D GeoSEIS software for multifactor volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modeling we offer:
Multifactor volumetric structural-geodynamic models “4D GeoSEISM” with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 22 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
Integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEISM had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
Seeking business partners for 3D-4D GeoSEIS Tomography modeling and Monitoring…
Seeking business partners for developing 3D-4D GeoSEIS Tomography transformation of 2D-3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video...
* We are looking for investment partnership for developing 6D GeoSEIS Tomography transformation of 3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video... If you interest it, please don’t miss this opportunity. Please check of the information:
* Uniqueness of 3D-4D GeoSEIS Tomography technology is determined by algorithms that transforms digital images of physical fields into volumetric space-time models which reflects not only an volumetric structure, but also evolution of field`s structures.
* 6D GeoSEIS Tomography brings 3D scan visualization to a whole 6D volumetric animation level. Its 6D Space-time-based Technology extends the capabilities of volumetric modeling practices – allowing anyone, anywhere to see, explore and share (in real-time) 6D interactive views directly from traditional 3D Seismic, MRI, CT and ultrasound scans…
My Customers & Partners: Institute of Geological Sciences of NAS (National Academy of Sciences of Ukraine), Institute of Geotechnical Mechanics of NAS, Institute of Problems on Nature Management & Ecology of NAS, State Enterprise NIGRI (Mining-Ore Research Institute)...
Publications and scientific reports:
www.cosis.net/members/submissions.php, www.cosis.net/members/submissions.php?user=u8c8d2c4436821...
Certificates:
www.flickr.com/photos/jeisus2012/5531682555/in/photostream , www.slideshare.net/JarosloveBondarenko/4-d-geoseis, foto.mail.ru/mail/jeisus/7/64.html# , foto.mail.ru/mail/jeisus/7/62.html# , foto.mail.ru/mail/jeisus/7/65.html#
Shestopalov V.M., Bondarenko Ya.I., Zayonts I.O., Rudenko Yu.F., Bohuslavsky A.S. Complexation of Structural-Geodynamical and Hydrogeological Methods of Studying Areas to Reveal Geological Structural Perspectives for Deep Isolation of Radioactive Wastes. // Field Testing and Associated Modeling of Potential High-Level Nuclear Waste Geologic Disposal Sites // Berkeley, USA, 1998.
Kolotenko V.P. Bondarenko J.J. Spiritual and Moral aspects of Sustainable Development Theory // Man and City. Towards a Human and Sustainable Development // Napoli, Italy, 2000.
Bondarenko J.J., Risk analysis, synthesis and Spiritual Energy-Information Structure Modeling 'SEISM' to reveal environmental perspectives for isolation of radioactive and hazardous chemical wastes // ECO-INFORMA 2001 // Chicago, USA, 2001.
Bondarenko J. J., The Multifactor Predictive SEIS (GIS) Model of ecological, genetic and population health risk in connection with dangerous bio-geodynamical processes in geopathogenic hazard zones //ECO-INFORMA 2001// Chicago, USA, 2001.
Zayonts I.O., Bondarenko J.J., Slipchenko B., Lysychenko G.V., New approaches to the problem of geoecological risk for urbanized territories // ECO-INFORMA 2001 // Chicago, USA, 2001...
3D GeoSEIS Tomography volumetric model for gas-bearing formation of Zasyadko mine (Ukraine) is created by 3D GeoSEIS Tomography processing of top surface.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
Seeking business partners for 3D-4D GeoSEIS Tomography modeling and Monitoring…
Seeking business partners for developing 3D-4D GeoSEIS Tomography transformation of 2D-3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video...
* We are looking for investment partnership for developing 6D GeoSEIS Tomography transformation of 3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video... If you interest it, please don’t miss this opportunity. Please check of the information:
* Uniqueness of 3D-4D GeoSEIS Tomography technology is determined by algorithms that transforms digital images of physical fields into volumetric space-time models which reflects not only an volumetric structure, but also evolution of field`s structures.
* 6D GeoSEIS Tomography brings 3D scan visualization to a whole 6D volumetric animation level. Its 6D Space-time-based Technology extends the capabilities of volumetric modeling practices – allowing anyone, anywhere to see, explore and share (in real-time) 6D interactive views directly from traditional 3D Seismic, MRI, CT and ultrasound scans…
My Customers & Partners: Institute of Geological Sciences of NAS (National Academy of Sciences of Ukraine), Institute of Geotechnical Mechanics of NAS, Institute of Problems on Nature Management & Ecology of NAS, State Enterprise NIGRI (Mining-Ore Research Institute)...
Publications and scientific reports:
www.cosis.net/members/submissions.php, www.cosis.net/members/submissions.php?user=u8c8d2c4436821...
Certificates:
www.flickr.com/photos/jeisus2012/5531682555/in/photostream , www.slideshare.net/JarosloveBondarenko/4-d-geoseis, foto.mail.ru/mail/jeisus/7/64.html# , foto.mail.ru/mail/jeisus/7/62.html# , foto.mail.ru/mail/jeisus/7/65.html#
Shestopalov V.M., Bondarenko Ya.I., Zayonts I.O., Rudenko Yu.F., Bohuslavsky A.S. Complexation of Structural-Geodynamical and Hydrogeological Methods of Studying Areas to Reveal Geological Structural Perspectives for Deep Isolation of Radioactive Wastes. // Field Testing and Associated Modeling of Potential High-Level Nuclear Waste Geologic Disposal Sites // Berkeley, USA, 1998.
Kolotenko V.P. Bondarenko J.J. Spiritual and Moral aspects of Sustainable Development Theory // Man and City. Towards a Human and Sustainable Development // Napoli, Italy, 2000.
Bondarenko J.J., Risk analysis, synthesis and Spiritual Energy-Information Structure Modeling 'SEISM' to reveal environmental perspectives for isolation of radioactive and hazardous chemical wastes // ECO-INFORMA 2001 // Chicago, USA, 2001.
Bondarenko J. J., The Multifactor Predictive SEIS (GIS) Model of ecological, genetic and population health risk in connection with dangerous bio-geodynamical processes in geopathogenic hazard zones //ECO-INFORMA 2001// Chicago, USA, 2001.
Zayonts I.O., Bondarenko J.J., Slipchenko B., Lysychenko G.V., New approaches to the problem of geoecological risk for urbanized territories // ECO-INFORMA 2001 // Chicago, USA, 2001...
The perspective projection of the volumetric structural-cinematic-geodynamic 4Dseist model of Prutovka gabbroid intrusive complex with predicted zones of Cu-Ni-Co-PGM ore.
The volumetric 4D GeoSEIST model of distribution of Cu-Ni-Co-Pt mineralization has been predicted on the basis of the most informative characteristics of gravity anomaly field images. Certificate of validation of 4D GeoSEIST Technology for predicts Ni-Cu-Co deposit: www.flickr.com/photos/jeisus2012/5531682555/in/set-721576... .
Using 4D GeoSEIS software for multifactor volumetric (structural-geodynamical, geophysical, geochemical and mineralogical) modelling we offer:
Multifactorial volumetric structural-cinematic-geodynamic 4Dseist model with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral and geophysical images for cost-effective geological prospecting.
During 22 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
Integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIST software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamical models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIST Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEIST had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE of “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamical modelling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of folds amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamical zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
2D GeoSEIS map of multifactor health risks, geophysical and geodynamical hazard zones is created by decoding and processing of SPOT image (space resolution: 10-20м).
The multifactor nonlinear correlation between solar activity and cosmic ray variations, geophysical, geodynamical, geochemical, atmospheric, technological, biological, socio-economical processes and oncologic case rate frequency, general and primary population sickness cases in Dnepropetrovsk City (1.2 million persons) are described by the multifactor predictive 3D GeoSEIS Model of geopathic zones that determines the human health risk and hazards.
THE MULTIFACTOR PREDICTIVE SEIS (GIS) MODEL OF ECOLOGICAL, GENETICAL AND POPULATION HEALTH RISK IN CONNECTION WITH DANGEROUS BIO-GEODYNAMICAL PROCESSES IN GEOPATHOGENIC HAZARD ZONES (ECO-INFORMA 2001// Chicago, USA, 2001)
* We have created the multifactor predictive 3D SEIS Tomography model for the analysis of multidimensional Phase-Metric SpaceTime nonlinear correlation and variations of rhythms of human health, ecological, genetic, epidemiological risks, demographic, socio-economic, bio-geophysical, bio-geodynamical processes in geopathogenic hazard zones.
* Space maps of vegetation index, anthropogenic-landscape and landscape-geophysical human health risk of Dnepropetrovsk City are presented based elements of multilayer GIS and 3D GeoSEIS Tomography model, which include multispectral images, maps of different geophysical, geochemical, anthropogenic and citogenic risk factors, maps of integral oncologic case rate frequency, general and primary population sickness cases for administrative districts.
* Structural map of large bio-geodynamical (geopathogenic) zones (Fig. 3) with marked desynchronization of natural and anthropogenic rhythms offers the most plausible phase-metric basis for their study and forecast of oncologic case rate frequency (1) of childrens / adults “NOV” (2) and hazardous environmental destruction processes.
* Correlation trigrams on interaction of specified values of gravitational “G” and magnetic “Z” fields with oncologic case rate frequency of adults “NOV” ( Fig.4 ), general and primary population sickness cases have been used for statistical classification of regional geopathogenic zones as to landscape-geophysical human health risk zones.
* Results of multilayer spatio-temporal correlation of geophysical field parameters and variations of population sickness rate rhythms have enabled us to state grounds and to develop medical-biological and bio-geodynamic classification of geopathogenic zones. Bio-geodynamic model has served to define contours of anthropogenic-landscape and landscape-geophysical human health risk in Dnipropetrovsk City…
Publications and scientific reports:
www.cosis.net/members/submissions.php, www.cosis.net/members/submissions.php?user=u8c8d2c4436821...
Certificates:
www.flickr.com/photos/jeisus2012/5531682555/in/photostream , www.slideshare.net/JarosloveBondarenko/4-d-geoseis, foto.mail.ru/mail/jeisus/7/64.html# , foto.mail.ru/mail/jeisus/7/62.html# , foto.mail.ru/mail/jeisus/7/65.html#
Shestopalov V.M., Bondarenko Ya.I., Zayonts I.O., Rudenko Yu.F., Bohuslavsky A.S. Complexation of Structural-Geodynamical and Hydrogeological Methods of Studying Areas to Reveal Geological Structural Perspectives for Deep Isolation of Radioactive Wastes. // Field Testing and Associated Modeling of Potential High-Level Nuclear Waste Geologic Disposal Sites // Berkeley, USA, 1998.
Kolotenko V.P. Bondarenko J.J. Spiritual and Moral aspects of Sustainable Development Theory // Man and City. Towards a Human and Sustainable Development // Napoli, Italy, 2000.
Bondarenko J.J., Risk analysis, synthesis and Spiritual Energy-Information Structure Modeling 'SEISM' to reveal environmental perspectives for isolation of radioactive and hazardous chemical wastes // ECO-INFORMA 2001 // Chicago, USA, 2001.
Bondarenko J. J., The Multifactor Predictive SEIS (GIS) Model of ecological, genetic and population health risk in connection with dangerous bio-geodynamical processes in geopathogenic hazard zones //ECO-INFORMA 2001// Chicago, USA, 2001.
Zayonts I.O., Bondarenko J.J., Slipchenko B., Lysychenko G.V., New approaches to the problem of geoecological risk for urbanized territories // ECO-INFORMA 2001 // Chicago, USA, 2001...
3D-4Dseist volumetric model of rock`s resistance field (The subsurface King, quaternion) of gas-bearing formation is created by 3D-4Dseist processing of rock`s resistance date.
Using 3D-4Dseist software for multifactor volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modeling we offer:
The multifactor volumetric 3D-4Dseist models with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 22 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
Integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
3Dseist software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a 4Dseist model through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4Dseist technology had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4Dseist Tomography!
VALIDATION CERTIFICATE for 4Dseist Tomography Method (English ver.)http://www.slideshare.net/JarosloveBondarenko/4-d-geoseissertificatrev1.
*Using 3Dseist Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3Dseist Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4Dseist Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4Dseist Tomography Method is a unique tool of 3D-4D spacetime transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4Dseist GIS for an exact and cost-effective 4D spacetime modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4Dseist Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
The volumetric 3D-4D SEIST Model of an internal spacetime brightness field of a Sun is created by the 3D SEIST transformation of 2D image!
The 3Dseist slices of 4Dseist unified (inertial quark-lepton-photonic) field is created by the 3D-4D SEIST transformation and integration of 2D images!
Take your geospatial analysis to the next 4D-7D level with 4D-7D SEIS Tomography!
Seeking business partners for 3D-4D GeoSEIS Tomography modelling and Monitoring…
Seeking business partners for developing 3D-4D GeoSEIS Tomography transformation of 2D-3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video...
* We are looking for investment partnership for developing 6D GeoSEIS Tomography transformation of 3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video... If you interest it, please don’t miss this opportunity. Please check of the information:
* The uniqueness of 3D-4D GeoSEIS Tomography technology is determined by algorithms that transforms digital images of physical fields into volumetric spacetime models which reflects its volumetric structure and evolution!
* 6D GeoSEIS Tomography brings 3D scan visualization to a whole 6D volumetric animation level. Its 6D Space-time-based Technology extends the capabilities of volumetric modeling practices – allowing anyone, anywhere to see, explore and share (in real-time) 6D interactive views directly from traditional 3D Seismic, MRI, CT and ultrasound scans…
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
My Customers & Partners: Institute of Geological Sciences of NAS (National Academy of Sciences of Ukraine), Institute of Geotechnical Mechanics of NAS, Institute of Problems on Nature Management & Ecology of NAS, State Enterprise NIGRI (Mining-Ore Research Institute)...
Publications and scientific reports:
www.cosis.net/members/submissions.php, www.cosis.net/members/submissions.php?user=u8c8d2c4436821...
Certificates:
www.flickr.com/photos/jeisus2012/5531682555/in/photostream , www.slideshare.net/JarosloveBondarenko/4-d-geoseis, foto.mail.ru/mail/jeisus/7/64.html# , foto.mail.ru/mail/jeisus/7/62.html# , foto.mail.ru/mail/jeisus/7/65.html#
Shestopalov V.M., Bondarenko Ya.I., Zayonts I.O., Rudenko Yu.F., Bohuslavsky A.S. Complexation of Structural-Geodynamical and Hydrogeological Methods of Studying Areas to Reveal Geological Structural Perspectives for Deep Isolation of Radioactive Wastes. // Field Testing and Associated Modeling of Potential High-Level Nuclear Waste Geologic Disposal Sites // Berkeley, USA, 1998.
Kolotenko V.P. Bondarenko J.J. Spiritual and Moral aspects of Sustainable Development Theory // Man and City. Towards a Human and Sustainable Development // Napoli, Italy, 2000.
Bondarenko J.J., Risk analysis, synthesis and Spiritual Energy-Information Structure Modeling 'SEISM' to reveal environmental perspectives for isolation of radioactive and hazardous chemical wastes // ECO-INFORMA 2001 // Chicago, USA, 2001.
Bondarenko J. J., The Multifactor Predictive SEIS (GIS) Model of ecological, genetic and population health risk in connection with dangerous bio-geodynamical processes in geopathogenic hazard zones //ECO-INFORMA 2001// Chicago, USA, 2001.
Zayonts I.O., Bondarenko J.J., Slipchenko B., Lysychenko G.V., New approaches to the problem of geoecological risk for urbanized territories // ECO-INFORMA 2001 // Chicago, USA, 2001.
3D GeoSEIS Model & Orthoslice of gravity field (Bouguer anomaly) of the Prutovka gabbro intrusive complex with Cu-Ni-Co-Pt deposit (Ukrainian Cristalline Shield).
Volumetric 3D GeoSEIS model of distribution of Cu-Ni-Co-Pt mineralization has been predicted on the basis of the most informative characteristics of gravity anomaly field images. Certificate of validation 3D GeoSEIS Technology for predicts Ni-Cu-Co deposit: www.flickr.com/photos/jeisus2012/5531682555/in/set-721576... .
Using 4D GeoSEIS software for multifactor volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modeling we offer:
Multifactor volumetric structural-geodynamic models “4D GeoSEISM” with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 22 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
Integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEISM had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
World-first discovery of 4D GeoSEIS Tomography Method can help save cost for ore deposits prospecting
and 4D Risk Modeling/Monitoring !
* We propose your company partnership on integrating AMT, Magnetic, Gravity, IP, Seismic etc. into multicomponent volumetric 3D-4D GeoSEIS Tomography model:
The integrated 3D-4D GeoSEIS Tomography™ Method is a unique tool of transformations & integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry and geophysical data (AMT, Magnetic, Gravity, IP, Seismic etc.) into multifactor volumetric 3D-4D GeoSEIS (3D-4D SpaceTime) Tomography Model for exact ranging and forecasting of ore deposits, multifactor volumetric mapping of low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, cost-effective 4D Geomechanical Modeling/Monitoring: www.flickr.com/photos/jeisus2012/sets/72157626153283579/w...;
The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Outputs:
*Development of data acquisition and interpretation strategies aimed at generating and prioritizing targets for maximum expected value. Such services will most likely be used for targeting ore deposits in areas where the available data is insufficient to generate good 3D- 4D geological interpretations;
*Direct prediction of favorable locations for target ore deposits on volumetric space-time geometries provided by 3D-4D GeoSEIS Tomography model;
*Prediction and prioritization of favorable ore environments in 3D-4D GeoSEIS Tomography models by translation of modeling results - obtained by running a large series of models using simplified geometries for a range of possible ore host scenarios - into 3D GIS;
*Assessment of the relative favorability of terrains for the discovery of certain ore & oil-gas trap types based on the multicomponent volumetric 4D GeoSEIS Tomography modeling of crustal scale magmatic-hydrothermal fluid generation, deformation and fluid flow based on geodynamic scenarios.
* We have used multispectral images of WorldView-2 satellite with 1-2 meter resolution for volumetric 3D GeoSEIS mapping (deep: 500-1500m) with much higher resolution (0,5-2m) than 3D seismic, magneto-telluric, electromagnetic data.
* We have used geophysical data & multispectral images of Landsat 5-7, ASTER, Hyperion satellites with 15-30 meter resolution for predict volcanic/earthquake activity and volumetric mapping of volcano-tectonic structures up to depth 60km: www.flickr.com/photos/jeisus2012/5559736588/in/set-721576....
* Volumetric 3D-4D GeoSEIS models will allow to increase accuracy of tectonic structures mapping on deep horizons to a level of near-surface horizons, that in many times will raise the efficiency and will reduce the operating costs for geological prospecting and explorations.
. * 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
* Mining professionals of State Enterprise "Mining-Ore Research Institute” (Ukraine) used 3D GeoSEIS Tomography to accurately locate subsurface volumetric distribution (deep:500-700m) of cavities, mine workings, active geodynamic zones, concentration of stresses, ore and oil-gas deposits with much higher resolution (1-2m) than 3D seismic, magneto-telluric, electromagnetic data before drilling. 3D GeoSEIS Tomography is helping mining companies to identify volumetric distribution of cavities, active geodynamic zones and concentration of stresses to prevent Earth surface collapses.
The “4D GeoSEIS Tomography” method developed for multifactor volumetric structural-geodynamic modeling can serve for accurate 3D mapping & 4D monitoring of the oil-gas deposits, low-amplitude tectonic structures (lineaments, fractures, shear zones, folds, faults), active geodynamic zones, landslides, cavities, old underground workings (mined-out areas) and collapse sinks.
* The integrated 3D-4D GeoSEIS Tomography™ is a unique tool for volumetric mapping of structural-geodynamical evolution of local fields of thermo-elastic stresses, fractures, shear zones and faults around underground faults, cavities and old mined out areas that detects, measures and monitors different geophysical and geodynamical phenomena (e.g. 3D fractures/stresses/strains lineaments and shear zones, subsidence, uplift, landslides, seismic faults, etc.) and verifies the stability of individual structures, providing precise measurements of displacements.
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method: www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
Sincerely yours,
Yaroslav Bondarenko,
4D GeoSEIS Entrepreneur,
4D GeoSEIS Tomography Developer
www.linkedin.com/pub/yaroslav-bondarenko/24/171/a38
My Customers & Partners: Institute of Geological Sciences of NAS (National Academy of Sciences of Ukraine), Institute of Geotechnical Mechanics of NAS, Institute of Problems on Nature Management & Ecology of NAS, SE NIGRI (Mining-Ore Research Institute)...
Volumetric 3D GeoSEIS Models of the gravity anomaly field (Bouguer anomaly) of Bobrikovskiy gold deposit prospected area (Nagolny Cryazh, Donbass, Ukraine)
Volumetric 3D GeoSEIS model of distribution of Cu-Pb-Zn-Au mineralization has been predicted on the basis of the most informative characteristics of gravity anomaly field images.
Using 4D GeoSEIS software for multifactor volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modeling we offer:
Multifactor volumetric structural-geodynamic models “4D GeoSEISM” with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 22 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
Integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEISM had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Volumetric 3D-4D GeoSEIS Models of the spectral brightness field of NW Namibia & SW Angola area (Depth: 17 km. Area: 100x220 km) .
The volumetric 3D GeoSEIST model of distribution of Cu-Ti-Fe-Pb-Zn-Au mineralization has been predicted on the basis of the most informative characteristics of multispectral Landsat7ETM + image.
Using 4D GeoSEIS software for multicomponent volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modelling we offer:
* The multicomponent volumetric 4D GeoSEIST models with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 25 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
*The integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEIST Method had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modelling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Volumetric 3D GeoSEIS model of predicted copper and titaniferous magnetite mineralization
based on "2D GeoSEIS neural network processing" of Landsat 7 ETM & ASTER images
(NW surrounding area of the Kunene Intrusive Complex, Namibia).
The volumetric 3D GeoSEIST model of distribution of Cu-Ti-Fe-Pb-Zn-Au mineralization has been predicted on the basis of the most informative characteristics of multispectral Landsat7ETM + image.
Using 4D GeoSEIS software for multicomponent volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modelling we offer:
* The multicomponent volumetric 4D GeoSEIST models with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 25 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
*The integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEIST Method had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modelling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Regional Volumetric 3D GeoSEIS model (Landsat 7 ETM) for predict new copper and titaniferous magnetite mineralization (NW surrounding area of the Kunene Intrusive Complex, Namibia).
Horizontal scale: 1:25000 (1px=30m); Vertical scale: 5 times increased Area: 30х45km; Depth: 500m.
The volumetric 3D GeoSEIST model of distribution of Cu-Ti-Fe-Pb-Zn-Au mineralization has been predicted on the basis of the most informative characteristics of multispectral Landsat7ETM + image.
Using 4D GeoSEIS software for multicomponent volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modelling we offer:
* The multicomponent volumetric 4D GeoSEIST models with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 25 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
*The integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEIST Method had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modelling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Deep horizontal slice (scale 1:5000; depth: 1 km) of 3DGeoSEIS model with the predicted low-amplitude folds of the coal bead “m3”, based on 3D GeoSEIS Tomography & neural network processing of Landsat 7 ETM image flic.kr/p/cq94Fu
Using 4D GeoSEIS software for multifactor volumetric (structural-geodynamic, geophysical, geochemical, and mineralogical) modeling, we offer:
Multifactor volumetric structural-geodynamic models “4D GeoSEISM” with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies, and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
Over the past 22 years, a great number of volumetric structural-geodynamic, geological, and geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) have been created.
Integration of the mineralogical and geochemical data, geophysical maps, and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM, and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop an understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentrations of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEISM had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay, and hydrothermal minerals can be accurately volumetrically mapped...
* The results of structural-geodynamic modeling proved the possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of the mining works plan on a scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of the 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological, and geochemical data into multicomponent volumetric 3D-4D GeoSEIS GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and can potentially improve the probability of exploration success by reducing the time and cost involved in discovery.
The orthoslice of volumetric 3D GeoSEIS Model of the Landsat 7 image's spectral brightness field (Kunene intrusive complex "KIC" & surrounding area of NW Namibia & SW Angola area; Depth: 17 km. Area: 100 x 220 km) .
The volumetric 3D GeoSEIST model of distribution of Cu-Ti-Fe-Pb-Zn-Au mineralization has been predicted on the basis of the most informative characteristics of multispectral Landsat7ETM + image.
Using 4D GeoSEIS software for multicomponent volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modelling we offer:
* The multicomponent volumetric 4D GeoSEIST models with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 25 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
*The integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEISM had been confirmed by field observations.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
3D GeoSEIS volumetric model of oil and gas-bearing formation of Southern Uzbekistan have been created by 3D GeoSEIS processing of geophysical fields.
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Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
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Using 4D GeoSEIS software for multifactorial volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modeling we offer:
* The multifactorial volumetric 4D GeoSEIST models with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 15 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
* The integration of a mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEISM had been confirmed by field observations.
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VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
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WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
The ring tower is a striking high-rise building in a prominent location in Vienna, where is located the headquarters of the Vienna Insurance Group. It was built in 1953-1955 after designs of Erich Boltenstern at Schottenring inside the Viennese Ringstrasse and is located at the stop Schottenring of the Wiener Linien (Vienna Public Transport). The 73 meter (93 meter height including the weather light column) high ring tower was deemed as innovative project for the reconstruction of the city.
The building, which previously stood on this plot, was the only one of the entire Scots ring which was destroyed in the Second World War. The ring tower with its 23 floors and its 20-meter high weather lighthouse is the second highest building inside Vienna's Ringstrasse. Higher is only the Gothic-style St. Stephen's Cathedral. In addition to the central office of the Vienna Insurance Group are now also offices of Wiener Stadtwerke (public utility company) in the ring tower. In the office building a total of 12,000 square meters of effective surface is available. The facade and parts of the ring tower were renovated in 1996.
Name
In a contest, a name was sought for the then very modern office skyscraper. Among 6,502 entries the name "ring tower" was chosen. There were, among other proposals, such as City House, Gutwill-house (goodwill-house), house of reciprocity, high-corner, new tower, Sonnblick-house, insurance high-rise, Vindobona-house or vision-house (farsightedness-house) of the creative population after the war. One of the submitters of the name "ring tower" was rewarded with an honorarium of 2,000 shillings.
Weather lighthouse
Weather lighthouse, seen from the ring road
On the roof there is the 20-meter high weather lighthouse with 117 lights in differently colored light signals the weather for the next day displaying (each 39 white, red and green lights as well as 2 additional air traffic control lights).
This light column is directly connected to the ZAMG (Central Institute for Meteorology and Geodynamics) on the Hohenwarte in Vienna.
Meaning of the signals:
red ascending = temperature rising
red descending = temperature falling
green ascending = weather conditions will be better
green descending = weather will be worse
Flashing red = warning lightning or storms
Flashing white = snow or ice
Ringturm 2013
Ringturm disguising
Since 2006, the ring tower is changed every year into an "art tower " by covering the building with printed webs. The covering consists of 30 printed network paths with about 3 meters wide and 63 or 36 meters in length , and the resulting area is approximately 4,000 square meters.
The previous art projects:
2006 "Don Giovianni" by Christian Ludwig Attersee (on the occasion of the Mozart Year)
2007 "Tower of Life" by Robert Hammerstiel
2008 "Tower in Bloom" by Hubert Schmalix (Blumenstillleben)
2011 "Sense of family" Xenia Hausner
2012 "Society" by Hungarian artist László Fehér
2013 "Connectedness" of the Slovak artist Dorota Sadovská
World-first discovery of 4D GeoSEIS Tomography Method can help save cost for ore deposits prospecting and 4D Risk Modeling/Monitoring !
* We propose your company partnership on integrating AMT, Magnetic, Gravity, IP, Seismic etc. into multicomponent volumetric 3D-4D GeoSEIS Tomography model:
The integrated 3D-4D GeoSEIS Tomography™ Method is a unique tool of transformations & integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry and geophysical data (AMT, Magnetic, Gravity, IP, Seismic etc.) into multifactor volumetric 3D-4D GeoSEIS (3D-4D SpaceTime) Tomography Model for exact ranging and forecasting of ore deposits, multifactor volumetric mapping of low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, cost-effective 4D Geomechanical Modeling/Monitoring: www.flickr.com/photos/jeisus2012/sets/72157626153283579/w...;
The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Outputs:
*Development of data acquisition and interpretation strategies aimed at generating and prioritizing targets for maximum expected value. Such services will most likely be used for targeting ore deposits in areas where the available data is insufficient to generate good 3D- 4D geological interpretations;
*Direct prediction of favorable locations for target ore deposits on volumetric space-time geometries provided by 3D-4D GeoSEIS Tomography model;
*Prediction and prioritization of favorable ore environments in 3D-4D GeoSEIS Tomography models by translation of modeling results - obtained by running a large series of models using simplified geometries for a range of possible ore host scenarios - into 3D GIS;
*Assessment of the relative favorability of terrains for the discovery of certain ore & oil-gas trap types based on the multicomponent volumetric 4D GeoSEIS Tomography modeling of crustal scale magmatic-hydrothermal fluid generation, deformation and fluid flow based on geodynamic scenarios.
* We have used multispectral images of WorldView-2 satellite with 1-2 meter resolution for volumetric 3D GeoSEIS mapping (deep: 500-1500m) with much higher resolution (0,5-2m) than 3D seismic, magneto-telluric, electromagnetic data.
* We have used geophysical data & multispectral images of Landsat 5-7, ASTER, Hyperion satellites with 15-30 meter resolution for predict volcanic/earthquake activity and volumetric mapping of volcano-tectonic structures up to depth 60km: www.flickr.com/photos/jeisus2012/5559736588/in/set-721576....
* Volumetric 3D-4D GeoSEIS models will allow to increase accuracy of tectonic structures mapping on deep horizons to a level of near-surface horizons, that in many times will raise the efficiency and will reduce the operating costs for geological prospecting and explorations.
. * 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
* Mining professionals of State Enterprise "Mining-Ore Research Institute” (Ukraine) used 3D GeoSEIS Tomography to accurately locate subsurface volumetric distribution (deep:500-700m) of cavities, mine workings, active geodynamic zones, concentration of stresses, ore and oil-gas deposits with much higher resolution (1-2m) than 3D seismic, magneto-telluric, electromagnetic data before drilling. 3D GeoSEIS Tomography is helping mining companies to identify volumetric distribution of cavities, active geodynamic zones and concentration of stresses to prevent Earth surface collapses.
The “4D GeoSEIS Tomography” method developed for multifactor volumetric structural-geodynamic modeling can serve for accurate 3D mapping & 4D monitoring of the oil-gas deposits, low-amplitude tectonic structures (lineaments, fractures, shear zones, folds, faults), active geodynamic zones, landslides, cavities, old underground workings (mined-out areas) and collapse sinks.
* The integrated 3D-4D GeoSEIS Tomography™ is a unique tool for volumetric mapping of structural-geodynamical evolution of local fields of thermo-elastic stresses, fractures, shear zones and faults around underground faults, cavities and old mined out areas that detects, measures and monitors different geophysical and geodynamical phenomena (e.g. 3D fractures/stresses/strains lineaments and shear zones, subsidence, uplift, landslides, seismic faults, etc.) and verifies the stability of individual structures, providing precise measurements of displacements.
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method: www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
From analysis of the obtained results, the following conclusions can be drawn: The “4D GeoSEIS Tomography” methods developed for multifactor volumetric structural-geodynamic modeling can serve for accurate mapping of the low-amplitude tectonic structures (lineaments, fractures, shear zones, folds, faults), active geodynamic zones, cavities, old underground workings (mined-out areas) and collapse sinks.
Vertical sections of volumetric “4D GeoSEIS Tomography” models of spectral brightness fields of airborne and satellite images are in good agreement with geological and geophysical sections, leaving behind other methods in detection of the locations of cavities and old underground workings (mined-out areas) at different depths.
The results of Multifactor Volumetric 4D GeoSEIS Tomography Modeling:
Developed “4D GeoSEIS Tomography” method has proved the ability to perform volumetric
mapping of underground areas of collapse and deformation associated with the local thermo-
elastic stress fields around mined-out areas at depths of 0-600m.
Subsurface maxima of spectral brightness fields, which are associated with the environmental
heating and rock breakage (caving) zones above old mine workings and below areas of collapse sinks formation, have been mapped on the orthogonal slices of volumetric 4D GeoSEIS Model.
The anomalies of spectral brightness measured by the airborne thermal imager and the infrared
sensors World View-2, which have been recalculated with regard to depth, have enabled accurate mapping of cavities, old underground workings (mined-out areas) and active geodynamic zones available in geologic environment.
Vertical sections of volumetric 4D GeoSEIS Models of spectral brightness fields of airborne and
satellite images are in good agreement with geological and geophysical sections, leaving
behind other methods in detection of the locations of cavities and old underground workings
(mined-out areas) at different depths.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi... .
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Vertical slice of 3D GeoSEIS Tomography model is created by decoding and 3D GeoSEIS transformation of satellite image (space resolution-1m).
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
Seeking business partners for 3D-4D GeoSEIS Tomography modeling and Monitoring…
Seeking business partners for developing 3D-4D GeoSEIS Tomography transformation of 2D-3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video...
* We are looking for investment partnership for developing 6D GeoSEIS Tomography transformation of 3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video... If you interest it, please don’t miss this opportunity. Please check of the information:
* Uniqueness of 3D-4D GeoSEIS Tomography technology is determined by algorithms that transforms digital images of physical fields into volumetric space-time models which reflects not only an volumetric structure, but also evolution of field`s structures.
* 6D GeoSEIS Tomography brings 3D scan visualization to a whole 6D volumetric animation level. Its 6D Space-time-based Technology extends the capabilities of volumetric modeling practices – allowing anyone, anywhere to see, explore and share (in real-time) 6D interactive views directly from traditional 3D Seismic, MRI, CT and ultrasound scans…
My Customers & Partners: Institute of Geological Sciences of NAS (National Academy of Sciences of Ukraine), Institute of Geotechnical Mechanics of NAS, Institute of Problems on Nature Management & Ecology of NAS, State Enterprise NIGRI (Mining-Ore Research Institute)...
Publications and scientific reports:
www.cosis.net/members/submissions.php, www.cosis.net/members/submissions.php?user=u8c8d2c4436821...
Certificates:
www.flickr.com/photos/jeisus2012/5531682555/in/photostream , www.slideshare.net/JarosloveBondarenko/4-d-geoseis, foto.mail.ru/mail/jeisus/7/64.html# , foto.mail.ru/mail/jeisus/7/62.html# , foto.mail.ru/mail/jeisus/7/65.html#
Shestopalov V.M., Bondarenko Ya.I., Zayonts I.O., Rudenko Yu.F., Bohuslavsky A.S. Complexation of Structural-Geodynamical and Hydrogeological Methods of Studying Areas to Reveal Geological Structural Perspectives for Deep Isolation of Radioactive Wastes. // Field Testing and Associated Modeling of Potential High-Level Nuclear Waste Geologic Disposal Sites // Berkeley, USA, 1998.
Kolotenko V.P. Bondarenko J.J. Spiritual and Moral aspects of Sustainable Development Theory // Man and City. Towards a Human and Sustainable Development // Napoli, Italy, 2000.
Bondarenko J.J., Risk analysis, synthesis and Spiritual Energy-Information Structure Modeling 'SEISM' to reveal environmental perspectives for isolation of radioactive and hazardous chemical wastes // ECO-INFORMA 2001 // Chicago, USA, 2001.
Bondarenko J. J., The Multifactor Predictive SEIS (GIS) Model of ecological, genetic and population health risk in connection with dangerous bio-geodynamical processes in geopathogenic hazard zones //ECO-INFORMA 2001// Chicago, USA, 2001.
Zayonts I.O., Bondarenko J.J., Slipchenko B., Lysychenko G.V., New approaches to the problem of geoecological risk for urbanized territories // ECO-INFORMA 2001 // Chicago, USA, 2001...
Selected by NASA in June 1985, ret. Navy Capt. Michael A. Baker became an astronaut in July 1986 upon completion of a one-year training and evaluation program.
Following the Challenger accident, from January 1986 to December 1987, Baker was assigned as a member of the team that was pursuing redesign, modification and improvements to the Shuttle Landing and Deceleration Systems, including nosewheel steering, brakes, tires, and drag chute, in an effort to provide greater safety margins during landing and rollout. He was then assigned to the Shuttle Avionics Integration Laboratory (SAIL), where he was involved in the checkout and verification of the computer software and hardware interfaces for STS-26R (the return-to-flight mission) and subsequent flights.
A veteran of four space flights, Baker has logged 965 hours in space. He served as pilot on STS-43 (August 2-11, 1991) and STS-52 (October 22 to November 1, 1992), and was the mission commander on STS-68 (September 30 to October 11, 1994) and STS-81 (January 12-22, 1997).
As of January 2008, Baker was assigned as the International Space Station Program Manager for International and Crew Operations and is responsible for the coordination of program operations, integration and flight crew training and support activities with the International Partners.
STS-43/Atlantis launched from the Kennedy Space Center, Florida, on August 2, 1991. During the flight, crew members deployed the fifth Tracking and Data Relay Satellite (TDRS-E), in addition to conducting 32 physical, material, and life science experiments, mostly relating to the Extended Duration Orbiter and Space Station Freedom.
After 142 orbits of the Earth, the 9-day mission concluded with a landing on Runway 15 at the Kennedy Space Center on August 11, 1991. Mission duration was 213 hours, 21 minutes, 25 seconds.
STS-52/Columbia launched from the Kennedy Space Center, Florida, on October 22, 1992. During the mission crew members deployed the Italian Laser Geodynamic Satellite (LAGEOS) that will be used to measure movement of the Earth’s crust, and operated the U.S. Microgravity Payload 1 (USMP-1).
Additionally, the Space Vision System (SVS) developed by the Canadian Space Agency was tested by the Canadian payload specialist and the crew using a small target assembly that was released from the remote manipulator system. The SVS will be used for Space Station construction. These three primary payloads together with numerous other payloads operated by the crew encompassed geophysics, materials science, biological research and applied research for Space Station Freedom.
Following 159 orbits of the Earth, the 10-day mission concluded with a landing on Runway 33 at the Kennedy Space Center on November 1, 1992. Mission duration was 236 hours, 56 minutes, 13 seconds.
STS-68/Endeavour launched from the Kennedy Space Center, Florida, on September 30, 1994. This flight was the second flight of the Space Radar Laboratory (SRL) comprised of a large radar called SIR-C/X-SAR (Shuttle Imaging Radar-C/X-Band Synthetic Aperture Radar) and MAPS (Measurement of Air Pollution from Satellites).
As part of NASA’s Mission to Planet Earth, SRL was an international, multidisciplinary study of global environmental change, both natural and man-made. The primary objective was to radar map the surface of the Earth to help us understand the contributions of ecology, hydrology, geology, and oceanography to changes in our Planet’s environment. Real-time crew observations of environmental conditions, along with over 14,000 photographs, aided in interpretation of the radar images.
This SRL mission was a highly successful test of technology intended for long-term environmental and geological monitoring of planet Earth. Following 183 orbits of the Earth, the eleven-day mission concluded with a landing on Runway 22 at Edwards Air Force Base, California, on October 11, 1994. Mission duration was 269 hours, 46 minutes, 10 seconds.
STS-81/Atlantis launched from the Kennedy Space Center, Florida on January 12, 1997. STS-81 was the fifth in a series of joint missions between the U.S. Space Shuttle and the Russian Space Station Mir and the second one involving an exchange of U.S. astronauts.
In five days of docked operations more than three tons of food, water, experiment equipment and samples were moved back and forth between the two spacecraft. Following 160 orbits of the Earth the STS-81 mission concluded with a landing on Kennedy Space Center’s Runway 33 ending a 3.9 million mile journey. Mission duration was 244 hours, 56 minutes.
3D GeoSEIS Tomography volumetric model of Earth's surface above the ore-bearing formation is created by 3D GeoSEIS Tomography processing of SRTM Date (DEM).
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
Seeking business partners for 3D-4D GeoSEIS Tomography modeling and Monitoring…
Seeking business partners for developing 3D-4D GeoSEIS Tomography transformation of 2D-3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video...
* We are looking for investment partnership for developing 6D GeoSEIS Tomography transformation of 3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video... If you interest it, please don’t miss this opportunity. Please check of the information:
* Uniqueness of 3D-4D GeoSEIS Tomography technology is determined by algorithms that transforms digital images of physical fields into volumetric space-time models which reflects not only an volumetric structure, but also evolution of field`s structures.
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
My Customers & Partners: Institute of Geological Sciences of NAS (National Academy of Sciences of Ukraine), Institute of Geotechnical Mechanics of NAS, Institute of Problems on Nature Management & Ecology of NAS, State Enterprise NIGRI (Mining-Ore Research Institute)...
3D GeoSEIS Tomography map of tectonic lineaments and geodynamical hazard zones is created by 3D decoding of World Wiev 2 image (space resolution: 50см)...
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
Seeking business partners for 3D-4D GeoSEIS Tomography modeling and Monitoring…
Seeking business partners for developing 3D-4D GeoSEIS Tomography transformation of 2D-3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video...
* We are looking for investment partnership for developing 6D GeoSEIS Tomography transformation of 3D digital (multispectral, radar, geophysical, CT, MRI, Ultrasound) images and video... If you interest it, please don’t miss this opportunity. Please check of the information:
* Uniqueness of 3D-4D GeoSEIS Tomography technology is determined by algorithms that transforms digital images of physical fields into volumetric space-time models which reflects not only an volumetric structure, but also evolution of field`s structures.
* 6D GeoSEIS Tomography brings 3D scan visualization to a whole 6D volumetric animation level. Its 6D Space-time-based Technology extends the capabilities of volumetric modeling practices – allowing anyone, anywhere to see, explore and share (in real-time) 6D interactive views directly from traditional 3D Seismic, MRI, CT and ultrasound scans…
My Customers & Partners: Institute of Geological Sciences of NAS (National Academy of Sciences of Ukraine), Institute of Geotechnical Mechanics of NAS, Institute of Problems on Nature Management & Ecology of NAS, State Enterprise NIGRI (Mining-Ore Research Institute)...
Publications and scientific reports:
www.cosis.net/members/submissions.php, www.cosis.net/members/submissions.php?user=u8c8d2c4436821...
Certificates:
www.flickr.com/photos/jeisus2012/5531682555/in/photostream , www.slideshare.net/JarosloveBondarenko/4-d-geoseis, foto.mail.ru/mail/jeisus/7/64.html# , foto.mail.ru/mail/jeisus/7/62.html# , foto.mail.ru/mail/jeisus/7/65.html#
Shestopalov V.M., Bondarenko Ya.I., Zayonts I.O., Rudenko Yu.F., Bohuslavsky A.S. Complexation of Structural-Geodynamical and Hydrogeological Methods of Studying Areas to Reveal Geological Structural Perspectives for Deep Isolation of Radioactive Wastes. // Field Testing and Associated Modeling of Potential High-Level Nuclear Waste Geologic Disposal Sites // Berkeley, USA, 1998.
Kolotenko V.P. Bondarenko J.J. Spiritual and Moral aspects of Sustainable Development Theory // Man and City. Towards a Human and Sustainable Development // Napoli, Italy, 2000.
Bondarenko J.J., Risk analysis, synthesis and Spiritual Energy-Information Structure Modeling 'SEISM' to reveal environmental perspectives for isolation of radioactive and hazardous chemical wastes // ECO-INFORMA 2001 // Chicago, USA, 2001.
Bondarenko J. J., The Multifactor Predictive SEIS (GIS) Model of ecological, genetic and population health risk in connection with dangerous bio-geodynamical processes in geopathogenic hazard zones //ECO-INFORMA 2001// Chicago, USA, 2001.
Zayonts I.O., Bondarenko J.J., Slipchenko B., Lysychenko G.V., New approaches to the problem of geoecological risk for urbanized territories // ECO-INFORMA 2001 // Chicago, USA, 2001...
From analysis of the obtained results, the following conclusions can be drawn: The “4D GeoSEIS Tomography” methods developed for multifactor volumetric structural-geodynamic modeling can serve for accurate mapping of the low-amplitude tectonic structures (lineaments, fractures, shear zones, folds, faults), active geodynamic zones, cavities, old underground workings (mined-out areas) and collapse sinks.
Vertical sections of volumetric “4D GeoSEIS Tomography” models of spectral brightness fields of airborne and satellite images are in good agreement with geological and geophysical sections, leaving behind other methods in detection of the locations of cavities and old underground workings (mined-out areas) at different depths.
Take your geospatial analysis to the next 3D-4D level with 3D-4D GeoSEIS Tomography!
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method (English ver.) www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi... .
*Using 4D GeoSEIS Tomography transformation of various bands of the multispectral imagery of WV-2, the discriminating iron oxides, clay and hydrothermal minerals can be accurately volumetric mapped...
* The results of structural-geodynamic modeling proved possibility of satellite maps creation (Landsat7ETM, ASTER, World View-2…) of low-amplitude tectonics with spatial resolution 1-20-30m/pix for horizontal lines, and 20 cm of fold’s amplitude. The spatial resolution of satellite models and maps on a concrete area exceeded the spatial resolution of mining works plan on the scale 1:5000.
* 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
World-first discovery of 4D GeoSEIS Tomography Method can help save cost for ore deposits prospecting
and 4D Risk Modeling/Monitoring !
* We propose your company partnership on integrating AMT, Magnetic, Gravity, IP, Seismic etc. into multicomponent volumetric 3D-4D GeoSEIS Tomography model:
The integrated 3D-4D GeoSEIS Tomography™ Method is a unique tool of transformations & integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry and geophysical data (AMT, Magnetic, Gravity, IP, Seismic etc.) into multifactor volumetric 3D-4D GeoSEIS (3D-4D SpaceTime) Tomography Model for exact ranging and forecasting of ore deposits, multifactor volumetric mapping of low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, cost-effective 4D Geomechanical Modeling/Monitoring: www.flickr.com/photos/jeisus2012/sets/72157626153283579/w...;
The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Outputs:
*Development of data acquisition and interpretation strategies aimed at generating and prioritizing targets for maximum expected value. Such services will most likely be used for targeting ore deposits in areas where the available data is insufficient to generate good 3D- 4D geological interpretations;
*Direct prediction of favorable locations for target ore deposits on volumetric space-time geometries provided by 3D-4D GeoSEIS Tomography model;
*Prediction and prioritization of favorable ore environments in 3D-4D GeoSEIS Tomography models by translation of modeling results - obtained by running a large series of models using simplified geometries for a range of possible ore host scenarios - into 3D GIS;
*Assessment of the relative favorability of terrains for the discovery of certain ore & oil-gas trap types based on the multicomponent volumetric 4D GeoSEIS Tomography modeling of crustal scale magmatic-hydrothermal fluid generation, deformation and fluid flow based on geodynamic scenarios.
* We have used multispectral images of WorldView-2 satellite with 1-2 meter resolution for volumetric 3D GeoSEIS mapping (deep: 500-1500m) with much higher resolution (0,5-2m) than 3D seismic, magneto-telluric, electromagnetic data.
* We have used geophysical data & multispectral images of Landsat 5-7, ASTER, Hyperion satellites with 15-30 meter resolution for predict volcanic/earthquake activity and volumetric mapping of volcano-tectonic structures up to depth 60km: www.flickr.com/photos/jeisus2012/5559736588/in/set-721576....
* Volumetric 3D-4D GeoSEIS models will allow to increase accuracy of tectonic structures mapping on deep horizons to a level of near-surface horizons, that in many times will raise the efficiency and will reduce the operating costs for geological prospecting and explorations.
. * 3D GeoSEIS Tomography is invaluable for identifying geodynamic zones that may be potential areas for rock bursts, 3D fracture patterns, their density (number of cracks per unit volume) and outline zones of high permeability, shear zones and faults...
* Mining professionals of State Enterprise "Mining-Ore Research Institute” (Ukraine) used 3D GeoSEIS Tomography to accurately locate subsurface volumetric distribution (deep:500-700m) of cavities, mine workings, active geodynamic zones, concentration of stresses, ore and oil-gas deposits with much higher resolution (1-2m) than 3D seismic, magneto-telluric, electromagnetic data before drilling. 3D GeoSEIS Tomography is helping mining companies to identify volumetric distribution of cavities, active geodynamic zones and concentration of stresses to prevent Earth surface collapses.
The “4D GeoSEIS Tomography” method developed for multifactor volumetric structural-geodynamic modeling can serve for accurate 3D mapping & 4D monitoring of the oil-gas deposits, low-amplitude tectonic structures (lineaments, fractures, shear zones, folds, faults), active geodynamic zones, landslides, cavities, old underground workings (mined-out areas) and collapse sinks.
* The integrated 3D-4D GeoSEIS Tomography™ is a unique tool for volumetric mapping of structural-geodynamical evolution of local fields of thermo-elastic stresses, fractures, shear zones and faults around underground faults, cavities and old mined out areas that detects, measures and monitors different geophysical and geodynamical phenomena (e.g. 3D fractures/stresses/strains lineaments and shear zones, subsidence, uplift, landslides, seismic faults, etc.) and verifies the stability of individual structures, providing precise measurements of displacements.
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method: www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
Sincerely yours,
Yaroslav Bondarenko,
4D GeoSEIS Entrepreneur,
4D GeoSEIS Tomography Developer
www.linkedin.com/pub/yaroslav-bondarenko/24/171/a38
My Customers & Partners: Institute of Geological Sciences of NAS (National Academy of Sciences of Ukraine), Institute of Geotechnical Mechanics of NAS, Institute of Problems on Nature Management & Ecology of NAS, SE NIGRI (Mining-Ore Research Institute)...
World-first discovery of 4D GeoSEIS Tomography Method can help save cost for ore deposits prospecting and 4D Risk Modeling/Monitoring !
* We propose your company partnership on integrating AMT, Magnetic, Gravity, IP, Seismic etc. into multicomponent volumetric 3D-4D GeoSEIS Tomography model:
The integrated 3D-4D GeoSEIS Tomography™ Method is a unique tool of transformations & integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry and geophysical data (AMT, Magnetic, Gravity, IP, Seismic etc.) into multifactor volumetric 3D-4D GeoSEIS (3D-4D SpaceTime) Tomography Model for exact ranging and forecasting of ore deposits, multifactor volumetric mapping of low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, cost-effective 4D Geomechanical Modeling/Monitoring: www.flickr.com/photos/jeisus2012/sets/72157626153283579/w...;
The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Outputs:
*Development of data acquisition and interpretation strategies aimed at generating and prioritizing targets for maximum expected value. Such services will most likely be used for targeting ore deposits in areas where the available data is insufficient to generate good 3D- 4D geological interpretations;
*Direct prediction of favorable locations for target ore deposits on volumetric space-time geometries provided by 3D-4D GeoSEIS Tomography model;
*Prediction and prioritization of favorable ore environments in 3D-4D GeoSEIS Tomography models by translation of modeling results - obtained by running a large series of models using simplified geometries for a range of possible ore host scenarios - into 3D GIS;
*Assessment of the relative favorability of terrains for the discovery of certain ore & oil-gas trap types based on the multicomponent volumetric 4D GeoSEIS Tomography modeling of crustal scale magmatic-hydrothermal fluid generation, deformation and fluid flow based on geodynamic scenarios.
* We have used multispectral images of WorldView-2 satellite with 1-2 meter resolution for volumetric 3D GeoSEIS mapping (deep: 500-1500m) with much higher resolution (0,5-2m) than 3D seismic, magneto-telluric, electromagnetic data.
* We have used geophysical data & multispectral images of Landsat 5-7, ASTER, Hyperion satellites with 15-30 meter resolution for predict volcanic/earthquake activity and volumetric mapping of volcano-tectonic structures up to depth 60km: www.flickr.com/photos/jeisus2012/5559736588/in/set-721576....
* Volumetric 3D-4D GeoSEIS models will allow to increase accuracy of tectonic structures mapping on deep horizons to a level of near-surface horizons, that in many times will raise the efficiency and will reduce the operating costs for geological prospecting and explorations.
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method: www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
World-first discovery of 4D GeoSEIS Tomography Method can help save cost for ore deposits prospecting and 4D Risk Modeling/Monitoring !
* We propose your company partnership on integrating AMT, Magnetic, Gravity, IP, Seismic etc. into multicomponent volumetric 3D-4D GeoSEIS Tomography model:
The integrated 3D-4D GeoSEIS Tomography™ Method is a unique tool of transformations & integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry and geophysical data (AMT, Magnetic, Gravity, IP, Seismic etc.) into multifactor volumetric 3D-4D GeoSEIS (3D-4D SpaceTime) Tomography Model for exact ranging and forecasting of ore deposits, multifactor volumetric mapping of low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, cost-effective 4D Geomechanical Modeling/Monitoring: www.flickr.com/photos/jeisus2012/sets/72157626153283579/w...;
The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
Outputs:
*Development of data acquisition and interpretation strategies aimed at generating and prioritizing targets for maximum expected value. Such services will most likely be used for targeting ore deposits in areas where the available data is insufficient to generate good 3D- 4D geological interpretations;
*Direct prediction of favorable locations for target ore deposits on volumetric space-time geometries provided by 3D-4D GeoSEIS Tomography model;
*Prediction and prioritization of favorable ore environments in 3D-4D GeoSEIS Tomography models by translation of modeling results - obtained by running a large series of models using simplified geometries for a range of possible ore host scenarios - into 3D GIS;
*Assessment of the relative favorability of terrains for the discovery of certain ore & oil-gas trap types based on the multicomponent volumetric 4D GeoSEIS Tomography modeling of crustal scale magmatic-hydrothermal fluid generation, deformation and fluid flow based on geodynamic scenarios.
* We have used multispectral images of WorldView-2 satellite with 1-2 meter resolution for volumetric 3D GeoSEIS mapping (deep: 500-1500m) with much higher resolution (0,5-2m) than 3D seismic, magneto-telluric, electromagnetic data.
* We have used geophysical data & multispectral images of Landsat 5-7, ASTER, Hyperion satellites with 15-30 meter resolution for predict volcanic/earthquake activity and volumetric mapping of volcano-tectonic structures up to depth 60km: www.flickr.com/photos/jeisus2012/5559736588/in/set-721576....
* Volumetric 3D-4D GeoSEIS models will allow to increase accuracy of tectonic structures mapping on deep horizons to a level of near-surface horizons, that in many times will raise the efficiency and will reduce the operating costs for geological prospecting and explorations.
VALIDATION CERTIFICATE for “4D GeoSEIS Tomography” Method: www.slideshare.net/JarosloveBondarenko/4-d-geoseissertifi....
Madeira Diferente -
From a geodynamic point of view, the archipelago is located in the northwest sector of the African plate (Nubian plate), about 500 km south from the Azores-Gibraltar fault zone, 1600 km east from the Mid-Atlantic Ridge and 640 km to the west from the African continental margin.
Madeira Island represents the emerged part of a huge volcanic shield, of Miocenic to Holocenic age (7 Ma), built over a Cretaceous oceanic crust. Its building is the result of submarine volcanic activity, and, later, by the stacking of subaerial eruptions generated mostly by fissural activity along a principal axis of approximate direction E-W.
Picture was taken from the west looking east.
Mirador Observatory lies within the town of Baguio close to the western boundary of the city, and comprises an isolated hill, “Mirado” (Mount Lookout)
Illustrations from the book:
Mirador Observatory, Baguio, Benguet
A new meteorological-geodynamic station of the Weather Bureau
By Rev. Jose Algue, S.J. director to the Weather Bureau.
Published 1909 by Bureau of Printing in Manila.
openlibrary.org/books/OL7077917M/Mirador_observatory_Bagu...
* Volumetric 3D-4D GeoSEIS models will allow to increase accuracy of tectonic structures mapping on deep horizons to a level of near-surface horizons, that in many times will raise the efficiency and will reduce the operating costs for geological prospecting and explorations.
* The volumetric 3D GeoSEIS models of low-amplitude geodynamic zones, tectonic structures and geophysical fields shows that the well-explored areas of hydrocarbon occurrences and deposit are locate on the most favorable trap structures that are fixed on 3D GeoSEIS model of multicomponent stress field.
* Vertical sections of volumetric “4D GeoSEIS Tomography” (4D Space-Time) Models of spectral brightness fields of airborne and satellite images are in good agreement with geological
and geophysical section obtained with AMT and RAP profiling, the results of drilling and geo-surveying details of old underground mining at the test site area:
1) Locations of all AMT (Audio-Magneto-Telluric) anomalies of maximal resistivity at 100m-150m depths coincide with the local anomalies of maximum spectral brightness (VNIR/ch.8/WV-2)
of highly porous zones (oil-gas trap). The latter offer more accurate reflection of the morphology of the echelon fracture zones associated with horizontal left-hand shear zone;
2) Patterns of resistivity and the local anomalies of maximum spectral brightness (VNIR & TIR) are direct hidrocarbon indicators: the presence of hydrocarbons in highly porous rocks
is also associated with characteristic resistivity patterns revealed by MT - so-called "Direct Hydrocarbon Indicators" - as demonstrated by the international Project Paleorift in Uzbekistan.
* The intervals and locations of the points, where drilling tools sink down, are notable for anomalies of maximum spectral brightness. The locations and intervals between places
of drilling fluid loss coincide with aquifer zones, which are registered due to anomalies
of minimum spectral brightness.
WHY WAIT FOR YOUR 90% DISCOUNT of 3D-4D GeoSEIS Tomography Modelling & Monitoring?
* The approbation of 3D-4D GeoSEIS Tomography method on any area, as my research at Iron Ore Open Pit №1 of PAO“CGOK” (Krivoy Rog, Ukraine) will be cost only $5000...
* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
La Mussara, Tarragona (Spain).
EnFoCa: 2ª KDD - "Los Castillejos" i La Mussara [22/03/2009].
ENGLISH
Geodesy, also called geodetics, a branch of earth sciences, is the scientific discipline that deals with the measurement and representation of the Earth, including its gravitational field, in a three-dimensional time-varying space. Geodesists also study geodynamical phenomena such as crustal motion, tides, and polar motion. For this they design global and national control networks, using space and terrestrial techniques while relying on datums and coordinate systems.
Geodesy (from Greek γεωδαισία - geodaisia, lit. "division of the Earth") is primarily concerned with positioning within the temporally varying gravity field. Somewhat obsolete nowadays, geodesy in the German speaking world is divided into "Higher Geodesy" ("Erdmessung" or "höhere Geodäsie"), which is concerned with measuring the Earth on the global scale, and "Practical Geodesy" or "Engineering Geodesy" ("Ingenieurgeodäsie"), which is concerned with measuring specific parts or regions of the Earth, and which includes surveying.
The shape of the Earth is to a large extent the result of its rotation, which causes its equatorial bulge, and the competition of geological processes such as the collision of plates and of vulcanism, resisted by the Earth's gravity field. This applies to the solid surface, the liquid surface (dynamic sea surface topography) and the Earth's atmosphere. For this reason, the study of the Earth's gravity field is called physical geodesy by some.
More info: en.wikipedia.org/wiki/Geodesy
---------------------------------
CASTELLANO
El término Geodesia, del griego γη ("tierra") y δαιζω ("divisiones" o "yo divido") fue usado inicialmente por Aristóteles (384-322 a. C.) y puede significar, tanto "divisiones geográficas de la tierra", como también el acto de "dividir la tierra", por ejemplo, entre propietarios.
La Geodesia es, al mismo tiempo, una rama de las Geociencias y una Ingeniería. Trata del levantamiento y de la representación de la forma y de la superficie de la Tierra, global y parcial, con sus formas naturales y artificiales.
La Geodesia también es usada en matemáticas para la medición y el cálculo sobre superficies curvas. Se usan métodos semejantes a aquellos usados en la superficie curva de la Tierra.
La Geodesia suministra, con sus teorías y sus resultados de mediciones y cálculos, la referencia geométrica para las demás geociencias como también para la geomática, los Sistemas de Información Geográfica, el catastro, la planificación, la ingeniería, la construcción, el urbanismo, la navegación aérea, marítima y terrestre, entre otros e, inclusive, para aplicaciones militares y programas espaciales.
La geodesia superior o geodesia teórica, dividida entre la geodesia física y la geodesia matemática, trata de determinar y representar la figura de la Tierra en términos globales; la Geodesia Inferior, también llamada geodesia práctica o topografía, levanta y representa partes menores de la Tierra donde la superficie puede ser considerada plana. Para este fin, podemos considerar algunas ciencias auxiliares, como es el caso de la cartografía, de la fotogrametría, del cálculo de compensación y de la Teoría de Errores de observación, cada una con diversas sub-áreas.
Además de las disciplinas de la Geodesia científica, existen una serie de disciplinas técnicas que tratan problemas de la organización, administración pública o aplicación de mediciones geodésicas, p.e. la Cartografía sistemática, el Catastro inmobiliario, el Saneamiento rural, las Mediciones de Ingeniería y el geoprocesamiento.
Más info: es.wikipedia.org/wiki/Geodesia
Horizontal slice (depth 600-900м) of 3D GeoSEIS volumetric model of geodynamical zones at oil-gas bearing areas (NW Ukraine) is created by 3D GeoSEIS Tomography processing decoding and transformation of satelite image, geophysical fields and geological maps. the colored symbols show commercial hydrocarbon deposit and occurrences.
Using 4D GeoSEIS software for multifactor volumetric (structural-geodynamic, geophysical, geochemical and mineralogical) modeling we offer:
Multifactor volumetric structural-geodynamic models “4D GeoSEISM” with exact ranging and forecasting of mineral deposits, low-amplitude tectonics, geophysical anomalies and geologic properties of deep structures, using volumetric interpretation methods of multispectral satellite images for cost-effective geological prospecting.
During 15 years the great number of volumetric structural-geodynamic, geological, geophysical models of ore deposits (Fe-Ti, Cu, Au, Hg, Ni-Cu-Co) and oil-gas deposits (Namibia, Kalimantan, Urals, Ukraine, Timor, Uzbekistan) are created.
Integration of the mineralogical and geochemical data, geophysical maps and multispectral satellite images (Hyperion, ASTER, LANDSAT-7ETM and others) in multifactor volumetric structural-geodynamic models.
4D GeoSEIS software for computer processing of the ASTER and Landsat7ETM images have been used to create the volumetric structural-geodynamic models of the NW Namibia & SE Angola territory to discriminate the high potential concentration of mineral resources based on limited field data in order to aid exploration for new copper and titaniferous magnetite mineralization. The strategy adopted to facilitate this predictive modeling is to develop understanding and testing of a “4D GeoSEIS Model” through research. They allowed calculating the potential resources of commercially important concentration of copper and titaniferous magnetite ores. Several points of Fe-Ti-Cu mineralization predicted by the 4D GeoSEISM had been confirmed by field observations.
ЕКОЛОГІЯ І ПРИРОДОКОРИСТУВАННЯ, 2003, Випуск 5
ЧАСТИНА 5. МОНІТОРИНГ ДОВКІЛЛЯ ТА ТЕХНОГЕННА БЕЗПЕКА
GROUNDS FOR RADIOACTIVE WASTES ISOLATION IN CRYSTALLINE ROCKS WITHIN THE CHERNOBYL EXCLUSION ZONE
Shestopalov V.M1, Rudenko Yu.F. 1, Shymkiv L.M.2, Gritsenko M.M.3, Belevtsev R.Ya.4, Zaionts I.O.5, Bondarenko Ya.I.5, Yakovlev E.O.6, Stetsenko B.D.1, Bohuslavskiy O.S.1
1. Scientific-engineering centre of radio-hydro-ecological range of researches NAS of Ukraine 2. Northern State regional geological enterprise «Pivnschgeologiya»
3.Central expedition of not ore raw material «Nerudgeologiya»
4.Institute of geochemistry of an environment NAS of Ukraine
5. OOO «Geotekhnologiya»
6. Ukrainian institute of researches of an environment and resources RNBOU,
Kiev, Ukraine
Paper considers the possibility of high-level and long-lived wastes isolation in crystalline rocks within the Chernobyl exclusion zone. The methodology is based on multicomponent geological modeling, geophysical modeling, Hydrogeological modeling, petrophysical modeling, 3D-4Dseist multicomponent geodynamical modeling and model studies.
В статье рассматривается возможность захоронения высокоактивных и долгоживущих отходов в кристаллических породах Чернобыльской зоны отчуждения. В основе методологии лежат комплексные геологические, геофизические, гидрогеологические, петрофизические, геодинамические, дистанционные и модельные исследования в системе регион – район – участок - площадка.
The ring tower is a striking high-rise building in a prominent location in Vienna, where is located the headquarters of the Vienna Insurance Group. It was built in 1953-1955 after designs of Erich Boltenstern at Schottenring inside the Viennese Ringstrasse and is located at the stop Schottenring of the Wiener Linien (Vienna Public Transport). The 73 meter (93 meter height including the weather light column) high ring tower was deemed as innovative project for the reconstruction of the city.
The building, which previously stood on this plot, was the only one of the entire Scots ring which was destroyed in the Second World War. The ring tower with its 23 floors and its 20-meter high weather lighthouse is the second highest building inside Vienna's Ringstrasse. Higher is only the Gothic-style St. Stephen's Cathedral. In addition to the central office of the Vienna Insurance Group are now also offices of Wiener Stadtwerke (public utility company) in the ring tower. In the office building a total of 12,000 square meters of effective surface is available. The facade and parts of the ring tower were renovated in 1996.
Name
In a contest, a name was sought for the then very modern office skyscraper. Among 6,502 entries the name "ring tower" was chosen. There were, among other proposals, such as City House, Gutwill-house (goodwill-house), house of reciprocity, high-corner, new tower, Sonnblick-house, insurance high-rise, Vindobona-house or vision-house (farsightedness-house) of the creative population after the war. One of the submitters of the name "ring tower" was rewarded with an honorarium of 2,000 shillings.
Weather lighthouse
Weather lighthouse, seen from the ring road
On the roof there is the 20-meter high weather lighthouse with 117 lights in differently colored light signals the weather for the next day displaying (each 39 white, red and green lights as well as 2 additional air traffic control lights).
This light column is directly connected to the ZAMG (Central Institute for Meteorology and Geodynamics) on the Hohenwarte in Vienna.
Meaning of the signals:
red ascending = temperature rising
red descending = temperature falling
green ascending = weather conditions will be better
green descending = weather will be worse
Flashing red = warning lightning or storms
Flashing white = snow or ice
Ringturm 2013
Ringturm disguising
Since 2006, the ring tower is changed every year into an "art tower " by covering the building with printed webs. The covering consists of 30 printed network paths with about 3 meters wide and 63 or 36 meters in length , and the resulting area is approximately 4,000 square meters.
The previous art projects:
2006 "Don Giovianni" by Christian Ludwig Attersee (on the occasion of the Mozart Year)
2007 "Tower of Life" by Robert Hammerstiel
2008 "Tower in Bloom" by Hubert Schmalix (Blumenstillleben)
2011 "Sense of family" Xenia Hausner
2012 "Society" by Hungarian artist László Fehér
2013 "Connectedness" of the Slovak artist Dorota Sadovská
Voronezh State University (Russian: Воро́нежский госуда́рственный университе́т, ВГУ; VSU) is one of the main universities in Central Russia, located in the city of Voronezh. The university was established in 1918 by professors evacuated from the University of Tartu in Estonia. The university has 18 faculties and an enrollment of 22,000 students from Russia, Europe, Africa, the Americas and Asia. Besides, the university has 6 research institutes and 16 research laboratories administered by the Russian Academy of Science. The university is composed of 10 buildings and 7 resident halls situated throughout the city. For over 90 years the University has trained more than 100,000 professionals.
Sanctions
Dmitry Yendovitsky (Ендовицкий Дмитрий Александрович), the rector of the Voronezh State University has signed a letter of support for the Russian invasion of Ukraine.
History
In 1802 following a decree of Russian Emperor Alexander I the University of Tartu in Estonia was re-established. As a result of the German occupation of Estonia during World War I in March 1918, Russian students and professors had to leave the Estonian territory for their own safety. It was decided that a new university would be established in central Russia. In July and September 1918 from Dorpat (now Tartu), 39 professors, 45 lecturers, 43 staff and about 800 students arrived in Voronezh. The first rector of the university was Basil E. Regel.
On 12 November 1918 four faculties started working, namely the faculty of Medicine, the faculty of Physics and Mathematics, the faculty of History and Philology and the Law faculty. In the beginning of 1919, the University had an enrollment of 10,000 students. Anyone could study there, only 4 years later in 1923 that entrance exams were introduced. In 1920, after the Treaty of Tartu, the properties of the University of Tartu (libraries, archives, manuals, documents and other objects) were returned to Estonia. However, most of the teachers who have left due to the onset of the army of Imperial Germany and the occupation of Estonia, did not return to Estonia.
In the early 1920s, Voronezh Institute of Education was added to the university, which marked the beginning of pedagogical faculties, departments that prepares teachers of mathematics, physics, chemistry, natural science, Russian language and literature, social and economic disciplines for schools. In 1930, the Medical Faculty was transformed into an independent institute. During World War II the university was relocated in Yelabuga in the Republic of Tatarstan for a period of two years from 1941 to 1943.
Faculties
Applied Mathematics, Informatics and Mechanics
Mathematics
Computer Sciences
Physics
Chemistry
Pharmaceutics
Medicine and Biology
Economics
Geography, Geoecology & Tourism
Geology
History
Institute of International Education
International Relations
Journalism
Law
Philology
Philosophy and Psychology
Romance and Germanic Philology
Military education
Buildings and infrastructures
Voronezh State University has 10 academic buildings and 7 residence halls located primarily in the city centre.
Fundamental research
research centres
Wave Processes in Inhomogeneous and Non-Linear Media ( Director: Prof. Aleksandr S. Sidorkin www.rec.vsu.ru/eng/)
Innovative Technologies (Director: Prof. Boris A. Zon )
Spacecraft and Rocket Engineering (Co-Director: Prof. Sergey A. Zapryagayev )
Radio Engineering and Electronics (Co-Director: Prof. Ivan I. Borisov )
Scientific and technological cooperation with the EU ( Director: Prof. Igor N. Zornikov )
Shared use of research equipment ( Director: Dr. Mikhail V. Lesovoy )
Technology Transfer ( Director: Dr. Igor V. Aristov )
Geography, Land use and Geo-ecology( Co-Director: Prof. Vladimir I. Fedotov )
Geology ( Co-Director: Prof. Sergey A. Zapryagayev )
Human ecology ( Co-Director: Prof. Semyon A. Kurolap )
Biology ("Venevitino")
Chemical Physics ( Co-Director: Prof. Ivan I. Borisov )
research laboratories
Wave Processes (Co-Director: Prof. Boris A. Zon www.vsu.ru/english/depts/research/labs/waveproc.html )
X-ray Crystallography (Co-Director: Dr. Kseniya B. Aleynikova )
Electron Spectroscopy for Solid-State Physics (Academic Director: Prof. Evelina P.Domashevskaya Administrative Director: Dr. S.V. Ryabtsev www.vsu.ru/english/depts/research/labs/spectroscopy.html)
Mathematical Simulation of Complex Nonlinear Processes and Structures (Co-Director: Prof. V.V. Obukhovskiy www.vsu.ru/english/depts/research/labs/mathsim.html)
Theoretical Physics (Director: Kopitin I.V. )
Biodiversity and Ecosystems Monitoring
Conjugated Processes in Electrochemistry and Corrosion
Economics and Management
Ellipsometric Materials Research
Geodynamics and Seismic Monitoring Academic
Geology and Minerals
History of Archaeological Research and Records in Eurasia
Institute of Geology, Mineralogy and Geo-Chemistry of Russian Academy of Sciences, Voronezh Branch ( Director: Prof. Nikolay M. Chernyshov )
Ion Exchange and Chromatography
Photostimulated Processes in Crystals (Co-Director: Prof. Anatoly N. Latyshev )
Physics and Chemistry of Nanoscale Structured Systems ( Co-Director: Prof. Irina Ya. Mittova )
Systematics and Ecology of Insects ( Co-Director: Prof. Oleg P. Negrobov )
research institutes
Chemistry and Pharmacy
Geology
Mathematics (Director: Prof. Victor G. Zvyagin)
Physics
Social Sciences
Alumni
Svitlana Bilyayeva, archaeologist
Anna Bogomazova, Russian kickboxer, professional wrestler and valet
Pavel Cherenkov, a Nobel Prize in Physics winner
Bridget Kendall, a British journalist
Mark Krasnosel'skii, Soviet mathematician
Sally Laird, British writer, editor and translator
Lev Pavlovich Rapoport Soviet (Russian) theoretician physicist
Ali Mohamed Shein, 7th President of Zanzibar
Voronezh is a city and the administrative centre of Voronezh Oblast in southwestern Russia straddling the Voronezh River, located 12 kilometers (7.5 mi) from where it flows into the Don River. The city sits on the Southeastern Railway, which connects western Russia with the Urals and Siberia, the Caucasus and Ukraine, and the M4 highway (Moscow–Voronezh–Rostov-on-Don–Novorossiysk). In recent years the city has experienced rapid population growth, rising in 2021 to 1,057,681, up from 889,680 recorded in the 2010 Census, making it the 14th-most populous city in the country.
History
The first chronicle references to the word "Voronezh" are dated 1177, when the Ryazan prince Yaropolk, having lost the battle, fled "to Voronozh" and there was moving "from town to town". Modern data of archeology and history interpret Voronezh as a geographical region, which included the Voronezh river (tributary of the Don) and a number of settlements. In the lower reaches of the river, a unique Slavic town-planning complex of the 8th – early 11th century was discovered, which covered the territory of the present city of Voronezh and its environs (about 42 km long, about 13 forts and many unfortified villages). By the 12th – 13th centuries, most of the old towns were desolate, but new settlements appeared upstream, closer to Ryazan.
For many years, the hypothesis of the Soviet historian Vladimir Zagorovsky dominated: he produced the toponym "Voronezh" from the hypothetical Slavic personal name Voroneg. This man allegedly gave the name of a small town in the Chernigov Principality (now the village of Voronezh in Ukraine). Later, in the 11th or 12th century, the settlers were able to "transfer" this name to the Don region, where they named the second city Voronezh, and the river got its name from the city. However, now many researchers criticize the hypothesis, since in reality neither the name of Voroneg nor the second city was revealed, and usually the names of Russian cities repeated the names of the rivers, but not vice versa.
The linguistic comparative analysis of the name "Voronezh" was carried out by the Khovansky Foundation in 2009. There is an indication of the place names of many countries in Eurasia, which may partly be not only similar in sound, but also united by common Indo-European languages: Varanasi, Varna, Verona, Brno, etc.
A comprehensive scientific analysis was conducted in 2015–2016 by the historian Pavel Popov. His conclusion: "Voronezh" is a probable Slavic macrotoponym associated with outstanding signs of nature, has a root voron- (from the proto-Slavic vorn) in the meaning of "black, dark" and the suffix -ezh (-azh, -ozh). It was not “transferred” and in the 8th - 9th centuries it marked a vast territory covered with black forests (oak forests) - from the mouth of the Voronezh river to the Voronozhsky annalistic forests in the middle and upper reaches of the river, and in the west to the Don (many forests were cut down). The historian believes that the main "city" of the early town-planning complex could repeat the name of the region – Voronezh. Now the hillfort is located in the administrative part of the modern city, in the Voronezh upland oak forest. This is one of Europe's largest ancient Slavic hillforts, the area of which – more than 9 hectares – 13 times the area of the main settlement in Kyiv before the baptism of Rus.
In it is assumed that the word "Voronezh" means bluing - a technique to increase the corrosion resistance of iron products. This explanation fits well with the proximity to the ancient city of Voronezh of a large iron deposit and the city of Stary Oskol.
Folk etymology claims the name comes from combining the Russian words for raven (ворон) and hedgehog (еж) into Воронеж. According to this explanation two Slavic tribes named after the animals used this combination to name the river which later in turn provided the name for a settlement. There is not believed to be any scientific support for this explanation.
In the 16th century, the Middle Don basin, including the Voronezh river, was gradually conquered by Muscovy from the Nogai Horde (a successor state of the Golden Horde), and the current city of Voronezh was established in 1585 by Feodor I as a fort protecting the Muravsky Trail trade route against the slave raids of the Nogai and Crimean Tatars. The city was named after the river.
17th to 19th centuries
In the 17th century, Voronezh gradually evolved into a sizable town. Weronecz is shown on the Worona river in Resania in Joan Blaeu's map of 1645. Peter the Great built a dockyard in Voronezh where the Azov Flotilla was constructed for the Azov campaigns in 1695 and 1696. This fleet, the first ever built in Russia, included the first Russian ship of the line, Goto Predestinatsia. The Orthodox diocese of Voronezh was instituted in 1682 and its first bishop, Mitrofan of Voronezh, was later proclaimed the town's patron saint.
Owing to the Voronezh Admiralty Wharf, for a short time, Voronezh became the largest city of South Russia and the economic center of a large and fertile region. In 1711, it was made the seat of the Azov Governorate, which eventually morphed into the Voronezh Governorate.
In the 19th century, Voronezh was a center of the Central Black Earth Region. Manufacturing industry (mills, tallow-melting, butter-making, soap, leather, and other works) as well as bread, cattle, suet, and the hair trade developed in the town. A railway connected Voronezh with Moscow in 1868 and Rostov-on-Don in 1871.
20th century
World War II
During World War II, Voronezh was the scene of fierce fighting between Soviet and combined Axis troops. The Germans used it as a staging area for their attack on Stalingrad, and made it a key crossing point on the Don River. In June 1941, two BM-13 (Fighting machine #13 Katyusha) artillery installations were built at the Voronezh excavator factory. In July, the construction of Katyushas was rationalized so that their manufacture became easier and the time of volley repetition was shortened from five minutes to fifteen seconds. More than 300 BM-13 units manufactured in Voronezh were used in a counterattack near Moscow in December 1941. In October 22, 1941, the advance of the German troops prompted the establishment of a defense committee in the city. On November 7, 1941, there was a troop parade, devoted to the anniversary of the October Revolution. Only three such parades were organized that year: in Moscow, Kuybyshev, and Voronezh. In late June 1942, the city was attacked by German and Hungarian forces. In response, Soviet forces formed the Voronezh Front. By July 6, the German army occupied the western river-bank suburbs before being subjected to a fierce Soviet counter-attack. By July 24 the frontline had stabilised along the Voronezh River as the German forces continued southeast into the Great Bend of the Don. The attack on Voronezh represented the first phase of the German Army's 1942 campaign in the Soviet Union, codenamed Case Blue.
Until January 25, 1943, parts of the Second German Army and the Second Hungarian Army occupied the western part of Voronezh. During Operation Little Saturn, the Ostrogozhsk–Rossosh Offensive, and the Voronezhsko-Kastornenskoy Offensive, the Voronezh Front exacted heavy casualties on Axis forces. On January 25, 1943, Voronezh was liberated after ten days of combat. During the war the city was almost completely ruined, with 92% of all buildings destroyed.
Post-war
By 1950, Voronezh had been rebuilt. Most buildings and historical monuments were repaired. It was also the location of a prestigious Suvorov Military School, a boarding school for young boys who were considered to be prospective military officers, many of whom had been orphaned by war.
In 1950–1960, new factories were established: a tire factory, a machine-tool factory, a factory of heavy mechanical pressing, and others. In 1968, Serial production of the Tupolev Tu-144 supersonic plane was established at the Voronezh Aviation factory. In October 1977, the first Soviet domestic wide-body plane, Ilyushin Il-86, was built there.
In 1989, TASS published details of an alleged UFO landing in the city's park and purported encounters with extraterrestrial beings reported by a number of children. A Russian scientist that was cited in initial TASS reports later told the Associated Press that he was misquoted, cautioning, "Don't believe all you hear from TASS," and "We never gave them part of what they published", and a TASS correspondent admitted the possibility that some "make-believe" had been added to the TASS story, saying, "I think there is a certain portion of truth, but it is not excluded that there is also fantasizing".
21st century
From 10 to 17 September 2011, Voronezh celebrated its 425th anniversary. The anniversary of the city was given the status of a federal scale celebration that helped attract large investments from the federal and regional budgets for development.
On December 17, 2012, Voronezh became the fifteenth city in Russia with a population of over one million people.
Today Voronezh is the economic, industrial, cultural, and scientific center of the Central Black Earth Region. As part of the annual tradition in the Russian city of Voronezh, every winter the main city square is thematically drawn around a classic literature. In 2020, the city was decorated using the motifs from Pyotr Ilyich Tchaikovsky's The Nutcracker. In the year of 2021, the architects drew inspiration from Hans Christian Andersen's fairy tale The Snow Queen as well as the animation classic The Snow Queen from the Soviet Union. The fairy tale replica city will feature the houses of Kai and Gerda, the palace of the snow queen, an ice rink, and illumination.
In June 2023, during the Wagner Group rebellion, forces of the Wagner Group claimed to have taken control of military facilities in the city. Later they were confirmed to have taken the city itself.
Administrative and municipal status
Voronezh is the administrative center of the oblast.[1] Within the framework of administrative divisions, it is incorporated as Voronezh Urban Okrug—an administrative unit with the status equal to that of the districts.[1] As a municipal division, this administrative unit also has urban okrug status.
City divisions
The city is divided into six administrative districts:
Zheleznodorozhny (183,17 km²)
Tsentralny (63,96 km²)
Kominternovsky (47,41 km²)
Leninsky (18,53 km²)
Sovetsky (156,6 km²)
Levoberezhny (123,89 km²)
Economy
The leading sectors of the urban economy in the 20th century were mechanical engineering, metalworking, the electronics industry and the food industry.
In the city are such companies as:
Tupolev Tu-144
Voronezhselmash (agricultural engineering)
Sozvezdie[36] (headquarter, JSC Concern “Sozvezdie”, in 1958 the world's first created mobile telephony and wireless telephone Altai
Verofarm (pharmaceutics, owner Abbott Laboratories),
Voronezh Mechanical Plant[37] (production of missile and aircraft engines, oil and gas equipment)
Mining Machinery Holding - RUDGORMASH[38] (production of drilling, mineral processing and mining equipment)
VNiiPM Research Institute of Semiconductor Engineering (equipment for plasma-chemical processes, technical-chemical equipment for liquid operations, water treatment equipment)
KBKhA Chemical Automatics Design Bureau with notable products:.
Pirelli Voronezh.
On the territory of the city district government Maslovka Voronezh region with the support of the Investment Fund of Russia, is implementing a project to create an industrial park, "Maslowski", to accommodate more than 100 new businesses, including the transformer factory of Siemens. On September 7, 2011 in Voronezh there opened a Global network operation center of Nokia Siemens Networks, which was the fifth in the world and the first in Russia.
Construction
In 2014, 926,000 square meters of housing was delivered.
Clusters of Voronezh
In clusters of tax incentives and different preferences, the full support of the authorities. A cluster of Oil and Gas Equipment, Radio-electronic cluster, Furniture cluster, IT cluster, Cluster aircraft, Cluster Electromechanics, Transport and logistics cluster, Cluster building materials and technologies.
Geography
Urban layout
Information about the original urban layout of Voronezh is contained in the "Patrol Book" of 1615. At that time, the city fortress was logged and located on the banks of the Voronezh River. In plan, it was an irregular quadrangle with a perimeter of about 238 meter. inside it, due to lack of space, there was no housing or siege yards, and even the cathedral church was supposed to be taken out. However, at this small fortress there was a large garrison - 666 households of service people. These courtyards were reliably protected by the second line of fortifications by a standing prison on taras with 25 towers covered with earth; behind the prison was a moat, and beyond the moat there were stakes. Voronezh was a typical military settlement (ostrog). In the city prison there were only settlements of military men: Streletskaya, Kazachya, Belomestnaya atamanskaya, Zatinnaya and Pushkarskaya. The posad population received the territory between the ostrog and the river, where the Monastyrskaya settlements (at the Assumption Monastery) was formed. Subsequently, the Yamnaya Sloboda was added to them, and on the other side of the fort, on the Chizhovka Mountain, the Chizhovskaya Sloboda of archers and Cossacks appeared. As a result, the Voronezh settlements surrounded the fortress in a ring. The location of the parish churches emphasized this ring-like and even distribution of settlements: the Ilyinsky Church of the Streletskaya Sloboda, the Pyatnitskaya Cossack and Pokrovskaya Belomestnaya were brought out to the passage towers of the prison. The Nikolskaya Church of the Streletskaya Sloboda was located near the marketplace (and, accordingly, the front facade of the fortress), and the paired ensemble of the Rozhdestvenskaya and Georgievskaya churches of the Cossack Sloboda marked the main street of the city, going from the Cossack Gate to the fortress tower.
Climate
Voronezh experiences a humid continental climate (Köppen: Dfb) with long, cold winters and short, warm summers.
Transportation
Air
The city is served by the Voronezh International Airport, which is located north of the city and is home to Polet Airlines. Voronezh is also home to the Pridacha Airport, a part of a major aircraft manufacturing facility VASO (Voronezhskoye Aktsionernoye Samoletostroitelnoye Obshchestvo, Voronezh aircraft production association) where the Tupolev Tu-144 (known in the West as the "Concordski"), was built and the only operational unit is still stored. Voronezh also hosts the Voronezh Malshevo air force base in the southwest of the city, which, according to a Natural Resources Defense Council report, houses nuclear bombers.[citation needed]
Rail
Since 1868, there is a railway connection between Voronezh and Moscow. Rail services form a part of the South Eastern Railway of the Russian Railways. Destinations served direct from Voronezh include Moscow, Kyiv, Kursk, Novorossiysk, Sochi, and Tambov. The main train station is called Voronezh-1 railway station and is located in the center of the city.
Bus
There are three bus stations in Voronezh that connect the city with destinations including Moscow, Belgorod, Lipetsk, Volgograd, Rostov-on-Don, and Astrakhan.
Education and culture
Aviastroiteley Park
The city has seven theaters, twelve museums, a number of movie theaters, a philharmonic hall, and a circus. It is also a major center of higher education in central Russia. The main educational facilities include:
Voronezh State University
Voronezh State Technical University
Voronezh State University of Architecture and Construction
Voronezh State Pedagogical University
Voronezh State Agricultural University
Voronezh State University of Engineering Technologies
Voronezh State Medical University named after N. N. Burdenko
Voronezh State Academy of Arts
Voronezh State University of Forestry and Technologies named after G.F. Morozov
Voronezh State Institute of Physical Training
Voronezh Institute of Russia's Home Affairs Ministry
Voronezh Institute of High Technologies
Military Educational and Scientific Center of the Air Force «N.E. Zhukovsky and Y.A. Gagarin Air Force Academy» (Voronezh)
Plekhanov Russian University of Economics (Voronezh branch)
Russian State University of Justice
Admiral Makarov State University of Sea and River Fleet (Voronezh branch)
International Institute of Computer Technologies
Voronezh Institute of Economics and Law
and a number of other affiliate and private-funded institutes and universities. There are 2000 schools within the city.
Theaters
Voronezh Chamber Theatre
Koltsov Academic Drama Theater
Voronezh State Opera and Ballet Theatre
Shut Puppet Theater
Festivals
Platonov International Arts Festival
Sports
ClubSportFoundedCurrent LeagueLeague
RankStadium
Fakel VoronezhFootball1947Russian Premier League1stTsentralnyi Profsoyuz Stadion
Energy VoronezhFootball1989Women's Premier League1stRudgormash Stadium
Buran VoronezhIce Hockey1977Higher Hockey League2ndYubileyny Sports Palace
VC VoronezhVolleyball2006Women's Higher Volleyball League A2ndKristall Sports Complex
Religion
Annunciation Orthodox Cathedral in Voronezh
Orthodox Christianity is the predominant religion in Voronezh.[citation needed] There is an Orthodox Jewish community in Voronezh, with a synagogue located on Stankevicha Street.
In 1682, the Voronezh diocese was formed to fight the schismatics. Its first head was Bishop Mitrofan (1623-1703) at the age of 58. Under him, the construction began on the new Annunciation Cathedral to replace the old one. In 1832, Mitrofan was canonized by the Russian Orthodox Church.
In the 1990s, many Orthodox churches were returned to the diocese. Their restoration was continued. In 2009, instead of the lost one, a new Annunciation Cathedral was built with a monument to St. Mitrofan erected next to it.
Cemeteries
There are ten cemeteries in Voronezh:
Levoberezhnoye Cemetery
Lesnoye Cemetery
Jewish Cemetery
Nikolskoye Cemetery
Pravoberezhnoye Cemetery
Budyonnovskoe Cemetery
Yugo-Zapadnoye Cemetery
Podgorenskоye Cemetery
Kominternovskoe Cemetery
Ternovoye Cemetery is а historical site closed to the public.
Born in Voronezh
18th century
Yevgeny Bolkhovitinov (1767–1837), Orthodox Metropolitan of Kiev and Galicia
Mikhail Pavlov (1792–1840), Russian academic and professor at Moscow University
19th century
1801–1850
Aleksey Koltsov (1809–1842), Russian poet
Ivan Nikitin (1824–1861), Russian poet
Nikolai Ge (1831–1894), Russian realist painter famous for his works on historical and religious motifs
Vasily Sleptsov (1836–1878), Russian writer and social reformer
Nikolay Kashkin (1839–1920), Russian music critic
1851–1900
Valentin Zhukovski (1858–1918), Russian orientalist
Vasily Goncharov (1861–1915), Russian film director and screenwriter, one of the pioneers of the film industry in the Russian Empire
Anastasiya Verbitskaya (1861–1928), Russian novelist, playwright, screenplay writer, publisher and feminist
Mikhail Olminsky (1863–1933), Russian Communist
Serge Voronoff (1866–1951), French surgeon of Russian extraction
Andrei Shingarev (1869–1918), Russian doctor, publicist and politician
Ivan Bunin (1870–1953), the first Russian writer to win the Nobel Prize for Literature
Alexander Ostuzhev (1874–1953), Russian and Soviet drama actor
Valerian Albanov (1881–1919), Russian navigator and polar explorer
Jan Hambourg (1882–1947), Russian violinist, a member of a famous musical family
Volin (1882–1945), anarchist
Boris Hambourg (1885–1954), Russian cellist who made his career in the USA, Canada, England and Europe
Boris Eikhenbaum (1886–1959), Russian and Soviet literary scholar, and historian of Russian literature
Anatoly Durov (1887–1928), Russian animal trainer
Samuil Marshak (1887–1964), Russian and Soviet writer, translator and children's poet
Eduard Shpolsky (1892–1975), Russian and Soviet physicist and educator
George of Syracuse (1893–1981), Eastern Orthodox archbishop of the Ecumenical Patriarchate
Yevgeny Gabrilovich (1899–1993), Soviet screenwriter
Semyon Krivoshein (1899–1978), Soviet tank commander; Lieutenant General
Andrei Platonov (1899–1951), Soviet Russian writer, playwright and poet
Ivan Pravov (1899–1971), Russian and Soviet film director and screenwriter
William Dameshek (1900–1969), American hematologist
20th century
1901–1930
Ivan Nikolaev (1901–1979), Soviet architect and educator
Galina Shubina (1902–1980), Russian poster and graphics artist
Pavel Cherenkov (1904–1990), Soviet physicist who shared the Nobel Prize in physics in 1958 with Ilya Frank and Igor Tamm for the discovery of Cherenkov radiation, made in 1934
Yakov Kreizer (1905–1969), Soviet field commander, General of the army and Hero of the Soviet Union
Iosif Rudakovsky (1914–1947), Soviet chess master
Pawel Kassatkin (1915–1987), Russian writer
Alexander Shelepin (1918–1994), Soviet state security officer and party statesman
Grigory Baklanov (1923–2009), Russian writer
Gleb Strizhenov (1923–1985), Soviet actor
Vladimir Zagorovsky (1925–1994), Russian chess grandmaster of correspondence chess and the fourth ICCF World Champion between 1962 and 1965
Konstantin Feoktistov (1926–2009), cosmonaut and engineer
Vitaly Vorotnikov (1926–2012), Soviet statesman
Arkady Davidowitz (1930), writer and aphorist
1931–1950
Grigory Sanakoev (1935), Russian International Correspondence Chess Grandmaster, most famous for being the twelfth ICCF World Champion (1984–1991)
Yuri Zhuravlyov (1935), Russian mathematician
Mykola Koltsov (1936–2011), Soviet footballer and Ukrainian football children and youth trainer
Vyacheslav Ovchinnikov (1936), Russian composer
Iya Savvina (1936–2011), Soviet film actress
Tamara Zamotaylova (1939), Soviet gymnast, who won four Olympic medals at the 1960 and 1964 Summer Olympics
Yury Smolyakov (1941), Soviet Olympic fencer
Yevgeny Lapinsky (1942–1999), Soviet Olympic volleyball player
Galina Bukharina (1945), Soviet athlete
Vladimir Patkin (1945), Soviet Olympic volleyball player
Vladimir Proskurin (1945), Soviet Russian football player and coach
Aleksandr Maleyev (1947), Soviet artistic gymnast
Valeri Nenenko (1950), Russian professional football coach and player
1951–1970
Vladimir Rokhlin, Jr. (1952), Russian-American mathematician and professor of computer science and mathematics at the Yale University
Lyubov Burda (1953), Russian artistic gymnast
Mikhail Khryukin (1955), Russian swimmer
Aleksandr Tkachyov (1957), Russian gymnast and two times Olympic Champion
Nikolai Vasilyev (1957), Russian professional football coach and player
Aleksandr Babanov (1958), Russian professional football coach and player
Sergey Koliukh (1960), Russian political figure; 4th Mayor of Voronezh
Yelena Davydova (1961), Soviet gymnast
Aleksandr Borodyuk (1962), Russian football manager and former international player for USSR and Russia
Aleksandr Chayev (1962), Russian swimmer
Elena Fanailova (1962), Russian poet
Alexander Litvinenko (1962–2006), officer of the Russian FSB and political dissident
Yuri Shishkin (1963), Russian professional football coach and player
Yuri Klinskikh (1964–2000), Russian musician, singer, songwriter, arranger, founder rock band Sektor Gaza
Yelena Ruzina (1964), athlete
Igor Bragin (1965), footballer
Gennadi Remezov (1965), Russian professional footballer
Valeri Shmarov (1965), Russian football player and coach
Konstantin Chernyshov (1967), Russian chess grandmaster
Igor Pyvin (1967), Russian professional football coach and player
Vladimir Bobrezhov (1968), Soviet sprint canoer
1971–1980
Oleg Gorobiy (1971), Russian sprint canoer
Anatoli Kanishchev (1971), Russian professional association footballer
Ruslan Mashchenko (1971), Russian hurdler
Aleksandr Ovsyannikov (1974), Russian professional footballer
Dmitri Sautin (1974), Russian diver who has won more medals than any other Olympic diver
Sergey Verlin (1974), Russian sprint canoer
Maxim Narozhnyy (1975–2011), Paralympian athlete
Aleksandr Cherkes (1976), Russian football coach and player
Andrei Durov (1977), Russian professional footballer
Nikolai Kryukov (1978), Russian artistic gymnast
Kirill Gerstein (1979), Jewish American and Russian pianist
Evgeny Ignatov (1979), Russian sprint canoeist
Aleksey Nikolaev (1979), Russian-Uzbekistan footballer
Aleksandr Palchikov (1979), former Russian professional football player
Konstantin Skrylnikov (1979), Russian professional footballer
Aleksandr Varlamov (1979), Russian diver
Angelina Yushkova (1979), Russian gymnast
Maksim Potapov (1980), professional ice hockey player
1981–1990
Alexander Krysanov (1981), Russian professional ice hockey forward
Yulia Nachalova (1981–2019), Soviet and Russian singer, actress and television presenter
Andrei Ryabykh (1982), Russian football player
Maxim Shchyogolev (1982), Russian theatre and film actor
Eduard Vorganov (1982), Russian professional road bicycle racer
Anton Buslov (1983–2014), Russian astrophysicist, blogger, columnist at The New Times magazine and expert on transportation systems
Dmitri Grachyov (1983), Russian footballer
Aleksandr Kokorev (1984), Russian professional football player
Dmitry Kozonchuk (1984), Russian professional road bicycle racer for Team Katusha
Alexander Khatuntsev (1985), Russian professional road bicycle racer
Egor Vyaltsev (1985), Russian professional basketball player
Samvel Aslanyan (1986), Russian handball player
Maksim Chistyakov (1986), Russian football player
Yevgeniy Dorokhin (1986), Russian sprint canoer
Daniil Gridnev (1986), Russian professional footballer
Vladimir Moskalyov (1986), Russian football referee
Elena Danilova (1987), Russian football forward
Sektor Gaza (1987–2000), punk band
Regina Moroz (1987), Russian female volleyball player
Roman Shishkin (1987), Russian footballer
Viktor Stroyev (1987), Russian footballer
Elena Terekhova (1987), Russian international footballer
Natalia Goncharova (1988), Russian diver
Yelena Yudina (1988), Russian skeleton racer
Dmitry Abakumov (1989), Russian professional association football player
Igor Boev (1989), Russian professional racing cyclist
Ivan Dobronravov (1989), Russian actor
Anna Bogomazova (1990), Russian kickboxer, martial artist, professional wrestler and valet
Yuriy Kunakov (1990), Russian diver
Vitaly Melnikov (1990), Russian backstroke swimmer
Kristina Pravdina (1990), Russian female artistic gymnast
Vladislav Ryzhkov (1990), Russian footballer
1991–2000
Danila Poperechny (1994), Russian stand-up comedian, actor, youtuber, podcaster
Darya Stukalova (1994), Russian Paralympic swimmer
Viktoria Komova (1995), Russian Olympic gymnast
Vitali Lystsov (1995), Russian professional footballer
Marina Nekrasova (1995), Russian-born Azerbaijani artistic gymnast
Vladislav Parshikov (1996), Russian football player
Dmitri Skopintsev (1997), Russian footballer
Alexander Eickholtz (1998) American sportsman
Angelina Melnikova (2000), Russian Olympic gymnast
Lived in Voronezh
Aleksey Khovansky (1814–1899), editor
Ivan Kramskoi (1837–1887), Russian painter and art critic
Mitrofan Pyatnitsky (1864–1927), Russian musician
Mikhail Tsvet (1872–1919), Russian botanist
Alexander Kuprin (1880–1960), Russian painter, a member of the Jack of Diamonds group
Yevgeny Zamyatin (1884-1937), Russian writer, went to school in Voronezh
Osip Mandelstam (1891–1938), Russian poet
Nadezhda Mandelstam (1899-1980), Russian writer
Gavriil Troyepolsky (1905–1995), Soviet writer
Nikolay Basov (1922–2001), Soviet physicist and educator
Vasily Peskov (1930–2013), Russian writer, journalist, photographer, traveller and ecologist
Valentina Popova (1972), Russian weightlifter
Igor Samsonov, painter
Tatyana Zrazhevskaya, Russian boxer
C/n 10609 Del 2/81 to USSR Ministry of Radio Industry CCCP-26639, RA-26639 1993 Ermolinsky Charter Airlines, t/f by 2009 to Geodynamics Centre for Cartographic Aerial Surveying still active 2023
Illustrations from the book:
Mirador Observatory, Baguio, Benguet
A new meteorological-geodynamic station of the Weather Bureau
By Rev. Jose Algue, S.J. director to the Weather Bureau.
Published 1909 by Bureau of Printing in Manila.
openlibrary.org/books/OL7077917M/Mirador_observatory_Bagu...
Picture was taken from the west looking east.
Mirador Observatory lies within the town of Baguio close to the western boundary of the city, and comprises an isolated hill, “Mirado” (Mount Lookout)
Illustrations from the book:
Mirador Observatory, Baguio, Benguet
A new meteorological-geodynamic station of the Weather Bureau
By Rev. Jose Algue, S.J. director to the Weather Bureau.
Published 1909 by Bureau of Printing in Manila.
openlibrary.org/books/OL7077917M/Mirador_observatory_Bagu...
The ring tower is a striking high-rise building in a prominent location in Vienna, where is located the headquarters of the Vienna Insurance Group. It was built in 1953-1955 after designs of Erich Boltenstern at Schottenring inside the Viennese Ringstrasse and is located at the stop Schottenring of the Wiener Linien (Vienna Public Transport). The 73 meter (93 meter height including the weather light column) high ring tower was deemed as innovative project for the reconstruction of the city.
The building, which previously stood on this plot, was the only one of the entire Scots ring which was destroyed in the Second World War. The ring tower with its 23 floors and its 20-meter high weather lighthouse is the second highest building inside Vienna's Ringstrasse. Higher is only the Gothic-style St. Stephen's Cathedral. In addition to the central office of the Vienna Insurance Group are now also offices of Wiener Stadtwerke (public utility company) in the ring tower. In the office building a total of 12,000 square meters of effective surface is available. The facade and parts of the ring tower were renovated in 1996.
Name
In a contest, a name was sought for the then very modern office skyscraper. Among 6,502 entries the name "ring tower" was chosen. There were, among other proposals, such as City House, Gutwill-house (goodwill-house), house of reciprocity, high-corner, new tower, Sonnblick-house, insurance high-rise, Vindobona-house or vision-house (farsightedness-house) of the creative population after the war. One of the submitters of the name "ring tower" was rewarded with an honorarium of 2,000 shillings.
Weather lighthouse
Weather lighthouse, seen from the ring road
On the roof there is the 20-meter high weather lighthouse with 117 lights in differently colored light signals the weather for the next day displaying (each 39 white, red and green lights as well as 2 additional air traffic control lights).
This light column is directly connected to the ZAMG (Central Institute for Meteorology and Geodynamics) on the Hohenwarte in Vienna.
Meaning of the signals:
red ascending = temperature rising
red descending = temperature falling
green ascending = weather conditions will be better
green descending = weather will be worse
Flashing red = warning lightning or storms
Flashing white = snow or ice
Ringturm 2013
Ringturm disguising
Since 2006, the ring tower is changed every year into an "art tower " by covering the building with printed webs. The covering consists of 30 printed network paths with about 3 meters wide and 63 or 36 meters in length , and the resulting area is approximately 4,000 square meters.
The previous art projects:
2006 "Don Giovianni" by Christian Ludwig Attersee (on the occasion of the Mozart Year)
2007 "Tower of Life" by Robert Hammerstiel
2008 "Tower in Bloom" by Hubert Schmalix (Blumenstillleben)
2011 "Sense of family" Xenia Hausner
2012 "Society" by Hungarian artist László Fehér
2013 "Connectedness" of the Slovak artist Dorota Sadovská
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www.flickr.com/photos/jeisus2012/sets/72157626153283579/w...;
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* The integrated 3D-4D GeoSEIS Tomography Method is a unique tool of 3D-4D transformations and integration of DEM, airborne thermal & multispectral satellite images, airborne/ground gamma-ray spectrometry, geophysical, geological and geochemical data into multicomponent volumetric 3D-4DGeoSEIST GIS for an exact and cost-effective 4D modelling!
* The prime commercial focus is a consulting service to assist predictive discovery of mineral & oil-gas deposits through application of advanced multicomponent volumetric 4D GeoSEIS Tomography modeling of spectral brightness and geophysical fields to targeting problems. This emerging 4D GeoSEIS technology is starting to be utilized by exploration companies and has the potential to improve the probability of exploration success by reducing the time and cost involved in discovery.
* Mining professionals of State Enterprise "NIGRI" (Mining-Ore Research Institute, Ukraine) have used 3D GeoSEIS Tomography to accurately locate subsurface volumetric distribution of cavities, mine workings, active geodynamic zones, concentration of stresses for building thermographic inspection and nondistructive control of of buildings and engineering designs/constructions. The Infrared Inspection was performed by Thermal Imaging, by a certified IR/TIR Thermographer and Digital Photocamera. This inspection is designed to assess the performance and volumetric location of building, roof, underfloor heating stress lineament and also to show their...
Illustrations from the book:
Mirador Observatory, Baguio, Benguet
A new meteorological-geodynamic station of the Weather Bureau
By Rev. Jose Algue, S.J. director to the Weather Bureau.
Published 1909 by Bureau of Printing in Manila.
openlibrary.org/books/OL7077917M/Mirador_observatory_Bagu...
The Stefanos crater at the floor of the volcano caldera in the island of Nisyros.
The Greek island of Nisyros is an active volcano located at the easternmost end of the Aegean Volcanic Arc, within the Dodecanese archipelago, situated south of Kos. It has a circular form with a diameter of about 10 kilometers.
The island is a remnant of a prehistoric volcanic field from which 160,000 years ago the largest eruption in the eastern Mediterranean (Kos plateau tuff) devastated the entire Dodecanese islands. The explosion of the Kos volcano was many times stonger than the one that happened at Santorini in Minoan times. The south-western part of Kos was blown in the air by a huge eruption and even today you can find thick layers of pumice and pyroclastic rocks on the island.
Actually, Nisyros is one big strato-volcano and may have risen as high as 1000 metres 24,000 years ago. The main central cone of the volcano then collapsed during an eruption to leave the 3.8 km-wide caldera we see today, around 400 metres high. The eruption covered the sides of the island with a layer of pumice stones and pyroclastic deposits 100 meters thick.
Violent earthquakes and steam blasts accompanied the most recent hydrothermal eruptions in 1871-1873 and 1887 and left large crater holes behind.
In 1996 and 1997 seismic activity started again with earthquakes of magnitudes up to 5.5 and with hypocenters down to 10 km depth. The present geodynamic activity encompasses high seismic unrest and widespread fumarolic activity.
Stefanos is the biggest and the best preserved hydrothermal crater in the world. Its form is ellipsoidal; its tallest axe is extended at 330 metres and the smallest 260 metres. Its height is extended at 30 metres and it is estimated that it cannot be older than 3000-4000 years.
Illustrations from the book:
Mirador Observatory, Baguio, Benguet
A new meteorological-geodynamic station of the Weather Bureau
By Rev. Jose Algue, S.J. director to the Weather Bureau.
Published 1909 by Bureau of Printing in Manila.
openlibrary.org/books/OL7077917M/Mirador_observatory_Bagu...
Recent glacial deposits were uncovered by wave action at Reiss Beach in Caithness. Glacial striations on one of the surface of a Devonian Old Red Sandstone surface of a mainly mudstone boulder. Recent glacial deposits were uncovered by wave action. There are two main directions of multiple ice striae showing clear intersects and crosscuts. This is the best example of striae of the 4 boulders showing multiple ice striae. Unlike the other 3 in situ in the till/silt deposits this one was found on the east side of the recently uncovered till/silt deposits on top of boulders.
This photograph was taken by my father after I carried the striated boulder to his home, so copyright of the image is the property of Robert Sinclair Shand.
Glacial striations examples from all over the world:
maps.unomaha.edu/Maher/geo330/kirk1.html
blogs.agu.org/mountainbeltway/2014/10/28/glacial-striations/
www.flickr.com/photos/jsjgeology/14972503578/in/set-72157...
blogs.agu.org/mountainbeltway/2012/08/08/what-those-geolo...
www.uwosh.edu/faculty_staff/hiatt/Research/work.html
www.grisda.org/2014-banff/images/184d-glacier928.jpg
maps.unomaha.edu/Maher/geo330/kirk1.html
blogs.agu.org/mountainbeltway/2012/08/08/what-those-geolo...
www.swisseduc.ch/glaciers/earth_icy_planet/glaciers15-en....
webspace.ship.edu/cjwolt/geology/slides/jpg/gl08.jpg
blogs.agu.org/mountainbeltway/2012/08/21/glacial-striatio...
bgrg.org/pages/education/alevel/coldenvirons/Striations1.htm
www.uwgb.edu/dutchs/Petrology/Leaverite-Surface.HTM
luirig.altervista.org/pics/index4.php?search=Striated+gla...
quizlet.com/3777187/glaciers-flash-cards/
Links describing glacier plucking:
www.earthonlinemedia.com/ebooks/tpe_3e/glacial_systems/ge...
www.geology.um.maine.edu/geodynamics/AnalogWebsite/Underg...
www4.uwsp.edu/geo/faculty/lemke/geol370/lectures/08_trans...
members.shaw.ca/len92/geology.htm
www.geology.um.maine.edu/geodynamics/AnalogWebsite/Underg...
geogblogdno.blogspot.co.uk/p/ice-on-land-new.html
www.geocaching.com/geocache/GC26DTM_7wpc-ledgedale-natura...
uwaterloo.ca/wat-on-earth/news/selwyns-rock
Glacier rebound: