The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data
Збережено в:
| Опубліковано в: : | Геофизический журнал |
|---|---|
| Дата: | 2010 |
| Автори: | , , , |
| Формат: | Стаття |
| Мова: | Англійська |
| Опубліковано: |
Інститут геофізики ім. С.I. Субботіна НАН України
2010
|
| Онлайн доступ: | https://nasplib.isofts.kiev.ua/handle/123456789/101313 |
| Теги: |
Додати тег
Немає тегів, Будьте першим, хто поставить тег для цього запису!
|
| Назва журналу: | Digital Library of Periodicals of National Academy of Sciences of Ukraine |
| Цитувати: | The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data / B. Busygin, S. Nikulin, E. Zatsepin, I. Garkusha // Геофизический журнал. — 2010. — Т. 32, № 4. — С. 26-28. — Бібліогр.: 4 назв. — англ. |
Репозитарії
Digital Library of Periodicals of National Academy of Sciences of Ukraine| _version_ | 1859659815536558080 |
|---|---|
| author | Busygin, B. Nikulin, S. Zatsepin, E. Garkusha, I. |
| author_facet | Busygin, B. Nikulin, S. Zatsepin, E. Garkusha, I. |
| citation_txt | The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data / B. Busygin, S. Nikulin, E. Zatsepin, I. Garkusha // Геофизический журнал. — 2010. — Т. 32, № 4. — С. 26-28. — Бібліогр.: 4 назв. — англ. |
| collection | DSpace DC |
| container_title | Геофизический журнал |
| first_indexed | 2025-11-30T09:26:27Z |
| format | Article |
| fulltext |
�������
����
���� ����
�� ������������������ !�"�#$�%&�'�$��()(
The methodology of operative prognosis of hydrocarbons
by gravity-magnetic and space data
B. Busygin, S. Nikulin, E. Zatsepin, I. Garkusha, 2010
National Mining University, Dniepropetrovsk, Ukraine
BusyginB@nmu.org.ua
Introduction. Because of constant growth of
consumption of hydrocarbonic raw stock and ex-
haustion of world’s reserves of oil and gas the prob-
lem of searches of new hydrocarbonic objects be-
comes more and more important. Nowadays for its
decision the seismic survey in various modifications
(for example, 3D, etc.) is used. However, posses-
sing high geological efficiency, it demands large eco-
nomic expenses, especially at field surveying on
the big areas. For this reason the approaches based
on using of a complex of cheap gravity-magnetic
methods and space images of the various physical
nature (multispectral, radar, thermal, etc.) received
a wide dissemination.
Using the special geoinformation systems and
technologies of the integrated analysis of spatial
data [Pivnyak et al., 2007; Busygin, Nikulin, 2009],
it is possible to implement the preliminary alloca-
tion of the sites on which it is expedient to apply
detailed seismic survey. Use of such technique will
allow to reduce considerably costs without essen-
tial loss of the information and to optimize a loca-
tion of reconnaissance wells.
Investigated area. The proposed technique has
been tested on a site in the size 137 130 km by
the area more than 17000 km2, located within the
Dnieper—Donetsk cavity (DDC) (Fig. 1). Now the
major strategic direction of searches of oil and gas
in the territory of DDC are depths over 5 km. By the
Fig. �. Area location�
most reasonable estimations in the range of depths
of 5—8 km it is concentrated over 5 billion tons of
conditional fuel. At the beginning of 2009 there was
discovered a great number of deposits in this re-
gion, amongst them — one of the largest in Europe
Shebelinskoye gas-condensate deposit with re-
source of 650 bil. m3 (exhausted).
The initial data are presented by gravitational ( g)
and magnetic (Za) surveys on a grid 500 500 m,
and the radar image received by SRTM (Shuttle
Radar Topography Mission) with the resolution of
90 m. In researches were used 29 known hydrocar-
bons deposits, presented by gas, gas-condensate,
and oil-and-gas objects.
Research technique. The apparatus of line-
ament analysis, based on detection and research
of lineaments — the linear sites detected on space
images and on physical fields, underlie the proposed
technique.
������������������ !�"�#$�%&�'�$��()( �*
+,� ��-.�,/�0
��.������1
�,
��0.�0��0���,������ �����
��
Fig. 3. Orthogonal systems of lineaments with azimuth 45—135º, detected on
magnetic (a), gravitational (b) fields and in a radar image (c).
For more accurate allocation of lineaments the
radar image and geophysical fields were exposed
to the operations of images processing – contras-
ting, histogram alignment, sharpness increase
(Fig. 2). The images received as a result of proces-
sing, have allowed to allocate more amount of lin-
ear elements, including, visually not distinguishable
in initial materials. Then using the Canny «optimal
detector» [Canny, 1986] on space image and raster
Fig. 2. Fragment of the raster map of magnetic field before (a) and after (b) operations of
images processing (colors of a legend are generated in a random way).
maps of fields the borders of brightness were de-
fined and corresponding maps were built.
The lineaments were allocated using the Hough
transformation [Sewisy, 2002] to brightness borders
maps. The circle diagram estimation showed that two
orthogonal systems of lineaments with azimuth 0—
90 and 45—135 are presented on the image. In a
Fig. 3 the scheme of lineaments location with azimuths
45 and 135 is presented, and in a Fig. 4 — the den-
sity (amount on area unit) of these lineaments, calcu-
lated in a sliding window 5000 5000 m, is presented.
The absolute majority of known objects are in
conjunction with zones of high density (9 from 28)
and with sites of their intersection (8 from 28) or in
�������
����
���� ����
�2 ������������������ !�"�#$�%&�'�$��()(
immediate proximity from them, while no essential
relationship between the system of lineaments with
azimuths 0—90 is observed (Fig. 5).
Conclusions. Thus, the sites of high lineaments
density can be considered as perspective on de-
tection of oil and gas objects and to be recommen-
ded for analysis by seismic prospecting of various
modifications.
The relationship between location of oil and gas
objects and zones of the high lineaments density in-
dicate to the possibility of use the relatively cheap
geophysical (gravitational and magnetic), and also
space methods for preliminary allocation of promising
sites.
Fig. 4.�����
�����
������������with azimuth 45 and 135º. Fig. 5.�����
�����
�������
���
����
���������
���������
�� ���
����
��������
Busygin B., Nikulin S. The methodology of oil and gas
deposits prognosis by space and geophysical data
// 71rd EAGE conference. — Amsterdam, 2009. —
4 �.
Canny J. F. A computational approach to edge detec-
tion // IEEE Trans Pattern Analysis and Machine
Intelligence. — 1986. — � 8. — �. 679—698.
Pivnyak G. G., Busygin B. S., Nikulin S. L. GIS-techno-
logy of integrated heterogeneous and different-le-
vel geodata analysis // Rep. National Acad. Sci. of
Ukraine. — 2007. — ��7. — P. 121—128.
Sewisy A. A. Graphical techniques for detecting lines
with the Hough transform // JCM. — 2002. — 79. —
P. 49—64.
References
|
| id | nasplib_isofts_kiev_ua-123456789-101313 |
| institution | Digital Library of Periodicals of National Academy of Sciences of Ukraine |
| issn | 0203-3100 |
| language | English |
| last_indexed | 2025-11-30T09:26:27Z |
| publishDate | 2010 |
| publisher | Інститут геофізики ім. С.I. Субботіна НАН України |
| record_format | dspace |
| spelling | Busygin, B. Nikulin, S. Zatsepin, E. Garkusha, I. 2016-06-02T08:09:56Z 2016-06-02T08:09:56Z 2010 The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data / B. Busygin, S. Nikulin, E. Zatsepin, I. Garkusha // Геофизический журнал. — 2010. — Т. 32, № 4. — С. 26-28. — Бібліогр.: 4 назв. — англ. 0203-3100 https://nasplib.isofts.kiev.ua/handle/123456789/101313 en Інститут геофізики ім. С.I. Субботіна НАН України Геофизический журнал The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data Article published earlier |
| spellingShingle | The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data Busygin, B. Nikulin, S. Zatsepin, E. Garkusha, I. |
| title | The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data |
| title_full | The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data |
| title_fullStr | The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data |
| title_full_unstemmed | The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data |
| title_short | The methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data |
| title_sort | methodology of operative prognosis of hydrocarbons by gravity-magnetic and space data |
| url | https://nasplib.isofts.kiev.ua/handle/123456789/101313 |
| work_keys_str_mv | AT busyginb themethodologyofoperativeprognosisofhydrocarbonsbygravitymagneticandspacedata AT nikulins themethodologyofoperativeprognosisofhydrocarbonsbygravitymagneticandspacedata AT zatsepine themethodologyofoperativeprognosisofhydrocarbonsbygravitymagneticandspacedata AT garkushai themethodologyofoperativeprognosisofhydrocarbonsbygravitymagneticandspacedata AT busyginb methodologyofoperativeprognosisofhydrocarbonsbygravitymagneticandspacedata AT nikulins methodologyofoperativeprognosisofhydrocarbonsbygravitymagneticandspacedata AT zatsepine methodologyofoperativeprognosisofhydrocarbonsbygravitymagneticandspacedata AT garkushai methodologyofoperativeprognosisofhydrocarbonsbygravitymagneticandspacedata |