RU2215308C1 - Procedure detecting surface anomalies in process of seismic prospecting ( variants ) - Google Patents

Abstract

FIELD: search for mineral wealth. SUBSTANCE: seismic vibrations excited by sources and received by detectors are summed up by common points of reception and excitation to obtain time seismic sections of profile in the form of collection of signals of summary routes. Mentioned sections are rectified by way of input of static corrections. Fixed groups ( bases ) are selected from detectors of seismic vibrations uniformly arranged along profile and summation of seismic vibrations received by detectors on corresponding adjacent bases is carried out per each source. Fixed bases of sources are also selected and summation of seismic vibrations excited by sources on corresponding fixed bases is also carried out per each detector. At least two routes belonging to two different fixed bases of summation spaced along profile are obtained per each detector and source in process of summation. Surface anomalies are isolated on time seismic sections by coincidence sign of time distortions of reflections on time seismic sections related to different bases of summation. Boundaries of anomalies and values of time shift of times of arrival of reflected waves within limits of anomaly relative to smoothed lines of time of arrival of reflected waves conducted by points outside of anomalous districts are established. These time shifts averaged by collection of obtained time seismic sections are entered as static corrections into obtained seismic data. EFFECT: raised authenticity of detection of surface anomalies of various extent thanks to surface-timed summation of data of seismic prospecting. 4 cl, 10 dwg

Description

 The claimed method (options) relates to the means and methods used in seismic exploration, including minerals, by means of which surface anomalies are detected and taken into account, since they can veil useful data on deep heterogeneities. The claimed method (options) relates to the so-called seismic method of OGT (common deep points) in two-dimensional or three-dimensional modifications. Identified surface anomalies are taken into account in the formation of sections and cubes of total traces by determining and introducing static corrections that eliminate the time shifts caused by these surface anomalies.

 When processing seismic data according to the method of common deep points (OGT) in the claimed variants of the method, surface-consistent time-dependent seismic sections obtained and obtained from the common excitation points (OTV) and the common reception points (OTP) of two modifications are formed and analyzed: with fixing of the summation bases and with fixing the distance ranges between the oscillation sources and the receiver. Such a temporary seismic section is a sequence of total traces obtained by summing the signals recorded during excitation of oscillations in one point (source) (OTV) by different receivers or in one point of reception (receiver) when excitation of oscillations by different sources (OTP). With three-dimensional observation systems (3D), the so-called cubes of total traces of OTV and OTP are formed and analyzed similarly to two-dimensional sections.

State of the art
A known method for detecting surface anomalies in partial multiple time sections described in US patent 3940734, G 01 V 1/12 [1]. The essence of the known method is to identify unaccounted for surface anomalies in partial multiple time sections of the OGT. In the presence of such anomalies, the reflection times on the paths, summed up by different selections of sources and receivers for the same CDPs, should differ. The alternating time differences in partial multiple sections of the OHT in different ranges of removal can serve as a sign of surface anomalies. However, the determination of the magnitude of the amendments compensating for the identified anomalies is not provided for in this method.

 To date, reliable methods for determining static corrections, taking into account the revealed rather long, medium and long-period surface anomalies, have not been developed. This is largely due to the estimation uncertainty that increases with the increase in spatial wavelengths during seismic exploration (Wiggins RA: et al., 1976, Residual static analysis as a general linear inverse problem / Geophysics, v.41, p.922-938) [5 ]. To eliminate this type of uncertainty, additional data is needed. Therefore, numerous automatic correction methods for static corrections, working with reflection signals, in which the introduction of these additional data is not provided, reliably determine, as a rule, only short-period components.

 Known methods for using surface-consistent temporal seismic sections to determine static corrections, involving the summation of traces with the common position of the oscillation source or receiver (Disher DA and Naquin PJ, 1970, Statistical automatic statics analysis / Geophysics, v. 35, p. 574-585 [ 2]; SU 369527 G 01 V 1/28 04/12/1973 [3], US 3681749, G 01 V 1/28, 08/01/1972 [4]). Such a summation of traces provides information compression and an increase in the signal-to-noise ratio, which facilitates the analysis of data by a geophysicist. However, the described methods relate mainly to the determination of short-period components, i.e. superficial anomalies of small extent.

Disclosure of the technical essence
To take into account extended surface anomalies, an interactive analysis and interpretation of time sections of various types by a geophysicist is required with the use of additional data on the upper part of the section and reflecting boundaries, which is provided for in the proposed methods.

 The technical result of the invention is to provide the possibility of increasing the reliability of detecting surface anomalies of various lengths due to surface-matched summation of seismic data by the OGT method, i.e. summation with fixing the positions of the source or receiver, carried out with fixing the summation bases - groups of sources or receivers or in different ranges of distances, which provides the transmission of inhomogeneities from different points, at different angles, while forming temporary seismic sections with two-dimensional (2D) or total cubes traces during three-dimensional (3D) seismic observations. The claimed methods provide for the determination of anomalies according to the principle of surface consistency: anomalies that are observed at the same points of reception or excitation and diverge when the sections are aligned at common depth points, can be classified as static and eliminated using residual static corrections. The claimed method (options) provides, in comparison with known methods, an increase in the reliability of identifying and accounting for surface anomalies of different lengths during seismic surveys with CDP.

 The technical result is achieved by the fact that the method for detecting surface anomalies during seismic exploration according to profiles according to the first embodiment consists in summing up seismic vibrations excited by sources and received by receivers from common points of reception and common points of excitation, to obtain temporary seismic sections along the profile in the form the totality of the signals of the total traces and carry out the correction of these sections by entering static corrections, while from uniformly located along the profile at of seismic vibrations, fixed groups (bases) are selected and, for each source, the seismic vibrations received by the receivers at the corresponding nearest fixed bases are summarized, fixed source bases are also selected, and for each receiver, the seismic vibrations excited by the sources at the corresponding fixed bases are added up, with the specified summation receive for each receiver and source at least two total paths belonging to two different phi surface anomalies are identified on temporary seismic sections on the basis of coincidence of reflection time distortions on temporary seismic sections related to different fixed summation bases, the boundaries of the anomalies and the magnitude of time shifts of the arrival times of reflected waves within the anomaly relative to smooth lines the arrival times of reflected waves drawn along points outside the anomalous sections, and these time shifts, averaged over the aggregate and the obtained temporary seismic sections, are introduced as static corrections into the obtained seismic data.

 The technical result is also achieved by the fact that the method for detecting surface anomalies during seismic exploration according to profiles according to the second embodiment consists in summing up seismic vibrations excited by sources and received by receivers from common points of reception and common points of excitation, with the formation of temporary seismic sections along the profile in in the form of a set of signals of the total paths and carry out the correction of these sections by entering static corrections, while for uniformly located along the prof For seismic oscillation receivers, several fixed ranges of distances to the sources of oscillations are selected and summed for each receiver the vibrations excited by the sources separately in each of the ranges of distances, they also summarize for each source the vibrations received by receivers located in the selected ranges of distances from the sources, when this summation is obtained for each receiver and source, at least two total paths related to different fixed ranges of distances, comparing obtained temporal seismic sections on the scale of surface positions — points of location of sources and receivers and on the scale of depth positions — common depth points, identify anomalies that coincide in surface positions and do not coincide in depth points, determine the boundaries of the selected sections of anomalies or anomalies and the magnitude of time shifts by the value of the lead or delay of oscillations in time sections relative to the smoothed lines of the times of arrival of waves drawn along points outside the anomalous sections during temporal representation of seismic sections for deep positions (GBS), and these time shifts, averaged by said plurality of slits, is administered as static corrections in the received seismic data.

 The technical result is also achieved by the fact that the method for detecting surface anomalies during seismic exploration according to profiles according to the third embodiment consists in summing up seismic vibrations excited by sources and received by receivers from common points of reception and common points of excitation, to obtain temporary seismic sections along the profile in as a set of signals of total traces and carry out the correction of these seismic sections by entering static corrections, while for evenly located along the profile of the receivers of seismic vibrations, several fixed ranges of distances to the sources of oscillations are selected and summed for each receiver the vibrations excited by the sources separately in each of the ranges also summarize for each source the vibrations received by receivers located in the selected ranges of distances from the sources, with the specified summation receive for each receiver and source at least two total traces related to different fixed ranges of distances, average they comprehend the obtained temporary seismic sections on the scale of surface positions — points of location of sources and receivers and on the scale of depth positions — common depth points (CDPs), identify anomalies that coincide in surface positions and do not coincide in depth points, determine the boundaries of the selected sections of anomalies or anomalies, near the boundaries of the selected areas with anomalies, fixed bases for summing sources and receivers are selected, oscillations excited by the sources or registered are summed data from these fixed bases, using the totality of temporary seismic sections with both fixed offsets and fixed bases, determine the position of the anomalous sections and determine the magnitude of the time shifts of the reflected signals within the anomalies relative to the smoothed wave arrival time lines drawn at points outside the anomalous sections along the totality of temporary seismic sections, combined at depth positions (CDP), and these time shifts, averaged for different time seismic times cuts, introduced as static corrections in the obtained seismic data.

 The technical result is also achieved by the fact that a method for detecting surface anomalies in three-dimensional seismic exploration consists in summing up seismic vibrations excited by sources and received by seismic oscillation receivers using common points of reception and common points of excitation, to obtain cubes of total traces, and carry out data correction by static corrections, while fixed groups (bases) are selected from sources of oscillations uniformly located over the area of oscillations, and for each method nicknames summarize the seismic vibrations excited by the sources at the corresponding nearest fixed bases, also select the fixed base of the receivers by area and summarize the seismic vibrations recorded by the receivers at the corresponding fixed bases for each source, with at least two for each receiver and source total traces belonging to two different summation bases over the obtained sections of cubes of total traces for different fixed summation bases for each of the source and receiver location lines identify anomalies - areas of the same for different fixed bases time shifts of reflected signals, which corresponds to zones of surface inhomogeneities, determine the boundaries of inhomogeneities in the area and the magnitude of time shifts of reflected signals within the anomaly relative to smoothed time lines the arrival of reflected waves drawn at points outside the anomalous sections, and these shifts are introduced as static corrections in seismic data.

 The claimed group of inventions is illustrated by drawings.

 Figure 1 - diagram of the formation of a fragment of a temporary seismic section of the common points of excitation (OTV) by summing the signals recorded by receivers located on one fixed base.

 FIG. 2 is a diagram of the formation of an OT section along a profile using at least two summation bases with fixed receiver positions.

 Figure 3 - diagram of the summation of seismic traces (waveforms) on a generalized plane to obtain a fragment of a temporary seismic section with a fixed base (symmetric 96-channel arrangement).

 FIG. 4a is a diagram of the manifestation of surface inhomogeneity in temporary seismic sections of the OTP in a fixed range of removal of vibration sources.

Figb is a diagram of the manifestation of surface heterogeneity in the sections of the OTP with fixed bases of summation (base sources of oscillations S ₁ , S ₂ ).

 Figure 5 - partial temporary seismic sections of the OTP on the right branch of the arrangement of receivers in different ranges of removal of oscillation sources.

 FIG. 6 - partial multiple time seismic sections of the OTP along the left branch of the arrangement of receivers in different ranges of removal of oscillation sources.

 Fig. 7 is a partial multiple temporal seismic section of the OTP with fixing ranges of removal of sources (0-600 m, 600-1200 m, 1200-1800 m) in comparison with the section with fixed bases (FB) summing the OTP-FB.

 FIG. 8 is a diagram for detecting surface heterogeneity in the area of reception points from two fixed bases of vibration sources according to the fourth embodiment of the method for three-dimensional seismic observations.

 FIG. 9 is an example of the location of the bases of the sources of excitation of oscillations for summing the OTP during three-dimensional seismic observations.

 Figure 10 - the manifestation of surface inhomogeneities on the sections of two cubes of total traces of OTP with different base systems with fixed sources (a), the same sections after surface-matched static shifts (b).

 The method according to the first embodiment is illustrated using figures 1-3.

The upper part of Fig. 1 shows an example of an OGT observation system: upon excitation of oscillations by each of the sources S ₁ -S _n, registration is performed by the receivers R _i within the instrument arrangement indicated by a dotted line. Both the sources and the arrangements of the receivers are located on the profile, shifting by a certain step from the source to the source, however, for the convenience of the image, the placement line for each subsequent source is shifted vertically.

For each of the sources, a total trace is formed, obtained by summing the traces with kinematic corrections registered by the receivers indicated by the squares. Summation, as mentioned above, provides an increase in the ratio of the useful signal to the noise level, and, consequently, the reliability of detection and accounting of surface anomalies, as well as data compression, which facilitates the analysis of reflection times. The total paths are shown under each of the oscillation sources S _i in the lower part of figure 1. In the presence of heterogeneity in the upper part of the section (VChR) under the sources of oscillations, delays or advances in time caused by it unambiguously appear at the times of reception of reflected signals from a deep boundary. The heterogeneity is schematically reflected in the graph of the velocity of propagation of oscillations in the upper part of the section (VChR) along the profile placed under the sources. Increasing the speed reduces the signal time. Since the same receivers for each source participate in the summation (for example, four receivers in Fig. 1, which make up one fixed summation base, the shift associated with the receivers remains constant for all total traces.

 Summing within one fixed base FB1 provides only a fragment of the time section of the OTV, for the next source profile (Fig. 2), another base of FB2 receivers should be selected. In Fig. 2, the surface heterogeneity, as in Fig. 1, is reflected in the HFR velocity graph, and the total paths are placed under each source in the lower part of Fig. 2. Since in the example shown in Fig. 2, the first base of receivers lies within the low-speed heterogeneity, and the second base is outside it, then between the corresponding groups of total traces there is a time shift marked as block, since it is the same for the entire block of total traces included into the fragment. This shift is eliminated in the process of determining static corrections by block shifts. A system of fixed bases is selected along the profile, providing a continuous sequence of total traces — a time section. With a regular observation system, the step of the bases can be constant (we denote it by L).

 Similarly, the selection of fixed bases is carried out for receivers of seismic vibrations, while summation for receivers (OTP) is also performed: the oscillations excited by the sources sequentially at the first, second and so on bases are summed.

 The number of total traces that can be obtained from one fixed base depends on the observation system and on the limitations on the range of removals used. In Fig. 3, a summation diagram of a fragment of a time section with one fixed base is shown on a generalized plane for a central 96-channel arrangement of receivers. The total OTP paths for receivers 1-86 are formed from the paths recorded upon excitation at the source location points 38-49. Similarly, the summation for sources 1-86 is performed on receivers 38-49.

 The first base and the entire base system along the profile can be selected with an offset less than the step of the bases L, and as a result, another version of the time section will be obtained. For analysis, at least two systems of summation bases are set that are shifted one relative to the other on the profile by an interval less than L, and the corresponding number of time sections of each type (OTV / OTP) is formed. This allows us to determine the block shifts of the total signals due to shifts between the bases, to separate the surface anomalies from the deep ones, while increasing the reliability and reliability of detecting surface anomalies by screening them at different angles. Anomalies coinciding in time sections obtained from different systems of fixed summation bases are classified as surface, since the depth anomalies in these sections are shifted.

 The arrival times of the reflected waves at points in time sections outside the selected sections of the surface anomalies are approximated by a smooth line and relative to this line, the time shifts of the reflected signals for each source and receiver are determined within the anomalies. These time shifts, determined by different sections, are averaged separately for sources and receivers in each surface position and are used further in the processing of data as static corrections. After the introduction of certain amendments, the operation of summing and obtaining time sections is repeated, and for new time sections the static amendments are checked and refined.

 The method according to the second embodiment consists in the formation of time sections of OTV and OTP with fixing ranges of removal of the source-receiver. In this case, for the OT sections, the oscillations recorded by the receivers at selected distances from the source that are constant along the profile are summed. For the OTP section, the vibrations excited by the sources at selected distances from each receiver are respectively summed. In order to identify surface anomalies and separate them from the deep ones, several sections of OTV, as well as OTP in different ranges of distances are formed. Since the summation ranges are part of the full range of deletions in which the observations were made, such sections are called partial multiple.

The method according to the second embodiment is illustrated with reference to Fig. 4a, which shows the formation of anomalies in the arrival times of reflected waves in the time section of the OTP in the area of an extended surface anomaly. Section OTP involves the summation of the tracks recorded from sources S, located in a given range of distances from the receiver R. In Fig.4A, these sources are conventionally marked with icons at points S ₁ , S ₂ , S ₃ , S ₄ . Schematically, the set of rays from each of the sources S is replaced by a single beam from the middle source. The rays are drawn for receivers at points R ₁ , R ₂ , R ₃ , R ₄ , key for understanding the formation of the line of reflection times t ₀ in the section of the OTP, the shape of which (solid line) is determined by the superposition of two components: static, associated with the points of reception, and components called by the summing base - sources. At position R ₁ , a manifestation of heterogeneity at the points of reception begins (dashed line). At position R _{2, the} sources also go into this zone, which leads to an additional time shift. Behind the position of R _{3, the} time shift is almost doubled. In the region from S ₄ to R _{4, the} heterogeneity is manifested only on the rays incident from the sources. Accordingly, R ₄ is the extreme point of manifestation of heterogeneity. The time difference between the solid and dashed lines t ₀ represents the component associated with the summation base, in this case, with the sources.

 On different variants of partial time-seismic sections of the OTV and OTP sections, the component associated with the summation base is differently superimposed on the desired static shifts. Comparison of sections allows you to identify, evaluate and exclude the influence of this component.

 In FIG. Figure 5 shows temporary seismic sections of the OTP obtained by summing over sources in the three ranges of offsets indicated in the drawing for a profile with two surface inhomogeneities: high and low speed. The temporal amplitude of the low-speed anomaly is slightly less than the high-speed one. The cuts are aligned at the positions of the receivers. It can be seen that the left boundary of the heterogeneities is clearly distinguished by this set of sections. At intervals marked with dashed lines, heterogeneities reappear due to shifts in the downward rays along the positions of the sources. The shift of the component associated with the sources increases with removals, and in the lower section, the influence of anomalies in the receivers and sources is divided.

 The time sections in Fig. 6 were obtained in similar ranges of distances when the receivers were located on the other side of the sources on the profile. The component caused by the summation base — by the sources — is shifted in the opposite direction and the right boundary of the anomalies is clearly defined.

 When comparing the same sections at the average deep positions (average CDP), the surface anomalies are spaced and the deep anomalies coincide, which is used as a sign for separating the anomalies.

 The arrival times of the reflected waves at different time sections combined over the average OGT, with the exception of the selected sections of the surface anomalies and the areas of their manifestation, are approximated by the summation bases by a single smoothed line and relative to this line, the shifts of the reflected signals for each source and receiver are determined within anomalies. When calculating a smooth line, it is advisable to use the available geological data and drilling data on the depth and shape of the boundaries of the layer. The time shifts determined for different sections are averaged separately for sources and receivers at each surface position and are used further in the processing of data as static corrections, which are then refined using the time sections newly obtained with their introduction.

The disadvantage of using fixed summation bases according to the first variant of the method is the need to eliminate shifts between fragments of time sections for different bases, as well as the possibility of the effect of residual kinematic corrections on the reflection times, and when using summation with fixing source removals according to the second variant, the need to identify a variable component related to with heterogeneities on the basis of summation. In many cases, the most reliable results are obtained by the combined use of time sections with fixed summation bases and with fixed ranges of deletions, i.e. the method according to the third embodiment. Comparison of the OTV and OTP sections in different ranges of distances and with fixing the summation bases makes it easier to exclude the component associated with the summation bases, since in the sections with a fixed base this component appears only when moving from one base to another (lateral shift in Fig. 2). As can be seen in fig.4b, when fixing, for example, sources outside the heterogeneity at the points S ₁ , S _{2 the} reflection time T ₀ establishes an undistorted form of the anomaly. Fixed bases, selected at different points relative to the anomaly after its detection by sections with fixed ranges of distances, make it possible to clarify the heterogeneity at different angles of approach of the waves. 7, the same sections as in FIG. 5 in the interval of registration of the upper horizon, are given in the layout with a cut with fixed bases of summation. The influence of the summation bases in this section is manifested in a time shift between fragments of the section obtained from different bases (fragments are separated by a gap). The shape of the anomalies is reproduced undistorted.

 Over the entire set of sections, the shape of the anomalies is established and the time shifts that are used as static corrections are determined as above, according to the first and second options. When aligning the sections along the middle OGT, the observed anomalies do not coincide, which confirms their surface nature.

 According to the fourth embodiment, for the case of spatial observing systems (3D), surface-coordinated summation over the positions of sources and receivers is possible mainly in the version with fixed bases. The principle of fixed bases in the three-dimensional case is illustrated in Fig. 8. For the reception region indicated by the inverted triangles, the summation of oscillations recorded from the oscillation sources included in the first base is made to the left of the surface heterogeneity, and then from the sources of the second base to the right of it. The total OTP traces corresponding to two bases make up two OTP cubes for the marked area. Sections of the obtained cubes of OTP traces along the second line of receivers are shown schematically in the lower left part of Fig. 8. The surface anomaly on the total paths obtained from two different source bases is reflected equally. Deep anomalies on these paths would not coincide, since the reflecting areas for these bases (shaded areas at the reflecting boundary) are spaced.

 In three-dimensional shooting (3D), a system of spatial summation bases is selected to form a complete cube of surface-consistent total OTV / OTP paths over the entire shooting area. Figure 9 presents an example of the selection of bases for summing OTP over the plot of the actual survey. From each source base, a rectangular reception area is illuminated, in the center of which it is located. The frame and bold receiver icons highlight one of these areas.

 In order to detect a surface anomaly, at least two systems of source and / or receiver bases are set that are displaced on the observation surface relative to each other so that different parts of the reflecting boundaries correspond to different base systems, and the corresponding number of cubes of total traces of each type is summed (OTV / OTP). Vertical sections of cubes along the lines of sources / receivers are analyzed. If time shifts coincide on sections of different cubes, anomalies, as well as on 2D profiles, are classified as surface. It is determined, as in the previous versions, the magnitude of the same time cross-sections on the sections of different cubes for each source and receiver, and these shifts are used later in the processing of data as static corrections.

 In FIG. 10a and 10b show an example of analyzed sections of OTP cubes along one line of collection points on a 3D area with the presence of surface inhomogeneities. Two sections along which the correction is performed (Fig. 10a) are obtained with different systems of summation bases. The coincidence of anomalies in both sections allows us to identify them as static. The cuts in fig.10b are the same as in fig.10a, after eliminating the matching anomalies by static shifts, i.e. the introduction of static corrections.

 Thus, there are three options for implementing a method for detecting and quantifying surface anomalies in seismic exploration by profiles (2D) and one in three-dimensional (volumetric) seismic exploration (3D).

 According to the first option, for each receiver, oscillations with initial corrections, excited in groups of sources with fixed positions called aggregation bases evenly spaced along the profile, are summed to obtain temporary seismic sections, and for each source the oscillations recorded by receivers at selected fixed bases are summed up, and each the receiver and the source correspond to at least two total paths belonging to two different summation bases. According to the total paths of the obtained time sections, time anomalies with a length of up to one or two receiver arrays are selected that meet the criterion for the coincidence of distortions - time shifts for different bases and classified on this basis as zones of surface inhomogeneities, while determining the boundaries of the anomalies and the magnitude of time shifts relative to the smoothed time lines the arrival of waves drawn at points outside the anomalous sections, selected taking into account the available data on geological boundaries, and these shifts, we specify e iteratively used to eliminate irregularities affect the times of reflections by entering static corrections.

 According to the second method for detecting and quantifying surface anomalies during seismic exploration by profiles (2D), surface-consistent time sections (OTV and OTP) are obtained by summing for each receiver seismic vibrations with the introduced calculation corrections excited by sources in several (three to four or more , but not less than two) ranges of fixed distances from receivers, and for each source, fluctuations recorded by receivers in selected ranges of fixed distances, with each n at least two total paths belonging to different ranges of distances correspond to the receiver and source; the aggregate total paths (time sections) are combined on the scale of surface positions of sources / receivers and on the scale of depth positions - common depth points (CDPs), highlighting time anomalies with lengths up to the placement length receivers and more, identical in surface positions and not coinciding when combined in deep positions and related on this basis to surface inhomogeneities. Based on the set of different variants of the total paths (time sections), the boundaries of the anomalies and the areas of their repeated manifestation are determined - according to the sources at the time sections of the common points of reception (OTP), according to the receivers at the time sections of the common points of excitation (OTV), with the exception of the sites of repeated manifestation estimate the magnitude of the time shifts on the anomalies relative to the smoothed lines of the times of arrival of the waves drawn at points outside the anomalous sections when comparing the sections along the deep positions, and these shifts nyaemye on set of sections and iteratively refines, used to eliminate the irregularities affect the times of reflections by entering static corrections.

 According to the third method for detecting and quantifying surface anomalies during seismic exploration by profiles (2D), seismic vibrations are summed up with the introduced design corrections to obtain surface-consistent time sections (OTV and OTP), while for each receiver the vibrations excited by sources in several ( three - four or more, but not less than two) ranges of fixed distances from the receivers, and for each source, the oscillations recorded by the receivers in the selected n ranges of fixed deletions, with each receiver and source corresponding to at least two total traces belonging to different ranges of deletions. The sets of total paths (time sections) are combined on a scale of surface positions of sources / receivers and on a scale of depth positions - common depth points (CDPs), highlighting time anomalies extending to receivers or more, identical in surface positions and not matching when aligned in depth positions and related on this basis to surface inhomogeneities, select groups of sources and receivers (fixed summation bases) near the boundaries of the identified anomalies, summarize the oscillations summations induced or recorded on these fixed bases, using the combination of different variants of the total paths (time sections) with both fixed distances and fixed bases, determine the magnitude of the time shifts within the anomalies relative to the smoothed lines of the arrival times of waves that were taken along points outside the anomalous sections along sets of sections combined in deep positions, and these shifts are used to eliminate the influence of inhomogeneities on reflection times by entering static amendments.

 According to the fourth embodiment of the method for detecting and quantifying surface anomalies for the case of three-dimensional (volumetric) seismic exploration (3D), seismic vibrations are summarized with the introduced corrections to obtain cubes of total OTV and OTP traces, while for each receiver the vibrations excited by sources with fixed positions forming fixed summation bases uniformly located over the area, and for each source the oscillations recorded by the receiver are summed at the selected fixed bases, with each receiver and source corresponding to at least two total paths belonging to two different summation bases, anomalies are identified - sections of the distortions of the arrival time of the reflected signals that are the same for different bases of summation, classified according to the criterion for the coincidence of distortions - time shifts at different bases as zones of surface inhomogeneities, the boundaries of the inhomogeneities on the plane and the magnitude of the time shifts within their limits with respect to the smoothness are determined cruise lines arrival times of the reflected waves, carried out by the points is abnormal areas, and these shifts are used to eliminate irregularities affect the times of reflections by entering static corrections.

 The above examples of methods for detecting surface anomalies do not limit the scope of protection, but only confirm the possibility of implementing the claimed methods.

Claims (4)

 1. A method for detecting surface anomalies in seismic exploration according to profiles, which consists in summing up seismic oscillations excited by sources and received by receivers from common points of reception and common points of excitation, to obtain temporary seismic sections along the profile in the form of a set of signals of total paths and carry out correction of these sections by introducing static corrections, while fixed loads are selected from uniformly located along the profile of seismic vibration receivers Py (bases) and for each source summarize the seismic vibrations received by the receivers at the corresponding nearest fixed bases, also select the fixed source bases and for each receiver summarize the seismic vibrations excited by the sources at the corresponding fixed bases, with the specified summation for each receiver and source at least two total paths belonging to two different summation bases spaced along the profile for time s In sections, surface anomalies are distinguished by the sign of coincidence of distortions of the reflection times in time sections related to different summation bases, the boundaries of the anomalies and the magnitude of time shifts within the anomaly are determined relative to the smoothed lines of the times of arrival of reflected waves drawn at points outside the anomalous sections, and these time shifts , averaged over a set of sections, are introduced as static corrections into the obtained seismic data.  2. A method for detecting surface anomalies in seismic exploration by profiles, which consists in summing up seismic vibrations excited by sources and received by receivers from common points of reception and common points of excitation, to obtain temporary seismic sections along the profile in the form of a set of signals of total paths and carry out correction of these sections by entering static corrections, while for fixed receivers evenly spaced along the profile, several fixed ranges of removal are selected to each source of oscillations and summarize for each receiver the oscillations excited by the sources separately in each of the ranges, also summarize for each source the oscillations received by receivers located in the selected ranges of distances from the sources, with this summation, at least two are obtained for each receiver and source total traces related to different fixed ranges of offsets compare the obtained temporary seismic sections on the scale of surface positions - the point of location sources and receivers and on the scale of deep positions - common deep points (CDPs), identify anomalies that coincide in surface positions and do not coincide in depth points, determine the boundaries of the selected sections of the anomaly or anomalies and the magnitude of time shifts by the amount of timing or delay of fluctuations in time sections relative to the smoothed lines of the times of arrival of the waves drawn along points outside the anomalous sections when comparing the sections along the deep positions, and these shifts, averaged over the set of sections, introduced as static corrections to the obtained seismic data.  3. A method for detecting surface anomalies in seismic exploration by profiles, which consists in summing up seismic vibrations excited by sources and received by receivers from common points of reception and common points of excitation, to obtain temporary seismic sections along the profile in the form of a set of signals of total paths and carry out correction of the indicated sections by introducing static corrections, while for the seismic oscillation receivers evenly spaced along the profile, several fixers are selected range of distances to the sources of oscillations and summarize for each receiver the vibrations excited by the sources separately in each of the ranges, also summarize for each source the vibrations received by receivers located in the selected ranges of distances from the sources, with the specified summation, for each receiver and source at least at least two total traces related to different fixed ranges of offsets compare the obtained temporary seismic sections on the surface position scale - at the point of location of sources and receivers and on the scale of deep positions - common deep points (CDPs), anomalies are selected that coincide on surface positions and do not coincide on deep points, determine the boundaries of the selected sections of the anomaly or anomalies, groups are selected near the boundaries of the selected sections with anomalies sources and receivers (fixed summation bases), carry out the summation of oscillations excited by sources or registered by receivers on these fixed bases, according to the set of time sections with both fixed offsets and fixed bases specify the position of the anomalous sections and determine the amount of time shifts (advancing or delayed times of arrival of reflected signals) within the anomalies relative to the smoothed lines of the times of arrival of waves drawn along points outside the anomalous sections along the set of sections combined by deep positions, and these shifts, averaged for different sections, are introduced as static corrections into the obtained seismic data.  4. A method for detecting surface anomalies in three-dimensional (volumetric) seismic exploration, which consists in summing up the total seismic vibrations excited by the sources and received by the receivers with common points of reception and common points of excitation, to obtain cubes of total traces, and carry out data correction by introducing static corrections at that, fixed groups (bases) are selected from sources of oscillations uniformly distributed over the area of oscillations, and for each receiver summation of seismic oscillations is carried out, excited by the sources at the corresponding nearest fixed bases, the fixed base of the receivers is also selected by area and for each source the seismic vibrations received by the receivers at the corresponding fixed bases are summed, with the specified summation, at least two total paths belonging to two different paths are obtained for each receiver and source summing bases, according to the obtained sections of cubes of total traces for different summation bases along the lines of location of sources and receivers Anomalies are distinguished - sections of the reflected time signals shifts that are identical at different bases, which corresponds to zones of surface inhomogeneities, determine the boundaries of the inhomogeneities on the plane and the magnitude of the time shifts of the reflected signals within them relative to the smoothed lines of the times of arrival of reflected waves drawn at points outside the anomalous parts, these shifts are introduced as static corrections into the obtained seismic data.

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