CN105260605A - Three-dimensional seismic data volume processing method, server, client and system - Google Patents

Abstract

Embodiments of the application disclose a three-dimensional seismic data volume processing method, a server, a client and a system. The method comprises: acquiring all data sub-blocks meeting preset requirements in a three-dimension seismic data volume; comparing actually measured data in different sub-blocks with corresponding preset data at the same time so as to determine whether heterogeneous data exist in the three-dimension seismic data volume; and sending a processing result of the heterogeneous data in the three-dimension seismic data volume to the client. By using the technical scheme disclosed by the present application, the heterogeneous data in the three-dimension seismic data volume can be detected, thereby contributing to improvement of the reliability and strictness of subsequent calculated results.

Description

A kind of disposal route of 3-d seismic data set, server, client and system

Technical field

The application relates to oil exploration technology field, particularly a kind of disposal route of 3-d seismic data set, server, client and system.

Background technology

3-d seismic data set is the master data of difference equation application in seismic exploration technique, and it can by carrying out stress and strain model to obtain by 3D seismic data.Along with the requirement of the progress of oil exploration technology and high density exploration, corresponding to the data volume of the 3-d seismic data set of geologic model in continuous increase.The geologic model of one 100 square kilometres, the data volume of 3-d seismic data set can reach more than 100GB.If the stress and strain model precision of 3-d seismic data set increases, so the data volume of 3-d seismic data set will increase with geometric.Because the data volume of 3-d seismic data set is huge, in currently available technology when 3-d seismic data set is visual, all generally suppose that all measured datas in 3-d seismic data set all meet physical attribute feature, and Data Source in actual applications due to 3-d seismic data set is uncertain, or 3-d seismic data set is by the discrete conversion gained of block geologic model, this makes there is the heterogeneous data not meeting physical attribute feature in 3-d seismic data set.These heterogeneous datas may affect the reliability of subsequent calculations result, also may cause larger economic loss.

Summary of the invention

The object of the embodiment of the present application is to provide a kind of disposal route of 3-d seismic data set, server, client and system, to realize the object contributing to the reliability improving subsequent calculations result.

For solving the problems of the technologies described above, the embodiment of the present application provides a kind of disposal route of 3-d seismic data set, server, client and system to be achieved in that

The embodiment of the present application provides a kind of disposal route of 3-d seismic data set, comprising:

Obtain all data sub-block meeting preset requirement in 3-d seismic data set;

Measured data in different pieces of information sub-block and preset data are contrasted simultaneously, to judge whether there is heterogeneous data in described 3-d seismic data set;

Export the result of described 3-d seismic data set, comprise and send described result to client, described result comprises the numerical value of described heterogeneous data, quantity and/or position coordinates.

In one embodiment, in described acquisition 3-d seismic data set, all data sub-block meeting preset requirement comprise:

According to default piecemeal rule, obtained 3-d seismic data set is divided into multiple data sub-block;

The data sub-block meeting preset requirement is chosen from all described data sub-block.

In one embodiment, in described acquisition 3-d seismic data set, all data sub-block meeting preset requirement comprise:

The data sub-block meeting preset requirement is chosen from all data sub-block prestored.

In one embodiment, described all data sub-block store in the following manner:

According to the position coordinates of described data sub-block, all data sub-block are sorted;

According to the sequence of described data sub-block, a point race is carried out to the data sub-block after sequence;

According to point race of described data sub-block, described data sub-block is stored.

In one embodiment, described preset data obtains in the following manner:

Light signal entrained by many obtained light is converted into electric signal;

Described electric signal is utilized to obtain described preset data.

In one embodiment, after judging to there is heterogeneous data in described 3-d seismic data set, described method also comprises:

Add up the quantity of described heterogeneous data.

In one embodiment, after the quantity counting described heterogeneous data, described method also comprises:

The statistical magnitude of described heterogeneous data and predetermined number are contrasted, judges that whether the quality of described 3-d seismic data set is qualified.

In one embodiment, after the quantity counting described heterogeneous data, described method also comprises:

The statistical magnitude of described heterogeneous data is converted to color of image value.

In one embodiment, after judging to there is heterogeneous data in described 3-d seismic data set, described method also comprises:

According to the physical attribute of heterogeneous data, described heterogeneous data is classified.

In one embodiment, after judging to there is heterogeneous data in described 3-d seismic data set, described method also comprises:

The numerical value of described heterogeneous data and predetermined threshold value are contrasted, judges whether to ignore described heterogeneous data.

In one embodiment, described method also comprises:

Obtained data sub-block is stored.

The embodiment of the present application additionally provides a kind of disposal route of 3-d seismic data set, comprising:

The solicited message of analyzing three-dimensional geological data weight is sent to server;

The result of the described 3-d seismic data set that reception server sends, described result is that server is by carrying out contrasting obtaining by the measured data in different pieces of information sub-block and preset data simultaneously;

Show described result, described result comprises the numerical value of described heterogeneous data, quantity and/or position coordinates.

The embodiment of the present application provides a kind of server, and described server comprises:

First acquiring unit, for obtaining all data sub-block meeting preset requirement in 3-d seismic data set;

First contrast unit, for the measured data in different pieces of information sub-block and preset data being contrasted simultaneously, judges whether there is heterogeneous data in described 3-d seismic data set;

Output unit, for exporting the result of described 3-d seismic data set, comprising and sending described result to client.

In one embodiment, described server also comprises:

Conversion unit, for being converted into electric signal by the light signal entrained by many obtained light;

Second acquisition unit, for obtaining described preset data from transformed electric signal.

The embodiment of the present application provides a kind of client, and described client comprises:

Transmitting element, for sending the solicited message of analyzing three-dimensional geological data weight to server;

Receiving element, for the result of heterogeneous data in the described 3-d seismic data set that reception server sends, described result is that server is by carrying out contrasting obtaining by the measured data in different pieces of information sub-block and preset data simultaneously;

Display unit, for showing described result, described result comprises the numerical value of described heterogeneous data, quantity and/or position coordinates.

The embodiment of the present application provides a kind of analytic system of 3-d seismic data set, and described system comprises above-mentioned server and client.

The technical scheme provided from above the embodiment of the present application, the embodiment of the present application obtains all data sub-block meeting preset requirement in 3-d seismic data set; Measured data in different pieces of information sub-block and preset data are contrasted simultaneously, judges whether there is heterogeneous data in described 3-d seismic data set; The result of described 3-d seismic data set is sent to client, described result comprises the numerical value of described heterogeneous data, quantity and/or position coordinates, user is by checking that described result can check the relevant information of heterogeneous data, can select to reject described heterogeneous data in subsequent calculations, this is conducive to the reliability improving subsequent calculations result.

Accompanying drawing explanation

In order to be illustrated more clearly in the embodiment of the present application or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, the accompanying drawing that the following describes is only some embodiments recorded in the application, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.

Fig. 1 is the process flow diagram of an embodiment of the disposal route of a kind of 3-d seismic data set that the application provides.

Fig. 2 is the structural representation of 3-d seismic data set.

Fig. 3 is the schematic diagram with color display heterogeneous data.

Fig. 4 is the schematic diagram with column diagram display heterogeneous data.

Fig. 5 is the process flow diagram of an embodiment of the disposal route of the another kind of 3-d seismic data set that the application provides.

Fig. 6 is the structural representation of the analytic system of a kind of 3-d seismic data set that the application provides.

Fig. 7 is the structural representation of a kind of server that the application provides.

Fig. 8 is the structural representation of a kind of client that the application provides.

Embodiment

The embodiment of the present application provides a kind of disposal route of 3-d seismic data set, server, client and system.

Technical scheme in the application is understood better in order to make those skilled in the art person, below in conjunction with the accompanying drawing in the embodiment of the present application, technical scheme in the embodiment of the present application is clearly and completely described, obviously, described embodiment is only some embodiments of the present application, instead of whole embodiments.Based on the embodiment in the application, those of ordinary skill in the art are not making the every other embodiment obtained under creative work prerequisite, all should belong to the scope of the application's protection.

Be described in detail below in conjunction with the disposal route of accompanying drawing to the 3-d seismic data set described in the application.Although this application provides the method operation steps as described in following embodiment or process flow diagram, based on conventional or more or less operation steps can be comprised in the process without the need to performing creative labour.Logicality does not exist in necessary causal step, the execution sequence of these steps is not limited to the execution sequence that the embodiment of the present application provides.When the device in practice of described method or end product perform, can perform or executed in parallel according to embodiment or method shown in the drawings order.

Below based on server, composition graphs 1 illustrates the method flow diagram of an embodiment of the disposal route of a kind of 3-d seismic data set in the application.The method comprises:

S110: server obtains the data sub-block meeting preset requirement in 3-d seismic data set.

Server can obtain in 3-d seismic data set based on trigger condition the data sub-block meeting preset requirement.Described trigger condition can be the solicited message receiving the analyzing three-dimensional geological data weight that client sends; Also it can be the time meeting the data sub-block of preset requirement in default acquisition 3-d seismic data set.Described request information can wish the relevant information of geological data in the 3-d seismic data set analyzed containing user, the positional information of such as geological data and/or physical attribute information etc.Described preset requirement can be described request information.

Described 3-d seismic data set can be the set by carrying out the series of discrete data point that stress and strain model obtains to the geological data collected.Each data point (i.e. net point) can record physical property data and other data such as velocity of longitudinal wave, shear wave velocity and rock density.3-d seismic data set represents with coordinate (X, Y, Z) usually, and wherein, X, Y represent planimetric coordinates, and Z represents the longitudinal degree of depth in underground.Described 3-d seismic data set often has a large amount of grid cells, and such as nx × ny × nz=5120 × 5040 × 550 grid cell, each grid cell can have the summit be made up of four data points.Fig. 2 shows the structural representation of 3-d seismic data set, and wherein ix, iy, iz are respectively the length of a grid cell, width and the degree of depth.

Described 3-d seismic data set can obtain in the following manner: server can receive the 3-d seismic data set that client sends; The solicited message that server also can send according to client, calls the 3-d seismic data set prestored.

Described data sub-block can be that server is obtained by direct mode of described 3-d seismic data set being carried out piecemeal, also can be that server is obtained by the mode of the data sub-block calling the described 3-d seismic data set prestored.

In one embodiment, described server obtains by direct mode of described 3-d seismic data set being carried out piecemeal the data sub-block meeting solicited message and can comprise the following steps:

S111: obtained 3-d seismic data set, according to default piecemeal rule, is divided into multiple data sub-block by server.

After acquisition 3-d seismic data set, obtained 3-d seismic data set according to default piecemeal rule, can be divided into multiple data sub-block by server.Described default piecemeal rule can refer to the quantity of the data sub-block be divided into by described 3-d seismic data set, size and memory location etc.Described default piecemeal rule can be that client sends, and also can pre-set.

In one embodiment, server can be split obtained 3-d seismic data set according to the data volume of 3-d seismic data set, storage space (such as, the remaining space of each physical hard disk) and user's request.Such as, the data volume size of 3-d seismic data set is 100GB, and storage space is 2 physical hard disks, and each physical hard disk has 5 disks; User's request comprises and being stored in 4 disks by described 3-d seismic data set, pays the utmost attention to the Z-direction coordinate of the data at each net point place in 3-d seismic data set.Server can by analyzing the performance of described physical hard disk and Logical Disk and remaining space, described 3-d seismic data set can be divided into 12 data sub-block, each disk can store 3 data sub-block, wherein the size of data of 8 data sub-block is 8G, and the size of data of residue 4 data sub-block is 9G.

S112: server chooses all satisfactory data sub-block from described multiple data sub-block simultaneously.

After described 3-d seismic data set is divided into multiple data sub-block, server can choose all satisfactory data sub-block from obtained all data sub-block simultaneously.Containing the geological data indicating detection in described request information in selected data sub-block.Each data sub-block can contain multiple section, and selected data sub-block has common section.

In another embodiment, server can obtain by the mode of the data sub-block calling the described 3-d seismic data set prestored the data sub-block meeting solicited message.Concrete, server according to the relevant information of described data sub-block, can search corresponding data sub-block in a database, and calls found data sub-block.

Data sub-block in database can store in the following manner:

First, server according to received instruction, can define the piecemeal coordinate system of described data sub-block.In described piecemeal coordinate system, coordinate unit can be grid number, i.e. Grid dimension; Fix name can be row, column, the degree of depth, can fixedly be mapped to Y-axis, X-axis and Z axis respectively.

Then, server can sort to described data sub-block.Server can according to the coordinate of described data sub-block in described piecemeal coordinate system, the coded sequence of the coordinate of described data sub-block is set, such as, the coding of described data sub-block can be set according to the order of the Z axis coordinate of described data sub-block, X-axis coordinate and Y-axis coordinate; Then Morton (Morton) can be utilized to encode by the coordinate conversion of described data sub-block be the Z sequence (i.e. Morton sequence) of one dimension, sort according to changed Z sequence.Such as, described 3-d seismic data set has 5120 grid cells in X-direction, Y direction has 5040 grid cells and Z-direction to have 1100 grid cells; Described 3-d seismic data set has been divided into 12 data sub-block, according to the grid cell situation of all directions, described 3-d seismic data set can be divided into 2 data sub-block in Z-direction, X-direction is divided into 3 data sub-block and Y direction is divided into 2 data sub-block.Therefore, the Morton encoding model of data sub-block can be the binary coding of yy.xx.zz.The numbering of data sub-block can be expressed as follows: X-direction is: 0, and 1,2; Y direction is: 0, 1; Z-direction is: 0,1; Described data sub-block can according to sorting as follows:

Finally, server can store the data sub-block after sequence.After sorting to data sub-block, the data sub-block after sequence can be carried out a point race by server, and described data sub-block is divided into different data block races according to coordinate position, and the digital sub-block that wherein coordinate position is adjoining forms a data block race; Then the data sub-block belonging to same data block race is stored in same position, different pieces of information block race is stored in different positions.Described different position can refer to the different disk in same hard disk, also can refer to different hard disks.Such as, be encoded to 00 00 00 00, 00 00 01 00 He 01 00 00 0the data sub-block of 0 can be stored in the first disk (being namely positioned at the disk of a physical hard disk outermost subregion); Be encoded to 00 00 00 01, 00 00 01 01 He 01 00 00 0the data sub-block of 1 can be stored in second disk; Be encoded to 00 00 00 10, 00 00 01 10 He 01 00 00 1the data sub-block of 0 can be stored in the 3rd disk; 00 00 00 11, 00 00 01 11 He 01 00 00 1the data sub-block of 1 can be stored in the 4th disk (being namely positioned at the disk of this physical hard disk subregion).

By this step, server can realize the parallel memorizing to multiple data sub-block, and this can be conducive to the efficiency improving subsequent calculations.

S120: the measured data in different pieces of information sub-block contrasts with corresponding preset data by server simultaneously, judges whether there is heterogeneous data in described 3-d seismic data set.

After getting all satisfactory data sub-block, the measured data at respective grid points place in obtained all data sub-block and preset data can contrast by server simultaneously; Also can the measured data at respective grid points place in the some data sub-block in obtained all data sub-block and preset data be contrasted simultaneously simultaneously; Judge whether there is heterogeneous data in described 3-d seismic data set.Contrast in data sub-block exist different from preset data have a measured data time, can judge to there is heterogeneous data in described 3D seismic data; When contrasting the measured data in each data sub-block and being identical with preset data, can judge to there is not heterogeneous data in described 3D seismic data.

Described measured data can be obtained by actual measurement, and it can be the physical attribute data such as velocity of longitudinal wave, shear wave velocity and density.Described preset data can be the physical attribute data that client sends; Also can be the physical attribute data of server by light signal is converted into electric signal to obtain.Concrete, the multiple light signal entrained by the light that self can send by server or the extraneous multiple light signals sent are converted into electric signal simultaneously; Then preset data is obtained according to transformed electric signal.Preset data corresponding to each data sub-block can be different, also can be identical.

Described heterogeneous data is the measured data different from preset data, such as, and the native to this world physical property data such as 3-D seismics superposition offset data.Measured data is different from preset data can refer to that the numerical value of the numerical value of this measured data and preset data is different, such as, preset data is velocity of longitudinal wave, its numerical value can be 1500m/s, 2000m/s, 3400m/s, 4000m/s and 4700m/s, and to survey velocity of longitudinal wave be 3500m/s, so this velocity of longitudinal wave is heterogeneous data.Measured data is different from preset data can refer to that the physical attribute of the physical attribute of this measured data and preset data is different, such as preset data is velocity of longitudinal wave and shear wave velocity, and measured data is 3-D seismics superposition offset data, so 3-D seismics superposition offset data is heterogeneous data.

In one embodiment, server, after judging to there is heterogeneous data in described 3-d seismic data set, can add up the quantity of described heterogeneous data, then added up quantity and predetermined number can be contrasted.When contrasting added up quantity and being less than predetermined number, the result representing that described 3-d seismic data set is up-to-standard can be obtained; When contrasting added up quantity and being greater than predetermined number, the result representing that described 3-d seismic data set is off quality can be obtained.In one embodiment, described quantity, after the quantity counting described heterogeneous data, can be converted to color of image value by server.

In one embodiment, described heterogeneous data, after judging to there is heterogeneous data in described 3-d seismic data set, can be classified according to the physical attribute of heterogeneous data by server.Such as, by all positions heterogeneous data be the velocity of longitudinal wave of different numerical value be divided into a class, be that being divided into of the shear wave velocity of different numerical value is another kind of by all positions heterogeneous data.After to heterogeneous data classification, further the heterogeneous data in same class can also be divided into groups, such as heterogeneous data is velocity of longitudinal wave, and can be that the velocity of longitudinal wave of 5000m/s ~ 5100m/s is divided into one group by numerical value, be that the velocity of longitudinal wave of 5200m/s ~ 5300m/s is divided into another group by numerical value.After to described heterogeneous data after classification and/or grouping, server can also add up the quantity of heterogeneous data in each classification and/or grouping.

In one embodiment, server is after judging to there is heterogeneous data in described 3-d seismic data set, the numerical value of described heterogeneous data and predetermined threshold value can be contrasted, when the numerical value contrasting described heterogeneous data is less than predetermined threshold value, this heterogeneous data can be ignored; When the numerical value contrasting described heterogeneous data is greater than predetermined threshold value, the result can not ignoring this heterogeneous data can be obtained.Such as, heterogeneous data is rock density, and its value is 3.5t/m ³, predetermined threshold value is 4.0t/m ³, then can ignore this heterogeneous data, be regarded as satisfactory measured data.

In this step, the measured data in different pieces of information sub-block and preset data contrast by server simultaneously, and this is conducive to improving the efficiency detecting heterogeneous data in 3-d seismic data set.

S130: server exports the result of described 3-d seismic data set.

After contrasting all data sub-block, server can send the result of described 3-d seismic data set quality to client.Described result can represent that whether the quality of described 3-d seismic data set is qualified; Also the numerical value and/or positional information etc. of heterogeneous data in described 3-d seismic data set can be comprised.Described result also can also comprise the statistics in previous step, the quantity of such as heterogeneous data.

Client can show described result according to default display mode after receiving the result of server transmission.Such as, the heterogeneous data of different physical attribute and/or different numerical values recited can be shown by different colors, as shown in Figure 3.White represents that this net point place does not exist heterogeneous data in figure 3, and grey represents that this net point place exists heterogeneous data; Gray scale is darker, represents that the numerical value of heterogeneous data is larger.In addition, also described heterogeneous data can be shown by the form of histogram, as shown in Figure 4.As can be seen from Figure 4, the quantity that numerical value is less than the heterogeneous data of 10 is maximum, and numerical value is the minimum number of the heterogeneous data of 20.

Before or after server sends described result to client, server can also store described result.

By this step, the geological data that can adopt in the heterogeneous data that user can select to check, the display mode of heterogeneous data and subsequent calculations, this can improve the visuality of 3-d seismic data set, be conducive to improving Consumer's Experience effect, be also conducive to the reliability improving subsequent calculations result.

Can be found out by above-mentioned steps, the embodiment of the present application according to received solicited message, obtains the data sub-block corresponding to 3-d seismic data set by server; Measured data in different pieces of information sub-block and preset data contrast by server simultaneously, judge whether there is heterogeneous data in described 3-d seismic data set; Server sends the result of described 3-d seismic data set quality to client, user can know the relevant information of heterogeneous data existing in described 3-d seismic data set by described result, user also can select to reject described heterogeneous data in subsequent calculations, this achieve the object being conducive to the reliability improving subsequent calculations result, be also conducive to reducing subsequent calculations workload and improving subsequent calculations efficiency.

In one embodiment, for the ease of subsequent calculations, described method can also comprise:

S140: the data sub-block of described 3-d seismic data set stores by server.

After the data sub-block obtaining described 3-d seismic data set, data sub-block after sequence can be carried out a point race by server, described data sub-block is divided into different data block races according to coordinate position, and the digital sub-block that wherein coordinate position is adjoining forms a data block race; Then the data sub-block belonging to same data block race is stored in same position, different pieces of information block race is stored in different positions.

After storing data sub-block, server can also be named the memory location of described data sub-block, and records the relevant information of each data sub-block, such as, and the quantity of data sub-block, size and/or positional information etc.

The concrete implementation of this step can associated description in refer step S110, no longer superfluously to chat at this.

It should be noted that, the execution sequence between this step and step S120-S130 is restriction not.

Below based on client, composition graphs 5 illustrates the disposal route of a kind of 3-d seismic data set that the embodiment of the present application provides.The method comprises:

S210: user end to server sends the solicited message of the quality of analyzing three-dimensional seismic data volume.

Client can send the solicited message of analyzing three-dimensional geological data weight to server based on data analysis task.Described request information can wish the relevant information of geological data in the 3-d seismic data set analyzed containing user, the positional information of such as geological data and/or physical attribute information etc.

S220: the result of the described 3-d seismic data set that client reception server sends, described result is that server is by carrying out contrasting obtaining by the measured data in different pieces of information sub-block and preset data simultaneously.

After server transmission request information, client can the result of heterogeneous data in the described 3-d seismic data set that sends of reception server, and described result is that server is by carrying out contrasting obtaining by the measured data in different pieces of information sub-block and preset data simultaneously.Server obtains the detailed process of described result can refer step S120, no longer superfluously to chat at this.

S230: client shows described result, described result comprises the numerical value of described heterogeneous data, quantity and/or position coordinates.

After the result receiving server transmission, client according to default display mode, can show described result, so that user checks.

The heterogeneous data of different physical attribute and/or different numerical values recited can show by different colors by client; Also described heterogeneous data can be shown by the form of histogram.

Pass through above-mentioned steps, user can know the relevant information of heterogeneous data existing in described 3-d seismic data set by shown result, user also can select to reject described heterogeneous data in subsequent calculations, this achieve the object being conducive to the reliability improving subsequent calculations result, be also conducive to reducing subsequent calculations workload and improving subsequent calculations efficiency.

The embodiment of the present application additionally provides the analytic system of another kind of 3-d seismic data set, as shown in Figure 6.This system comprises server 610 and client 620.Wherein, server 610 may be used for the solicited message receiving client transmission, can also be used for obtaining data sub-block corresponding in 3-d seismic data set; Also may be used for the measured data in different pieces of information sub-block and preset data being carried out parallel contrast, judge whether there is heterogeneous data in described 3-d seismic data set; Also can also be used for sending to client the result corresponding to described heterogeneous data.In addition, server 610 can also be used for storing described data sub-block and result.Client 620 may be used for the solicited message sending analyzing three-dimensional geological data weight to server; Also may be used for the result of heterogeneous data in the described 3-d seismic data set of reception server transmission; Can also be used for showing described result.

The embodiment of the present application additionally provides a kind of server, as shown in Figure 7.This server can comprise: acquiring unit 710, first contrasts unit 720 and output unit 730.Wherein, acquiring unit 710 may be used for obtaining all data sub-block meeting preset requirement in 3-d seismic data set; First contrast unit 720 may be used for the measured data in different pieces of information sub-block and preset data to contrast simultaneously, judges whether there is heterogeneous data in described 3-d seismic data set; Transmitting element 730 may be used for the result exporting described 3-d seismic data set, comprises for client transmission processing result.

In one embodiment, acquiring unit 710 can comprise:

Piecemeal subelement, may be used for, according to default piecemeal rule, obtained 3-d seismic data set being divided into multiple data sub-block;

First chooses subelement, may be used for choosing the data sub-block meeting preset requirement from all described data sub-block.

In one embodiment, acquiring unit 710 can also comprise:

Second chooses subelement, may be used for choosing the data sub-block meeting preset requirement from all data sub-block prestored.

In one embodiment, described server can also comprise:

Conversion unit, the multiple light signals that may be used for the multiple light signal entrained by light or the extraneous transmission self sent are converted into electric signal simultaneously;

Second acquisition unit, may be used for obtaining preset data according to transformed electric signal.

In one embodiment, described server can also comprise statistic unit, and it may be used for the quantity of adding up described heterogeneous data.

In one embodiment, described server can also comprise the second contrast unit, and it may be used for the statistical magnitude of described heterogeneous data and predetermined number to contrast, and judges that whether the quality of described 3-d seismic data set is qualified.

In one embodiment, described server can also comprise converting unit, and it may be used for the statistical magnitude of described heterogeneous data to be converted to color of image value.

In one embodiment, described server can also comprise taxon, and it may be used for the physical attribute according to heterogeneous data, is classified by described heterogeneous data.

In one embodiment, described server can also comprise the 3rd contrast unit, and it may be used for the numerical value of described heterogeneous data and predetermined threshold value to contrast, and judges whether to ignore described heterogeneous data.

In one embodiment, described server can also comprise storage unit, and it may be used for storing obtained data sub-block and result.

The embodiment of the present application additionally provides a kind of client, as shown in Figure 8.This client can comprise:

Transmitting element 810, may be used for the solicited message sending analyzing three-dimensional geological data weight to server;

Receiving element 820, may be used for the result of the described 3-d seismic data set that reception server sends, described result can be that server is by carrying out contrasting obtaining by the measured data in different pieces of information sub-block and preset data simultaneously;

Display unit 830, may be used for showing described result, and described result can comprise the numerical value of described heterogeneous data, quantity and/or position coordinates.

System, device or unit that above-described embodiment is illustrated, specifically can be realized by computer chip or entity, or be realized by the product with certain function.

For convenience of description, various unit is divided into describe respectively with function when describing above device.Certainly, the function of each unit can be realized in same or multiple software and/or hardware when implementing the application.

The software module that method described in the embodiment of the present invention or the step of algorithm directly can embed hardware, processor performs or the combination of both.Software module can be stored in the storage medium of other arbitrary form in RAM storer, flash memory, ROM storer, eprom memory, eeprom memory, register, hard disk, moveable magnetic disc, CD-ROM or this area.Exemplarily, storage medium can be connected with processor, with make processor can from storage medium reading information, and write information can be deposited to storage medium.Alternatively, storage medium can also be integrated in processor.Processor and storage medium can be arranged in ASIC, and ASIC can be arranged in user terminal.Alternatively, processor and storage medium also can be arranged in the different parts in user terminal.

In one or more exemplary design, the above-mentioned functions described by the embodiment of the present invention can realize in the combination in any of hardware, software, firmware or this three.If realized in software, these functions can store on the medium with computer-readable, or are transmitted on the medium of computer-readable with one or more instruction or code form.Computer readable medium comprises computer storage medium and is convenient to make to allow computer program transfer to the telecommunication media in other place from a place.Storage medium can be that any general or special computer can the useable medium of access.Such as, such computer readable media can include but not limited to RAM, ROM, EEPROM, CD-ROM or other optical disc storage, disk storage or other magnetic storage device, or other anyly may be used for carrying or store the medium that can be read the program code of form with instruction or data structure and other by general or special computer or general or special processor.In addition, any connection can be properly termed computer readable medium, such as, if software is by a concentric cable, fiber optic cables, twisted-pair feeder, Digital Subscriber Line (DSL) or being also comprised in defined computer readable medium with wireless way for transmittings such as such as infrared, wireless and microwaves from a web-site, server or other remote resource.Described video disc (disk) and disk (disc) comprise Zip disk, radium-shine dish, CD, DVD, floppy disk and Blu-ray Disc, and disk is usually with magnetic duplication data, and video disc carries out optical reproduction data with laser usually.Above-mentioned combination also can be included in computer readable medium.

Each embodiment in this instructions all adopts the mode of going forward one by one to describe, between each embodiment identical similar part mutually see, what each embodiment stressed is the difference with other embodiments.Especially, for system embodiment, because it is substantially similar to embodiment of the method, so description is fairly simple, relevant part illustrates see the part of embodiment of the method.

Although depict the application by embodiment, those of ordinary skill in the art know, the application has many distortion and change and do not depart from the spirit of the application, and the claim appended by wishing comprises these distortion and change and do not depart from the spirit of the application.

Claims (16)

1. a disposal route for 3-d seismic data set, is characterized in that, comprising:

Obtain all data sub-block meeting preset requirement in 3-d seismic data set;

Measured data in different pieces of information sub-block is contrasted with corresponding preset data simultaneously, to judge whether there is heterogeneous data in described 3-d seismic data set;

Export the result of described 3-d seismic data set, comprise and send described result to client, described result comprises the numerical value of described heterogeneous data, quantity and/or position coordinates.

2. method according to claim 1, is characterized in that, in described acquisition 3-d seismic data set, all data sub-block meeting preset requirement comprise:

According to default piecemeal rule, obtained 3-d seismic data set is divided into multiple data sub-block;

The data sub-block meeting preset requirement is chosen from all described data sub-block.

3. method according to claim 1, is characterized in that, in described acquisition 3-d seismic data set, all data sub-block meeting preset requirement comprise:

The data sub-block meeting preset requirement is chosen from all data sub-block prestored.

4. method according to claim 3, is characterized in that, described all data sub-block store in the following manner:

According to the position coordinates of described data sub-block, all data sub-block are sorted;

According to the sequence of described data sub-block, a point race is carried out to the data sub-block after sequence;

According to point race of described data sub-block, described data sub-block is stored.

5. method according to claim 1, is characterized in that, described preset data obtains in the following manner:

Light signal entrained by many obtained light is converted into electric signal;

Described preset data is generated according to transformed electric signal.

6. method according to claim 1, is characterized in that, after judging to there is heterogeneous data in described 3-d seismic data set, described method also comprises:

Add up the quantity of described heterogeneous data.

7. method according to claim 6, is characterized in that, after the quantity counting described heterogeneous data, described method also comprises:

The statistical magnitude of described heterogeneous data and predetermined number are contrasted, judges that whether the quality of described 3-d seismic data set is qualified.

8. method according to claim 6, is characterized in that, after the quantity counting described heterogeneous data, described method also comprises:

The statistical magnitude of described heterogeneous data is converted to color of image value.

9. method according to claim 1, is characterized in that, after judging to there is heterogeneous data in described 3-d seismic data set, described method also comprises:

According to the physical attribute of heterogeneous data, described heterogeneous data is classified.

10. method according to claim 1, is characterized in that, after judging to there is heterogeneous data in described 3-d seismic data set, described method also comprises:

The numerical value of described heterogeneous data and predetermined threshold value are contrasted, judges whether to ignore described heterogeneous data.

11. methods according to claim 1, is characterized in that, described method also comprises:

Obtained data sub-block is stored.

The disposal route of 12. 1 kinds of 3-d seismic data sets, is characterized in that, comprising:

The solicited message of analyzing three-dimensional geological data weight is sent to server;

The result of the described 3-d seismic data set that reception server sends, described result is that server is by carrying out contrasting obtaining by the measured data in different pieces of information sub-block and preset data simultaneously;

Show described result, described result comprises the numerical value of described heterogeneous data, quantity and/or position coordinates.

13. 1 kinds of servers, is characterized in that, described server comprises:

First acquiring unit, for obtaining all data sub-block meeting preset requirement in 3-d seismic data set;

First contrast unit, for contrasting the measured data in different pieces of information sub-block and preset data, to judge simultaneously

State in 3-d seismic data set and whether there is heterogeneous data;

Output unit, for exporting the result of described 3-d seismic data set, comprises for sending described result to client.

14. servers according to claim 13, is characterized in that, described server also comprises:

Conversion unit, for being converted into electric signal by the light signal entrained by many obtained light;

Second acquisition unit, for obtaining described preset data from transformed electric signal.

15. 1 kinds of clients, is characterized in that, described client comprises:

Transmitting element, for sending the solicited message of analyzing three-dimensional geological data weight to server;

Receiving element, for the result of the described 3-d seismic data set that reception server sends, described result is that server is by carrying out contrasting obtaining by the measured data in different pieces of information sub-block and preset data simultaneously;

Display unit, for showing described result, described result comprises the numerical value of described heterogeneous data, quantity and/or position coordinates.

The analytic system of 16. 1 kinds of 3-d seismic data sets, is characterized in that, described system comprises server as described in claim 13 or 14 and client as claimed in claim 15.