CN117891886A - Rapid mapping method for route geological survey - Google Patents

Abstract

The invention discloses a quick mapping method of a route geological survey, which comprises the following steps: acquiring an original route geological survey of a target area; taking the original route geological survey as a basic survey, and storing the basic survey into a first storage area; acquiring a plurality of updated route geological survey graphs of a target area, wherein the updated route geological survey graphs are obtained by re-surveying the target area by a plurality of survey groups; and comparing each updated route geological survey of the plurality of updated route geological survey of the target area to determine a target updated route geological survey. The method solves the technical problems of low accuracy and low precision of the route geological survey shortcut generated by the prior art.

Description

Rapid mapping method for route geological survey

Technical Field

The invention relates to the technical field of route geological survey, in particular to a quick map forming method of a route geological survey.

Background

At present, a route geological survey map is obtained by processing remote sensing images shot by remote sensing satellites by explorators, dividing the processed remote sensing images, simulating a route by a computer simulation of the divided remote sensing images, and generating a quick screenshot of the route geological survey map by the route geological survey map through the existing mapping technology.

Disclosure of Invention

The embodiment of the invention provides a rapid mapping method for a route geological survey map, which aims to solve the technical problems of low precision and accuracy of the rapid map of the route geological survey generated in the prior art.

According to an aspect of the embodiment of the present invention, there is provided a rapid mapping method for a route geological survey, which may include: acquiring an original route geological survey of a target area; taking the original route geological survey as a basic survey, and storing the basic survey into a first storage area; acquiring a plurality of updated route geological survey graphs of a target area, wherein the updated route geological survey graphs are obtained by re-surveying the target area by a plurality of survey groups; comparing each updated route geological survey of the plurality of updated route geological survey of the target area, and determining a target updated route geological survey; comparing the geological survey map of the target updating route with the basic survey map to obtain a target comparison result; and when the target comparison result is within the preset threshold range, generating a shortcut icon by updating the route geological survey map with the target.

Optionally, the method further comprises: determining a first hash value of the basic survey map and a second hash value of the first storage area through a hash function; when the basic investigation diagram is called, judging whether the hash value of the input first storage area is correct, when the hash value of the input first storage area is correct, judging whether the hash value of the input basic investigation diagram is correct, and when the hash value of the input basic investigation diagram is correct, obtaining the basic investigation diagram.

Optionally, comparing each of the plurality of updated route geological survey maps of the target area to determine a target updated route geological survey map, including: determining any one of the plurality of updated route geological survey maps as a first updated route geological survey map; calculating a plurality of Euclidean distances between other updated route geological survey graphs of the plurality of updated route geological survey graphs except the first updated route geological survey graph and the first updated route geological survey graph; determining a minimum value in the plurality of Euclidean distances as a first Euclidean distance; and determining the updated route geological survey corresponding to the first Euclidean distance as a target updated route geological survey.

Optionally, calculating a plurality of euclidean distances between other updated route geological survey of the plurality of updated route geological survey graphs, except the first updated route geological survey, and the first updated route geological survey, comprising: determining longitude and latitude information of each address in the plurality of updated route geological survey; calculating the Euclidean distance between the longitude and latitude information of each address of each updated route geological survey of other updated route geological survey of the plurality of updated route geological survey graphs except the first updated route geological survey and the longitude and latitude information of each address of the first updated route geological survey; and accumulating and summing the Euclidean distances of each address of each of the other updated route geological survey maps except the first updated route geological survey map in the updated route geological survey maps to obtain the Euclidean distances of each of the other updated route geological survey maps except the first updated route geological survey map in the updated route geological survey maps.

Optionally, comparing the target updated route geological survey with the basic survey to obtain a target comparison result, including: and comparing the longitude and latitude information of each address in the target updating route geological survey with the longitude and latitude information of each address in the basic survey, and comparing the route of the target updating route geological survey with the route of the basic survey when the first comparison is passed, so as to obtain a target comparison result.

Optionally, performing first comparison between the latitude and longitude information of each address in the geological survey of the target update route and the latitude and longitude information of each address in the basic survey includes: calculating the Euclidean distance between the longitude and latitude information of each address in the geological survey of the target updating route and the longitude and latitude information of each address in the basic survey; accumulating and summing the Euclidean distance of the longitude and latitude information of each address in the target updating route geological survey to obtain a target Euclidean distance; and when the target Euclidean distance is smaller than the preset Euclidean distance, the first comparison is passed.

Optionally, the method further comprises: and when the target Euclidean distance is greater than or equal to the preset Euclidean distance, the first comparison is not passed, and the generation of the shortcut icon by the target updating route geological survey is forbidden.

Optionally, the method further comprises: and when the target comparison result is not in the preset threshold range, prohibiting the target updating route geological survey from generating a shortcut icon.

In the embodiment of the invention, the original route geological survey of the target area is obtained; taking the original route geological survey as a basic survey, and storing the basic survey into a first storage area; acquiring a plurality of updated route geological survey graphs of a target area, wherein the updated route geological survey graphs are obtained by re-surveying the target area by a plurality of survey groups; comparing each updated route geological survey of the plurality of updated route geological survey of the target area, and determining a target updated route geological survey; comparing the geological survey map of the target updating route with the basic survey map to obtain a target comparison result; when the target comparison result is within the preset threshold value range, the target is updated to generate the shortcut icon, so that the technical problem that the accuracy and the precision of the generated route geological survey shortcut map are low in the prior art is solved, and the technical effect of improving the accuracy and the precision of the generated route geological survey shortcut map is achieved.

The invention has the advantages that:

compared with the prior art, the method and the device have the advantages that the multiple updated route geological survey maps of the target area are obtained, every two updated route geological survey maps are calculated to obtain the target updated route geological survey map, the target updated route geological survey map is calculated with the basic survey map to obtain the target comparison result, when the target comparison result is within the preset threshold range, the target updated route geological survey map is generated to be a shortcut icon, the shortcut icon of the route geological survey map is obtained through double calculation, and the accuracy and the precision of the generated route geological survey shortcut map are improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and together with the description serve to explain the invention and do not constitute a limitation on the invention. In the drawings:

FIG. 1 is a flow chart of a route geological survey shortcut mapping method in accordance with an embodiment of the present invention;

FIG. 2 is a block diagram of a route geological survey shortcut mapping system in accordance with an embodiment of the present invention.

Detailed Description

In order that those skilled in the art will better understand the present invention, a technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, shall fall within the scope of the invention.

It should be noted that the terms "first," "second," and the like in the description and the claims of the present invention and the above-described drawings are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the terms so used are interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Description of related Art terms:

hash (Hash) functions. It is a one-way cryptosystem, i.e. it is an irreversible mapping from plaintext to ciphertext, with only encryption and no decryption. Meanwhile, the hash function can obtain the output with fixed length after the input with any length is changed. This unidirectional feature of the hash function and the fixed length of the output data enable it to generate messages or data.

Sea distance: in information coding, the coding of different bits on corresponding bits of two legal codes is called code distance, also called Hamming distance. Examples are as follows: 10101 and 00110, the first, fourth and fifth bits are different from the first bit in sequence, and the Hamming distance is 3. The number of bits with different values of the corresponding bits of the two codewords is called the hamming distance of the two codewords. The minimum value of the hamming distance of any two codewords in an active set of codes is called the hamming distance of the set of codes. In information coding, the coding of different bits on corresponding bits of two legal codes is called code distance, also called Hamming distance. Error detection and correction for coding in order to detect d errors, a coding scheme with a hamming distance of d+1 is required. Because in such a coding scheme it is not possible to adapt one valid codeword to another one by d 1-bit errors. When the receiving party sees an invalid codeword, it knows that a transmission error has occurred. Similarly, in order to correct d errors, a coding scheme with a distance 2d+1 is required, because in such a coding scheme, the distance between legal codewords is far enough, so that even if d-bit changes occur, the original codeword is closest to it, so that the original codeword can be determined, and the purpose of error correction is achieved. One method of calculating the hamming distance is to perform an exclusive or (xor) operation on two bit strings and calculate the number of 1 s in the exclusive or operation result. For example, 110 and 011, which are xored as a result of:the exclusive or result contains two 1 s, so the hamming distance between 110 and 011 is equal to 2.

Example 1

According to an embodiment of the present invention, a method for rapid mapping of a route geological survey is provided, it being noted that the steps shown in the flowchart of the drawing may be performed in a computer system containing at least one set of computer executable instructions, and although a logical order is shown in the flowchart, in some cases the steps shown or described may be performed in an order different from that shown or described herein.

FIG. 1 is a flow chart of a method for rapid mapping of a route geological survey, according to an embodiment of the invention, as shown in FIG. 1, the method may include the steps of:

step S101, an original route geological survey of a target area is obtained.

In the technical solution provided in the above step S101 of the present invention, an original route geological survey map corresponding to the target area is obtained, where the original route geological survey map includes multiple geology of the target area, and the multiple geology includes lakes, hillsides, and the like, which are not limited specifically and only illustrated herein.

Step S102, taking the original route geological survey as a basic survey, and storing the basic survey into a first storage area.

In the technical scheme provided in the step S102, the original route geological survey is used as the basic survey, and the basic survey is stored in the first storage area.

Step S103, a plurality of updated route geological survey graphs of the target area are obtained, wherein the updated route geological survey graphs are obtained by re-surveying the target area through a plurality of survey groups.

In the technical scheme provided in the step S103, a plurality of survey groups shoot the target area, draw a new updated route geological survey map, and obtain a plurality of updated route geological survey maps.

Step S104, each updated route geological survey of the plurality of updated route geological surveys of the target area is compared, and a target updated route geological survey is determined.

In the technical scheme provided in the step S104, the euclidean distance between every two updated route geological survey maps in the plurality of updated route geological survey maps of the target area is calculated, and the target updated route geological survey map is obtained according to the plurality of euclidean distances.

Step S105, comparing the geological survey of the target updating route with the basic survey to obtain a target comparison result.

In the technical scheme provided in the step S105, the euclidean distance between the geological survey map and the basic survey map of the target updated route is calculated to obtain the target euclidean distance, and when the target euclidean distance meets the condition, the trace route of the geological survey map of the target updated route is compared with the route trace route of the basic survey map to obtain the target comparison result.

And S106, when the target comparison result is within a preset threshold range, generating a shortcut icon from the target updating route geological survey.

In the technical solution provided in the above step S106 of the present invention, when the target comparison result is 7 and the target comparison result is within the preset threshold range, the shortcut icon is generated from the target updated route geological survey map, wherein the preset threshold range is 6 to 8, which is only illustrated herein and is not particularly limited.

The above-described method of this embodiment is further described below.

As an alternative embodiment, the method further comprises: determining a first hash value of the basic survey map and a second hash value of the first storage area through a hash function; when the basic investigation diagram is called, judging whether the hash value of the input first storage area is correct, when the hash value of the input first storage area is correct, judging whether the hash value of the input basic investigation diagram is correct, and when the hash value of the input basic investigation diagram is correct, obtaining the basic investigation diagram.

In this embodiment, the flow is throughDetermining a first hash value of the basic survey map and a second hash value of the first storage area by the hash function, for example, the first hash value of the basic survey map is 011101110, the second hash value of the first storage area is 001110000011, and if the basic survey map needs to be called, calculating a first Hamming distance between the input hash value of the first storage area and the second hash value by a Hamming distance algorithm, for example, the input hash value of the first storage area is 001110000111Thus, the first Hamming distance between 001110000111 and 001110000011 is equal to 1, and when the first Hamming distance 1 is less than the first preset Hamming distance 2, the first Hamming distance between the hash value of the input first storage area and the second hash value is calculated by the Hamming distance algorithm, for example, the hash value of the input basic survey map is 011111110, thenThus (S)>And when the second Hamming distance 1 is smaller than the second preset Hamming distance 3, obtaining a basic investigation diagram.

As an alternative embodiment, step S104, comparing each updated route geological survey of the plurality of updated route geological surveys of the target area, and determining the target updated route geological survey includes: determining any one of the plurality of updated route geological survey maps as a first updated route geological survey map; calculating a plurality of Euclidean distances between other updated route geological survey graphs of the plurality of updated route geological survey graphs except the first updated route geological survey graph and the first updated route geological survey graph; determining a minimum value in the plurality of Euclidean distances as a first Euclidean distance; and determining the updated route geological survey corresponding to the first Euclidean distance as a target updated route geological survey.

In this embodiment, any one of the plurality of updated route geological survey maps is determined as a first updated route geological survey map, and a plurality of euclidean distances between other updated route geological survey maps of the plurality of updated route geological survey maps than the first updated route geological survey map and the first updated route geological survey map are calculated according to the euclidean distance formula; the plurality of euclidean distances are 5,12,14, the minimum value of the plurality of euclidean distances is determined to be the first euclidean distance, and the updated route geological survey map corresponding to the first euclidean distance is determined to be the target updated route geological survey map.

As an alternative embodiment, calculating a plurality of euclidean distances between other ones of the plurality of updated route geological survey maps, except the first updated route geological survey map, and the first updated route geological survey map includes: determining longitude and latitude information of each address in the plurality of updated route geological survey; calculating the Euclidean distance between the longitude and latitude information of each address of each updated route geological survey of other updated route geological survey of the plurality of updated route geological survey graphs except the first updated route geological survey and the longitude and latitude information of each address of the first updated route geological survey; and accumulating and summing the Euclidean distances of each address of each of the other updated route geological survey maps except the first updated route geological survey map in the updated route geological survey maps to obtain the Euclidean distances of each of the other updated route geological survey maps except the first updated route geological survey map in the updated route geological survey maps.

In this embodiment, the latitude and longitude information of each address in the plurality of updated route geologic survey maps is determined, the euclidean sub-distance between each latitude and longitude information in the first updated route geologic survey map and each latitude and longitude information of the other plurality of updated route geologic survey maps except for the first updated route geologic survey map is calculated by a euclidean distance formula, the euclidean sub-distance between the latitude and longitude of each address of the other plurality of updated route geologic survey maps except for the first updated route geologic survey map is summed up, and the euclidean distance between the latitude and longitude of the first address of the first updated route geologic survey map and the latitude and longitude of the first address of the second updated route geologic survey map is obtained, for example, the euclidean sub-distance between the latitude and longitude of the second address of the first updated route geologic survey map and the longitude and latitude of the second address of the second updated route geologic survey map is calculated by the euclidean distance between the latitude and longitude of the second address of the second updated route geologic survey map, and the euclidean distance between the longitude and latitude of the second address of the first updated route geologic survey map and the second address of the second updated route geologic survey map is calculated by the euclidean distance between the first euclidean distance between the latitude and longitude of the second address of the second updated route geologic survey map.

As an optional embodiment, step S105, comparing the target updated route geological survey map with the basic survey map to obtain a target comparison result, includes: and comparing the longitude and latitude information of each address in the target updating route geological survey with the longitude and latitude information of each address in the basic survey, and comparing the route of the target updating route geological survey with the route of the basic survey when the first comparison is passed, so as to obtain a target comparison result.

In this embodiment, the latitude and longitude information of each address in the target updated route geological survey map is compared with the latitude and longitude information of each address in the basic survey map one by one, and when the comparison is passed, each trace route of the target updated route geological survey map is compared with each trace route of the basic survey map, so as to obtain a target comparison result, wherein the target comparison is a specific number, for example, 3,4 and the like.

As an optional embodiment, the first comparing the latitude and longitude information of each address in the geological survey of the target updated route with the latitude and longitude information of each address in the basic survey includes: calculating the Euclidean distance between the longitude and latitude information of each address in the geological survey of the target updating route and the longitude and latitude information of each address in the basic survey; accumulating and summing the Euclidean distance of the longitude and latitude information of each address in the target updating route geological survey to obtain a target Euclidean distance; and when the target Euclidean distance is smaller than the preset Euclidean distance, the first comparison is passed.

In this embodiment, when there are 5 addresses in the target update route geological survey, and when there are also 5 addresses in the base survey, a fourth euclidean distance between the latitude and longitude information of the first address of the target update route geological survey and the latitude and longitude information of the first address of the base survey is calculated, a fifth euclidean distance, a sixth euclidean distance, a seventh euclidean distance, and an eighth euclidean distance between the latitude and longitude information of the other 4 addresses in the target update route geological survey and the latitude and longitude information of the other 4 addresses in the base survey are sequentially calculated, and when the target euclidean distance 4 is smaller than the preset euclidean distance 5, the sum among the fifth euclidean distance, the sixth euclidean distance, the seventh euclidean distance, and the eighth euclidean distance is determined as the target euclidean distance, and the first comparison is passed.

As an alternative embodiment, step S105 further includes: and when the target Euclidean distance is greater than or equal to the preset Euclidean distance, the first comparison is not passed, and the generation of the shortcut icon by the target updating route geological survey is forbidden.

In this embodiment, if the target euclidean distance 4 is greater than or equal to the preset euclidean distance 3, the first contrast is not passed, and the generation of the shortcut icon by the target update route geological survey is prohibited.

As an alternative embodiment, the method further comprises: and when the target comparison result is not in the preset threshold range, prohibiting the target updating route geological survey from generating a shortcut icon.

In this embodiment, when the target comparison result is 7, and the target comparison result is not within the preset threshold range 4-5, the generation of the shortcut icon by the target update route geological survey is prohibited.

In the embodiment of the invention, the original route geological survey of the target area is obtained; taking the original route geological survey as a basic survey, and storing the basic survey into a first storage area; acquiring a plurality of updated route geological survey graphs of a target area, wherein the updated route geological survey graphs are obtained by re-surveying the target area by a plurality of survey groups; comparing each updated route geological survey of the plurality of updated route geological survey of the target area, and determining a target updated route geological survey; comparing the geological survey map of the target updating route with the basic survey map to obtain a target comparison result; when the target comparison result is within the preset threshold value range, the target is updated to generate the shortcut icon, so that the technical problem that the accuracy and the precision of the generated route geological survey shortcut map are low in the prior art is solved, and the technical effect of improving the accuracy and the precision of the generated route geological survey shortcut map is achieved.

Example 2

According to an embodiment of the present invention, a rapid mapping system for a route geological survey is provided, and it should be noted that the rapid mapping system for a route geological survey may be used to execute the rapid mapping method for a route geological survey in embodiment 1.

FIG. 2 is a block diagram of a route geological survey shortcut mapping system in accordance with an embodiment of the present invention. As shown in fig. 2, a route geological survey shortcut mapping system may include: the device comprises a first acquisition unit, a first processing unit, a second acquisition unit, a first comparison unit, a second comparison unit and a generation unit.

The first acquisition unit is used for acquiring an original route geological survey of the target area.

The first processing unit is used for taking the original route geological survey as a basic survey and storing the basic survey into the first storage area.

And a second acquisition unit configured to acquire a plurality of updated route geological survey maps of the target area, wherein the plurality of updated route geological survey maps are obtained by re-surveying the target area by a plurality of survey groups.

And the first comparison unit is used for comparing each updated route geological survey of the plurality of updated route geological survey of the target area and determining a target updated route geological survey.

And the second comparison unit is used for comparing the target updating route geological survey with the basic survey to obtain a target comparison result.

And the generating unit is used for generating a shortcut icon from the geological survey of the target updating route when the target comparison result is within the preset threshold range.

Optionally, the system further comprises: a first determining unit configured to determine a first hash value of the basic survey map and a second hash value of the first storage area by a hash function; the second processing unit is used for judging whether the hash value of the input first storage area is correct or not when the basic investigation diagram is called, judging whether the hash value of the input basic investigation diagram is correct or not when the hash value of the input first storage area is correct, and obtaining the basic investigation diagram when the hash value of the input basic investigation diagram is correct.

Optionally, the first contrast unit further comprises: the first determining module is used for determining any one updated route geological survey of the updated route geological survey to be a first updated route geological survey; a first calculation module for calculating a plurality of euclidean distances between other updated route geological survey graphs of the plurality of updated route geological survey graphs except the first updated route geological survey graph and the first updated route geological survey graph; the second determining module is used for determining the minimum value in the plurality of Euclidean distances as the first Euclidean distance; and the third determining module is used for determining the updated route geological survey corresponding to the first Euclidean distance as a target updated route geological survey.

Optionally, the first computing module further comprises: the first determining submodule is used for determining longitude and latitude information of each address in the plurality of updated route geological survey graphs; the first calculation sub-module is used for calculating Euclidean sub-distances between the longitude and latitude information of each address of each updated route geological survey map of other updated route geological survey maps except the first updated route geological survey map in the plurality of updated route geological survey maps and the longitude and latitude information of each address of the first updated route geological survey map; and the first summation sub-module is used for carrying out accumulated summation on Euclidean distances of each address of each updated route geological survey map of other updated route geological survey maps except the first updated route geological survey map in the updated route geological survey maps to obtain Euclidean distances of each updated route geological survey map of the other updated route geological survey maps except the first updated route geological survey map in the updated route geological survey maps.

Optionally, the second contrast unit further comprises: the first processing module is used for performing first comparison on the longitude and latitude information of each address in the target updating route geological survey map and the longitude and latitude information of each address in the basic survey map, and when the first comparison is passed, the route of the target updating route geological survey map is compared with the route of the basic survey map, so that a target comparison result is obtained.

Optionally, the first processing module further comprises: the second calculation sub-module is used for calculating the Euclidean distance between the longitude and latitude information of each address in the target updating route geological survey and the longitude and latitude information of each address in the basic survey; the second summation sub-module is used for accumulating and summing the Euclidean distance of the longitude and latitude information of each address in the target updating route geological survey to obtain a target Euclidean distance; and the pass sub-module is used for passing the first comparison when the target Euclidean distance is smaller than the preset Euclidean distance.

Optionally, the first processing module further comprises: and the prohibition submodule is used for prohibiting the target updating route geological survey from generating a shortcut icon when the first comparison fails and the target Euclidean distance is larger than or equal to the preset Euclidean distance.

Optionally, the system further comprises: and the prohibition unit is used for prohibiting the target updating route geological survey from generating a shortcut icon when the target comparison result is not within the preset threshold range.

In the embodiment, a first acquisition unit is used for acquiring an original route geological survey of a target area; the first processing unit is used for taking the original route geological survey as a basic survey and storing the basic survey into a first storage area; a second acquisition unit configured to acquire a plurality of updated route geological survey maps of the target area, wherein the plurality of updated route geological survey maps are obtained by re-surveying the target area by a plurality of survey groups; the first comparison unit is used for comparing each updated route geological survey of the target area and determining a target updated route geological survey; the second comparison unit is used for comparing the target updating route geological survey with the basic survey to obtain a target comparison result; the generation unit is used for generating a shortcut icon by updating the route geological survey map according to the target comparison result when the target comparison result is within the preset threshold range, so that the technical problem that the accuracy of the geological model constructed by the current three-dimensional geological modeling is low is solved, the technical problem that the accuracy and the precision of the route geological survey shortcut map generated by the prior art are low is solved, and the technical effect of improving the accuracy and the precision of the generated route geological survey shortcut map is achieved.

Example 3

According to an embodiment of the present invention, there is also provided a computer-readable storage medium including a stored program, wherein the program executes a route geological survey shortcut mapping method of embodiment 1.

Example 4

According to an embodiment of the present invention, there is further provided a processor for running a program, wherein the program executes a route geological survey shortcut mapping method in embodiment 1.

The foregoing embodiment numbers of the present invention are merely for the purpose of description, and do not represent the advantages or disadvantages of the embodiments.

In the foregoing embodiments of the present invention, the descriptions of the embodiments are emphasized, and for a portion of this disclosure that is not described in detail in this embodiment, reference is made to the related descriptions of other embodiments.

In the several embodiments provided in the present application, it should be understood that the disclosed technology content may be implemented in other manners. The above-described embodiments of the apparatus are merely exemplary, and the division of units may be a logic function division, and there may be another division manner in actual implementation, for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be through some interfaces, units or modules, or may be in electrical or other forms.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed over a plurality of units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in the embodiments of the present invention may be integrated in one first processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit. The integrated units may be implemented in hardware or in software functional units.

The integrated units, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied in essence or a part contributing to the prior art or all or part of the technical solution in the form of a software product stored in a storage medium, comprising several instructions for causing a computer device (which may be a personal computer, a server or a network device, etc.) to perform all or part of the steps of the method of the various embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a Read-only memory (ROM), a random access memory (RAM, randomAccessMemory), a removable hard disk, a magnetic disk, or an optical disk, or other various media capable of storing program codes.

The foregoing is merely a preferred embodiment of the present invention and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present invention, which are intended to be comprehended within the scope of the present invention.

Claims (9)

1. A rapid mapping method for a route geological survey, comprising the steps of:

acquiring an original route geological survey of a target area;

taking the original route geological survey as a basic survey, and storing the basic survey into a first storage area;

acquiring a plurality of updated route geological survey graphs of the target area, wherein the updated route geological survey graphs are obtained by re-surveying the target area through a plurality of survey groups;

comparing each updated route geological survey of the plurality of updated route geological survey of the target area, and determining a target updated route geological survey;

comparing the target updating route geological survey with the basic survey to obtain a target comparison result;

and when the target comparison result is within a preset threshold range, generating a shortcut icon by updating the route geological survey map.

2. A route geological survey shortcut mapping method according to claim 1, wherein the method further comprises:

determining a first hash value of the basic survey map and a second hash value of the first storage area through a hash function;

when the basic investigation map is called, judging whether the hash value of the input first storage area is correct, when the hash value of the input first storage area is correct, judging whether the hash value of the input basic investigation map is correct, and when the hash value of the input basic investigation map is correct, obtaining the basic investigation map.

3. The method of claim 1, wherein comparing each updated route geological survey of the plurality of updated route geological surveys of the target area to determine a target updated route geological survey, comprises:

determining any one of the plurality of updated route geological survey maps as a first updated route geological survey map;

calculating a plurality of Euclidean distances between other updated route geological survey graphs of the plurality of updated route geological survey graphs except the first updated route geological survey graph and the first updated route geological survey graph;

determining a minimum value of the plurality of Euclidean distances as a first Euclidean distance;

and determining the updated route geological survey corresponding to the first Euclidean distance as the target updated route geological survey.

4. A route geological survey shortcut mapping method according to claim 3, wherein said calculating a plurality of euclidean distances between other ones of said plurality of updated route geological survey maps than said first updated route geological survey map and said first updated route geological survey map comprises:

determining longitude and latitude information of each address in the plurality of updated route geological survey;

calculating Euclidean distances between the longitude and latitude information of each address of each updated route geological survey of the other updated route geological survey of the plurality of updated route geological survey except the first updated route geological survey and the longitude and latitude information of each address of the first updated route geological survey;

and accumulating and summing the Euclidean distances of each address of each of the other updated route geological survey maps except the first updated route geological survey map in the updated route geological survey maps to obtain the Euclidean distances of each updated route geological survey map of the other updated route geological survey maps except the first updated route geological survey map in the updated route geological survey maps.

5. The method for quickly mapping a route geological survey according to claim 1, wherein comparing the target updated route geological survey with the base survey to obtain a target comparison result comprises:

and performing first comparison on the longitude and latitude information of each address in the target updating route geological survey and the longitude and latitude information of each address in the basic survey, and comparing the route of the target updating route geological survey with the route of the basic survey when the first comparison passes, so as to obtain a target comparison result.

6. The method for quickly mapping a route geological survey according to claim 5, wherein the first comparing the latitude and longitude information of each address in the route geological survey with the latitude and longitude information of each address in the basic survey comprises:

calculating the Euclidean distance between the longitude and latitude information of each address in the target updating route geological survey and the longitude and latitude information of each address in the basic survey;

accumulating and summing the Euclidean distance of the longitude and latitude information of each address in the target updating route geological survey to obtain a target Euclidean distance;

and when the target Euclidean distance is smaller than a preset Euclidean distance, the first comparison is passed.

7. A route geological survey shortcut mapping method according to claim 6, wherein the method further comprises:

and when the target Euclidean distance is greater than or equal to the preset Euclidean distance, the first comparison is not passed, and the target updating route geological survey is forbidden to generate the shortcut icon.

8. A route geological survey shortcut mapping method according to claim 1, wherein the method further comprises:

and when the target comparison result is not in the preset threshold range, prohibiting the target updating route geological survey from generating the shortcut icon.

9. A rapid mapping system for a route geological survey, comprising:

the first acquisition unit is used for acquiring an original route geological survey of the target area;

the first processing unit is used for taking the original route geological survey as a basic survey and storing the basic survey into the first storage area;

a second obtaining unit, configured to obtain a plurality of updated route geological survey maps of the target area, where the plurality of updated route geological survey maps are obtained by re-surveying the target area by a plurality of survey groups;

the first comparison unit is used for comparing each updated route geological survey of the target area and determining a target updated route geological survey;

the second comparison unit is used for comparing the target updating route geological survey with the basic survey to obtain a target comparison result;

and the generation unit is used for generating a shortcut icon from the target updating route geological survey when the target comparison result is within a preset threshold range.