CN115112866A - Hydrothermal deposit investigation system based on electromagnetic radiation - Google Patents
Hydrothermal deposit investigation system based on electromagnetic radiation Download PDFInfo
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Abstract
The invention relates to the technical field of geological survey, and particularly discloses a hydrothermal deposit exploration system based on electromagnetic radiation, which comprises a sample acquisition module, a sample processing module, a cleaning processing module, a sample pre-inspection module, a temperature information measuring module, a data receiving module, a pollution analysis module, a pollution evaluation module and a mark information sending module, wherein the output end of the sample acquisition module is connected with the sample processing module, the output end of the sample processing module is connected with the temperature information measuring module, the output end of the data receiving module is connected with the pollution analysis module, the output end of the pollution analysis module is connected with a master control module, the master control module comprises the mark information sending module, the uniform temperature data abnormal condition of a sample is determined according to the fluctuation of sample temperature data, the sample is classified according to the abnormal condition, and is determined to be sampling point pollution caused by an external invading mineral sampling point or pollution generated by sample processing, avoid contaminating the position and leading to the subsequent sample that produces the pollution.
Description
Technical Field
The invention relates to the technical field of geological survey, in particular to a hydrothermal deposit exploration system based on electromagnetic radiation.
Background
The hydrothermal ore deposit is a useful mineral accumulation body formed by filling, substituting and the like in various favorable structures and rocks under certain physicochemical conditions, one or more phase substances filled and sealed in tiny holes, cracks or inter-granular spaces of minerals are called fluid inclusion bodies in the process of mineral crystal growth, the fluid inclusion bodies record and store the material and chemical characteristics of different stages of geological action, the hydrothermal ore deposit is convenient to discuss the formation and mineralization mode of the ore deposit during the research of the fluid inclusion bodies, the ancient temperature and important parameters of the salt system components of the inclusion bodies are determined by measuring the temperature of the fluid inclusion bodies, and some solids such as rocks, minerals and the like contain bound charged particles and free charged point electrons, and irregular deformation and rupture of rock bodies are caused when the solids receive external stress, leading to the generation of electromagnetic radiation phenomenon before the occurrence of internal charges.
In the process of researching a fluid inclusion of a hydrothermal deposit, in the process of preparing and sampling the fluid inclusion sample, foreign minerals cause certain pollution to the fluid inclusion sample, influence the original properties of the fluid inclusion, influence the final judgment of the cause and the mineralization mode of the hydrothermal deposit, and after the polluted sample exists, the pollution cause cannot be determined in time, so that the subsequent polluted sample is generated, and the normal exploration of the hydrothermal deposit is influenced.
Disclosure of Invention
The present invention is directed to a hydrothermal deposit exploration system based on electromagnetic radiation, so as to solve the problems mentioned in the background art.
In order to achieve the purpose, the invention provides the following technical scheme:
a hydrothermal ore deposit exploration system based on electromagnetic radiation comprises a sample collection module, a sample processing module, a cleaning processing module, a sample pre-inspection module, a temperature information measuring module, a data receiving module, a pollution analysis module, a pollution evaluation module and a marking information sending module, wherein the output end of the sample collection module is connected with the sample processing module for processing collected fluid wrapped body samples, the sample collection and processing are convenient, the sample processing module comprises the sample pre-inspection module for collecting sample electromagnetic radiation information and the cleaning processing module for cleaning the sample processing module, the sample electromagnetic radiation detection is realized in the sample processing process, the sample processing module for processing samples is cleaned, the output end of the sample processing module is connected with the temperature information measuring module for collecting uniform temperature information of the samples, the data transmission sections of the cleaning processing module, the sample pre-detection module and the temperature information measuring module are all connected with the data receiving module, the cleaning processing module, the sample pre-detection module and the temperature information measuring module respectively transmit cleaning signals, sample electromagnetic radiation information and sample uniform temperature information to the data receiving module, so that the cleaning signals, the sample electromagnetic radiation information and the sample uniform temperature information can be conveniently summarized, and the cleaning signal, the sample electromagnetic radiation information and the sample uniform temperature information are all corresponding to the sample, the output end of the data receiving module is connected with a pollution analysis module used for analyzing the pollution reasons and the data abnormity, the output end of the pollution analysis module is connected with a master control module, which is convenient for realizing the transmission of control signals according to the analysis result, the master control module comprises a mark information sending module which sends a pollution mark signal to the sample acquisition module and the sample processing module.
Further, the specific sample collection process of the sample collection module is as follows: firstly, arranging sampling lines according to the distribution position of a hydrothermal deposit, wherein the distance between every two sampling lines is 100 meters, determining sampling points on the sampling lines by the point distance of 40 meters, determining the sampling range of the sampling points, sampling in the range of one tenth of the point-to-point distance around the sampling points, moving the sampling points in the range of one half of the point-to-line distance when the sampling points have non-sampling terrains such as waste rock piles, collapsed materials, rivers, riverbed piles and the like, recording and giving up the sampling of the sampling points after the step two, independently placing fluid inclusions collected in the sampling points meeting the sampling conditions, and marking the position information of the sampling points as C (m).
Further, the specific sample processing process of the sample processing module is as follows: checking the sample and the information of the sampling point C (m) to ensure that the sample corresponds to the information of the sampling point C (m), wherein the collected sample meets the sampling requirement in the sampling process, placing the sample under sunlight or a fluorescent lamp, drying the sample, lightly beating the sample to break down particles in clay cement on the surface of the sample to remove the attachments on the surface of the sample, preparing different fluid inclusion samples collected in the mth sampling point C (m) into sample pieces with two polished surfaces, and setting the sampling point C (m) and the nth processed sample piece as M (n) according to the sequence of sample processing according to the serial number of the sampling point C (m) of the fluid inclusion.
Further, the specific summary flow of the information data of the fluid inclusion sample by the data receiving module is as follows: extracting the temperature information of a single sample, summarizing the temperature information of different samples from the same sampling point, acquiring the intermediate value of the temperature information of the single sampling point C (m) as the temperature information data of the sample of the sampling point C (m), and summarizing the temperature information of the samples of different sampling points respectively.
Further, the specific processing procedure of the temperature information of the fluid inclusion sample at the same sampling point c (m) by the pollution analysis module is as follows: extracting temperature information of different fluid inclusion samples of the same sampling point C (m) and summarizing the data, making a temperature-sample number scatter diagram according to the temperature information of the sampling point C (m), and according to a linear regression equation formula:
wherein: x is the number of i For ordering of samples to be processed, y i Is the x (th) of i The uniform temperature data for each of the samples,half the total number of samples collected for this sample point c (m),average value of uniform temperature;
making a linear regression line, and presetting the slope range of the linear regression line as k 1 The slope b of the linear regression line is in a preset range k 1 In the time, the sample of the sampling point C (m) is classified as a regular sample, and when the slope b of the linear regression line exceeds the preset range k 1 In the meantime, the samples of the sampling points c (m) are classified as samples to be detected.
Further, the specific processing procedure of the temperature information of the fluid inclusion sample of all sampling points by the pollution analysis module is as follows: extracting temperature information of all sampling points of the fluid inclusion sample, summarizing the data, sequencing the data according to the sampling time of the sampling points, manufacturing a temperature-sample number scatter diagram, making a linear regression line according to a linear regression equation formula, and setting the maximum fluctuation range of the temperature point and the linear regression line in the scatter diagram as k 2 The temperature point in the scatter diagram and the linear regression line are greater than a preset range K 2 And classifying the corresponding sampling points into sampling points to be detected.
The pollution analysis module is further configured to perform secondary processing on data of the sampling points c (m) to be detected, where the specific processing procedure is as follows: setting that the sample temperature information of the sampling points C (m) sequenced to m is abnormal, acquiring the electromagnetic radiation intensity information of a sample pre-detection module, comparing the sample electromagnetic radiation information acquired by the sampling points C (m) sequenced to m with the sample electromagnetic radiation information acquired by the other sampling points, classifying the sample electromagnetic radiation information of the m-th sampling point C (m) as sampling point pollution when the sample electromagnetic radiation information of the m-th sampling point C (m) and the sample electromagnetic radiation information acquired by the other sampling points are obviously fluctuated, and classifying the sample electromagnetic radiation information of the m-th sampling point C (m) as sample treatment pollution when the sample electromagnetic radiation information of the m-th sampling point C (m) and the sample electromagnetic radiation information acquired by the other sampling points are not obviously fluctuated.
The pollution analysis module is further configured to perform secondary processing on sample data to be detected of the sampling points c (m), where the specific processing procedure is as follows: setting a sampling point C (m) with a sample to be detected, wherein the uniform temperature data of the nth sample and the uniform temperature data of the previous sample have the largest fluctuation amplitude, marking the sampling point C (m) as abnormal, acquiring cleaning signal data of a cleaning processing module in the sample processing process of the sampling point C (m), matching the sample data of the sampling point C (m) with the cleaning signal data, classifying the sampling point C (m) as sample processing pollution when n =1 exists or the corresponding sampling point C (m) of the sample with the cleaning signal does not exist, and classifying the sampling point C (m) as sample processing pollution when n > 1 exists and the sample without the cleaning signal exists in the (n-1) th sample.
Compared with the prior art, the invention has the following advantages: through a plurality of sampling points that set for and carry out the collection of a plurality of samples in same sampling point, after gathering sample data, confirm the homogeneous temperature data abnormal conditions of sample according to sample temperature data's fluctuation, and through the electromagnetic radiation information and the clearance information of unusual sample, classify the anomaly of this sample, confirm for the sampling point pollution that external mineral invasion sampling point caused or handle the pollution that produces to the sample, avoid polluting the position and lead to the sample that follow-up production pollutes, reduce the error that produces the sample pollution in the normal investigation of hydrothermal deposit investigation.
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In order to more clearly illustrate the technical solution of the present invention, the drawings needed to be used in the technical description of the present invention will be briefly introduced below, and it is apparent that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive labor.
FIG. 1 is a block diagram of the system of the present invention.
Detailed Description
The present invention is further described in the following with reference to specific embodiments, and all other embodiments obtained by a person of ordinary skill in the art without any inventive work are within the scope of the present invention.
Referring to fig. 1, the present invention provides an electromagnetic radiation-based hydrothermal ore deposit exploration system, which comprises a sample collection module, a sample processing module, a cleaning processing module, a sample pre-inspection module, a temperature information measurement module, a data receiving module, a pollution analysis module, a pollution evaluation module and a marking information sending module, wherein an output end of the sample collection module is connected with the sample processing module for processing collected fluid wrapped body samples, the sample processing module comprises a sample pre-inspection module for collecting sample electromagnetic radiation information and a cleaning processing module for cleaning the sample processing module, an output end of the sample processing module is connected with the temperature information measurement module for collecting uniform temperature information of samples, and data transmission sections of the cleaning processing module, the sample pre-inspection module and the temperature information measurement module are all connected with a data receiving module, and the cleaning processing module, the sample pre-detection module and the temperature information measuring module respectively carry out data transmission on cleaning signals, sample electromagnetic radiation information and sample uniform temperature information to the data receiving module, the output end of the data receiving module is connected with a pollution analysis module which is used for analyzing pollution reasons and data abnormity, the output end of the pollution analysis module is connected with a master control module, and the master control module comprises a mark information sending module which sends pollution mark signals to the sample collecting module and the sample processing module.
Through setting for a plurality of sampling points and carrying out the collection of a plurality of samples in same sampling point, after gathering sample data, confirm the homogeneous temperature data abnormal conditions of sample according to sample temperature data's fluctuation, and through the electromagnetic radiation information and the clearance information of unusual sample, classify the anomaly of this sample, confirm for the sampling point pollution that external mineral invasion sampling point caused or handle the pollution that produces to the sample, avoid polluting the position and lead to the sample of follow-up production pollution, reduce the error that the sample pollution produced in the normal investigation of hydrothermal deposit investigation.
The specific sample collection process of the sample collection module is as follows: firstly, arranging sampling lines according to the distribution position of a hydrothermal deposit, wherein the distance between every two sampling lines is 100 meters, determining sampling points on the sampling lines by the point distance of 40 meters, determining the sampling range of the sampling points, sampling in the range of one tenth of the point-to-point distance around the sampling points, moving the sampling points in the range of one half of the point-to-line distance when the sampling points have non-sampling terrains such as waste rock piles, collapsed materials, rivers, riverbed piles and the like, recording and giving up the sampling of the sampling points after the step two, independently placing fluid inclusions collected in the sampling points meeting the sampling conditions, and marking the position information of the sampling points as C (m).
Through carrying out the collection of sample to a plurality of sampling points to in the collection process, avoid carrying out the collection of sample to topography such as barren rock heap, collapse thing, river, riverbed pile up, reduce the external pollution of sample collection in-process, and conveniently fix a position the positional information of sampling point.
The specific sample processing process of the sample processing module is as follows: checking the sample and the information of the sampling point C (m) to ensure that the sample corresponds to the information of the sampling point C (m), wherein the collected sample meets the sampling requirement in the sampling process, placing the sample under sunlight or a fluorescent lamp, drying the sample, lightly beating the sample to break down particles in clay cement on the surface of the sample to remove the attachments on the surface of the sample, preparing different fluid inclusion samples collected in the mth sampling point C (m) into sample pieces with two polished surfaces, and setting the sampling point C (m) and the nth processed sample piece as M (n) according to the sequence of sample processing according to the serial number of the sampling point C (m) of the fluid inclusion.
Through the processing to the sample, further reduce the pollution of foreign matter to the sample, and conveniently discern the sample of same sampling point collection.
The specific summarizing process of the data receiving module for the information data of the fluid inclusion sample is as follows: extracting the temperature information of a single sample, summarizing the temperature information of different samples from the same sampling point, acquiring the intermediate value of the temperature information of the single sampling point C (m) as the temperature information data of the sample of the sampling point C (m), and summarizing the temperature information of the samples of different sampling points respectively.
The data are collected to compare the average values of the uniform temperatures of different sampling points or the data of the uniform temperatures of different samples of the same sampling point more conveniently.
The specific processing process of the pollution analysis module on the temperature information of the fluid inclusion sample at the same sampling point C (m) is as follows: extracting temperature information of different fluid inclusion samples of the same sampling point C (m) and summarizing the data, making a temperature-sample number scatter diagram according to the temperature information of the sampling point C (m), and according to a linear regression equation formula:
wherein: x is the number of i For ordering of samples to be processed, y i Is the x i The uniform temperature data for each of the samples,half the total number of samples collected for this sample point c (m),average value of uniform temperature;
making a linear regression line, and presetting the slope range of the linear regression line as k 1 The slope b of the linear regression line is in a preset range k 1 In the time, the sample of the sampling point C (m) is classified as a regular sample, and when the slope b of the linear regression line exceeds the preset range k 1 In the meantime, the samples of the sampling points c (m) are classified as samples to be detected.
By making a temperature-sample sequence number scatter diagram of the sample uniform temperature information, abnormal uniform temperature changes in different samples of the same sampling point can be conveniently determined.
The specific processing process of the pollution analysis module on the temperature information of the fluid inclusion sample of all sampling points is as follows: extracting temperature information of all sampling points of the fluid inclusion sample, summarizing the data, sequencing the data according to the sampling time of the sampling points, manufacturing a temperature-sample number scatter diagram, making a linear regression line according to a linear regression equation formula, and setting the maximum fluctuation range of the temperature point and the linear regression line in the scatter diagram as k 2 The temperature point in the scatter diagram and the linear regression line are greater than a preset range K 2 And classifying the corresponding sampling points into sampling points to be detected.
The sampling points of all the sampling points with abnormal uniform temperature samples are conveniently determined through the process.
The pollution analysis module is further configured to perform secondary processing on data of the sampling points c (m) to be detected, where the specific processing procedure is as follows: setting that the sample temperature information of the sampling points C (m) sequenced to m is abnormal, acquiring the electromagnetic radiation intensity information of a sample pre-detection module, comparing the sample electromagnetic radiation information acquired by the sampling points C (m) sequenced to m with the sample electromagnetic radiation information acquired by the other sampling points, classifying the sample electromagnetic radiation information of the m-th sampling point C (m) as sampling point pollution when the sample electromagnetic radiation information of the m-th sampling point C (m) and the sample electromagnetic radiation information acquired by the other sampling points are obviously fluctuated, and classifying the sample electromagnetic radiation information of the m-th sampling point C (m) as sample treatment pollution when the sample electromagnetic radiation information of the m-th sampling point C (m) and the sample electromagnetic radiation information acquired by the other sampling points are not obviously fluctuated.
The pollution reason judgment of sampling points with abnormal uniform temperature samples is assisted through the change of sample electromagnetic radiation information collected by different generation service points.
The pollution analysis module is also used for carrying out secondary processing on sample data to be detected of the sampling points C (m), and the specific processing process is as follows: setting a sampling point C (m) with a sample to be detected, wherein the uniform temperature data of the nth sample and the uniform temperature data of the previous sample have the largest fluctuation amplitude, marking the nth sample data of the sampling point C (m) as abnormal, acquiring cleaning signal data of a cleaning processing module in the sample processing process of the sampling point C (m), matching the sample data of the sampling point C (m) with the cleaning signal data, classifying the samples into sampling point pollution when n =1 exists or the corresponding sampling point C (m) of the sample without the cleaning signal exists, and classifying the samples into sample processing pollution when n > 1 exists and the nth-1 sample has the sample without the cleaning signal.
Whether the sample is abnormal or not is judged by judging whether the sample processing module is cleaned before the sample with the abnormality in the same sampling point is processed or not, and whether the sample is abnormal or not is judged by judging whether the sample is polluted due to the residue of the previous sample.
It should be noted that the specific workflow of the hydrothermal deposit exploration system based on electromagnetic radiation provided by the present invention is as follows:
the method comprises the following steps: firstly, a sample collection module collects samples at different positions of a hydrothermal deposit, the positions of the sampling points and sampling serial numbers of the sampling points are determined, the sampling points correspond to the collected samples, then the collected samples are sent into a sample processing module to be processed, after impurities and pollution on the surfaces of the samples are eliminated, the samples are finally made into sample pieces with two polished surfaces, electromagnetic radiation in the sample processing process is detected by a sample pre-detection module, then the sample pieces with the two polished surfaces are sent into a temperature measurement fixed module to be detected at uniform temperature of the samples, and the sample processing module is cleaned by a cleaning processing module to realize the preparation of the samples;
step two: the sample pre-detection module sends detected sample electromagnetic radiation information and detected sample uniform temperature information and detected cleaning information of the cleaning module to the data receiving module for gathering, the data receiving module sends gathered data to the pollution analysis module, uniform temperature information changes of different samples are recorded, the sample uniform temperature information changes are classified according to the sample electromagnetic radiation information and the cleaning information before sample processing, and a pollution starting point of the samples is determined;
step three: the total control module controls the mark information sending module according to the sample processing pollution information and the sampling point pollution information, marks the sample acquisition module and the sample processing module which acquire and process the abnormal pollution sample, and is convenient for eliminating pollution.
In summary, the system for investigating hydrothermal deposit based on electromagnetic radiation provided by this embodiment can also collect a plurality of samples by setting a plurality of sampling points and collecting the samples at the same sampling point, after the sample data is collected, determine the homogeneous temperature data abnormal condition of the samples according to the fluctuation of the sample temperature data, classify the abnormality of the samples according to the electromagnetic radiation information and the cleaning information of the abnormal samples, determine the pollution of the sampling points caused by the invasion of foreign minerals into the sampling points or the pollution generated by processing the samples, avoid the samples which are subsequently polluted due to the polluted positions, and reduce the errors generated by the sample pollution in the normal investigation of hydrothermal deposit investigation. Through carrying out the collection of sample to a plurality of sampling points to in the collection process, avoid carrying out the collection of sample to topography such as barren rock heap, collapse thing, river, riverbed pile up, reduce the external pollution of sample collection in-process, and conveniently fix a position the positional information of sampling point. Through the processing to the sample, further reduce the pollution of foreign matter to the sample, and conveniently discern the sample of same sampling point collection. The data are collected to compare the average values of the uniform temperatures of different sampling points or the data of the uniform temperatures of different samples of the same sampling point more conveniently. By making a temperature-sample sequence number scatter diagram of the sample uniform temperature information, abnormal uniform temperature changes in different samples of the same sampling point can be conveniently determined, and the sampling point of the abnormal uniform temperature sample in all the sampling points can be conveniently determined. The pollution reason judgment of sampling points with abnormal uniform temperature samples is assisted through the change of sample electromagnetic radiation information collected by different generation service points. Whether the sample is abnormal or not is judged by judging whether the sample processing module is cleaned before the sample with the abnormality in the same sampling point is processed or not, and whether the sample is abnormal or not is judged by judging whether the sample is polluted due to the residue of the previous sample.
The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and it should be understood that the technical solutions and the inventive concepts according to the present invention should be equally replaced or changed by those skilled in the art within the technical scope of the present invention.
Claims (8)
1. The utility model provides a hydrothermal deposit exploration system based on electromagnetic radiation, includes sample acquisition module, sample processing module, clearance processing module, sample preliminary examination module, temperature information survey module, data receiving module, pollution analysis module, pollution evaluation module and mark information sending module, its characterized in that: the output end of the sample acquisition module is connected with a sample processing module for processing the acquired fluid wrapped sample, the sample processing module comprises a sample pre-detection module for acquiring electromagnetic radiation information of the sample and a cleaning processing module for cleaning the sample processing module, the output end of the sample processing module is connected with a temperature information measuring module for acquiring uniform temperature information of the sample, the data transmission sections of the cleaning processing module, the sample pre-detection module and the temperature information measuring module are all connected with a data receiving module, the cleaning processing module, the sample pre-detection module and the temperature information measuring module respectively transmit cleaning signals, electromagnetic radiation information of the sample and uniform temperature information of the sample to the data receiving module for data transmission, and the output end of the data receiving module is connected with a pollution analysis module for analyzing the abnormal data and pollution reasons, the output end of the pollution analysis module is connected with a master control module, and the master control module comprises a mark information sending module which sends a pollution mark signal to the sample acquisition module and the sample processing module.
2. A hydrothermal deposit exploration system based on electromagnetic radiation, according to claim 1, characterized by: the specific sample collection process of the sample collection module is as follows: firstly, arranging sampling lines according to the distribution position of a hydrothermal deposit, wherein the distance between every two sampling lines is 100 meters, determining sampling points on the sampling lines by the point distance of 40 meters, determining the sampling range of the sampling points, sampling in the range of one tenth of the point-to-point distance around the sampling points, moving the sampling points in the range of one half of the point-to-line distance when the sampling points have non-sampling terrains such as waste rock piles, collapsed materials, rivers, riverbed piles and the like, recording and giving up the sampling of the sampling points after the step two, independently placing fluid inclusions collected in the sampling points meeting the sampling conditions, and marking the position information of the sampling points as C (m).
3. A hydrothermal deposit exploration system based on electromagnetic radiation, according to claim 1, characterized by: the specific sample processing process of the sample processing module is as follows: checking the sample and the information of the sampling point C (m) to ensure that the sample corresponds to the information of the sampling point C (m), wherein the collected sample meets the sampling requirement in the sampling process, placing the sample under sunlight or a fluorescent lamp, drying the sample, lightly beating the sample to break down particles in clay cement on the surface of the sample to remove the attachments on the surface of the sample, preparing different fluid inclusion samples collected in the mth sampling point C (m) into sample pieces with two polished surfaces, and setting the sampling point C (m) and the nth processed sample piece as M (n) according to the sequence of sample processing according to the serial number of the sampling point C (m) of the fluid inclusion.
4. A hydrothermal deposit exploration system based on electromagnetic radiation, according to claim 1, characterized by: the specific summarizing process of the data receiving module for the information data of the fluid inclusion sample is as follows: extracting the temperature information of a single sample, summarizing the temperature information of different samples from the same sampling point, acquiring the intermediate value of the temperature information of the single sampling point C (m) as the temperature information data of the sample of the sampling point C (m), and summarizing the temperature information of the samples of different sampling points C (m) respectively.
5. A hydrothermal deposit exploration system based on electromagnetic radiation, according to claim 1, characterized by: the specific processing process of the pollution analysis module on the temperature information of the fluid inclusion sample at the same sampling point C (m) is as follows: extracting temperature information of different fluid inclusion samples of the same sampling point C (m) and summarizing the data, making a temperature-sample number scatter diagram according to the temperature information of the sampling point C (m), and according to a linear regression equation formula:
wherein: x is the number of i For ordering of samples to be processed, y i Is the x i The uniform temperature data for each of the samples,half the total number of samples collected for this sample point c (m),average value of uniform temperature;
making a linear regression line, and presetting the slope range of the linear regression line as k 1 The slope b of the linear regression line is in a preset range k 1 In the time, the sample of the sampling point C (m) is classified as a regular sample, and when the slope b of the linear regression line exceeds the preset range k 1 In the meantime, the samples of the sampling points c (m) are classified as samples to be detected.
6. A hydrothermal deposit exploration system based on electromagnetic radiation, according to claim 1, characterized by: the specific processing process of the pollution analysis module on the temperature information of the fluid inclusion sample of all sampling points is as follows: data for summarizing temperature information of fluid inclusion sample extracted from all sampling pointsSorting the sampling time of the sampling points, making a temperature-sample number scatter diagram, making a linear regression line according to a linear regression equation formula, and setting the maximum fluctuation range of the temperature points and the linear regression line in the scatter diagram as k 2 The temperature point in the scatter diagram and the linear regression line are greater than a preset range K 2 And classifying the corresponding sampling points as sampling points to be detected.
7. A hydrothermal deposit exploration system based on electromagnetic radiation, according to claim 1, characterized by: the pollution analysis module is further configured to perform secondary processing on data of the sampling points c (m) to be detected, where the specific processing procedure is as follows: setting that the sample temperature information of the sampling points C (m) sequenced to m is abnormal, acquiring the electromagnetic radiation intensity information of a sample pre-detection module, comparing the sample electromagnetic radiation information acquired by the sampling points C (m) sequenced to m with the sample electromagnetic radiation information acquired by the other sampling points, classifying the sample electromagnetic radiation information of the m-th sampling point C (m) as sampling point pollution when the sample electromagnetic radiation information of the m-th sampling point C (m) and the sample electromagnetic radiation information acquired by the other sampling points are obviously fluctuated, and classifying the sample electromagnetic radiation information of the m-th sampling point C (m) as sample treatment pollution when the sample electromagnetic radiation information of the m-th sampling point C (m) and the sample electromagnetic radiation information acquired by the other sampling points are not obviously fluctuated.
8. A hydrothermal deposit exploration system based on electromagnetic radiation, according to claim 1, characterized by: the pollution analysis module is further configured to perform secondary processing on sample data to be detected of the sampling points c (m), where the specific processing procedure is as follows: setting a sampling point C (m) with a sample to be detected, wherein the uniform temperature data of the nth sample and the uniform temperature data of the previous sample have the largest fluctuation amplitude, marking the nth sample data of the sampling point C (m) as abnormal, acquiring cleaning signal data of a cleaning processing module in the sample processing process of the sampling point C (m), matching the sample data of the sampling point C (m) with the cleaning signal data, classifying the samples into sampling point pollution when n =1 exists or the corresponding sampling point C (m) of the sample without the cleaning signal exists, and classifying the samples into sample processing pollution when n > 1 exists and the nth-1 sample has the sample without the cleaning signal.
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