CN111582603A - Intelligent early warning method for coal and gas outburst based on multi-source information fusion - Google Patents
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Abstract
The invention provides an intelligent early warning method for coal and gas outburst based on multi-source information fusion, which comprises the following steps: acquiring historical data of coal and gas outburst early warning indexes, and carrying out normalization processing on the acquired historical data; performing association analysis on the historical early warning indexes by adopting an association rule algorithm, and calculating the support degree and the confidence degree of each historical early warning index; establishing a coal and gas outburst early warning index optimization rule based on the association rule, and performing early warning index optimization; constructing a confidence coefficient distribution rule of the early warning index; the method comprises the steps of collecting real-time indexes of coal and gas outburst, calculating the real-time indexes to obtain confidence degrees of the real-time indexes, forming a confidence degree distribution table of the real-time indexes, carrying out evidence synthesis on the real-time indexes by adopting an evidence theory algorithm to obtain decision results, and distributing coal and gas outburst early warning results according to the decision results, so that automatic screening of coal and gas outburst early warning indexes, automatic fusion analysis and decision of multiple indexes, automatic tracing of early warning reasons and dynamic updating and optimization of a model are realized, intelligent early warning of the coal and gas outburst is realized, and accuracy of the early warning results is ensured.
Description
Technical Field
The invention relates to a coal and gas outburst early warning method, in particular to an intelligent coal and gas outburst early warning method based on multi-source information fusion.
Background
Prediction and early warning are the first links of prevention and control of coal and gas outburst disasters, at present, most mines adopt a few static indexes (such as structure, gas, soft stratification, drill chip desorption indexes, initial rate of gas emission from drill holes, drill chip amount and the like) to carry out risk prediction, and the problems of single index, non-dynamic state in time, discontinuous space and the like, insufficient and timely analysis of hidden danger information and the like exist, so that the prediction accuracy is low; meanwhile, although the original coal mine monitoring system plays a role in reducing gas accidents to a certain extent, a lot of immature and incomplete places exist overall, the monitoring system can only perform simple conversion, storage, display and printing on original data, the data resource mining and analysis depth is not enough, major disaster hidden dangers cannot be found in time, and the early warning function of the whole system is not strong.
Therefore, in order to solve the above technical problems, it is necessary to provide a new technical means.
Disclosure of Invention
In view of the above, the invention aims to provide an intelligent early warning method for coal and gas outburst based on multi-source information fusion, aiming at the problems that the multi-source information fusion degree of the coal and gas outburst is not high, an early warning model is relatively solidified, the self-analysis and optimization capability is not enough, the early warning intelligence level is not high, and the like, the method combining association rules and an evidence theory algorithm is adopted, so that the automatic screening of the early warning indexes of the coal and gas outburst, the automatic fusion analysis and decision of multiple indexes, the automatic tracing of the early warning reasons and the dynamic updating and optimization of the model are realized, the intelligent early warning of the coal and gas outburst is realized, and the accuracy.
The invention provides an intelligent early warning method for coal and gas outburst based on multi-source information fusion, which comprises the following steps:
s1, collecting historical data of coal and gas outburst, and carrying out normalization processing on the collected historical data to obtain a historical early warning index;
s2, performing association analysis on the historical early warning indexes by adopting an association rule algorithm, and calculating the support degree and confidence degree of each historical early warning index;
s3, establishing a coal and gas outburst early warning index optimization rule based on the association rule, and performing early warning index optimization;
s4, establishing a confidence coefficient distribution rule of the early warning index;
and S5, acquiring real-time indexes of coal and gas outburst, calculating the real-time indexes to obtain confidence degrees of the real-time indexes, forming a confidence degree distribution table of the real-time indexes, performing evidence synthesis on the real-time indexes by adopting an evidence theory algorithm to obtain decision results, and issuing early warning results of the coal and gas outburst according to the decision results.
Further, the method also includes step S6:
and S6, analyzing the early warning result by adopting an expert judgment method, recalculating the confidence coefficient of the historical early warning index according to the analysis result and the association rule algorithm, adjusting the confidence coefficient distribution rule, and returning to the step S1.
Further, step S2 specifically includes:
s21, determining an association rule item of the historical early warning index:
let the item be imThe set of terms is I, wherein,m=1,2,…,k,I={i1,i2,…,ikitem is represented by an early warning index ZnForming;
if the early warning index Z isnIs a qualitative index, then an early warning index Z is givennIs an item;
if the early warning index Z isnAs a quantitative index, Zn≥Zn0+ L.j or Zn≤Zn0+ l.j is an item, where j ═ 1,2, …, k, Zn0Is an early warning index ZnL is the analysis step length;
let T be a transaction set, which is a non-empty subset of item set I, | T | be item set frequency;
s22, constructing an association rule algorithm model: defining association rulesA is a rule precondition and represents an early warning index, and B is a rule result and represents that the rule result has a prominent danger;
calculating support degree S and confidence degree C:
and dividing the association rules according to the support degree and the confidence degree:
firstly, a rule with high support degree and high confidence level is considered as a strong association rule; secondly, a rule with low support degree and high confidence level is considered as a strong association rule if the rule is a qualitative index, and is considered as a weak association item if the rule is a quantitative index; thirdly, considering the rule as a weak association rule with high support degree and low confidence coefficient; and fourthly, considering the rule as a weak association rule with low support degree and low confidence coefficient.
Further, step S3 specifically includes:
determining a minimum support Smin:
determining a minimum confidence Cmin;
Determining a preferred rule:
if the support degree S is larger than or equal to SminIf the support degree of the association rule is high, otherwise, the support degree is low;
if the confidence coefficient C is more than or equal to CminIf the confidence level of the association rule is high, otherwise, the confidence level is low;
and screening the early warning indexes according to the optimal rule.
Further, step S4 specifically includes:
s41, establishing a coal and gas outburst early warning grade: green, orange and red grades, and the early warning grade is increased in sequence;
s42, establishing an evidence theory identification framework theta: Θ is { red, orange, green }, and the evidence theorizes that the probability of identifying the frame Θ is 2Θ→[0,1]And satisfies the function p ofAnd isWhere X is a subset of the evidence theory recognition framework and p (X) assigns a value for confidence, then: evidence theory identifies a subset of the framework as: { red }, { orange }, { green }, and Θ, the confidence interval for each subset is:
s43, if the early warning index is a qualitative index:
if the early warning index Z isnWhen the expressed phenomenon appears, the confidence C of the index is assigned to the subset { red } or { orange }, and the residual probability 1-C is assigned to the subset theta;
if the early warning index Z isnWhen the phenomenon is not present, the phenomenon will beAll probabilities of the early warning indicator are assigned to the subset Θ;
if the early warning index is a quantitative index:
the early warning indexes are divided into 3 intervals: zn∈[Z0,+∞)、Zn∈[λ·Z0,Z0)、Zn∈(-∞,λ·Z0) Wherein Z is0Is an index critical value, and lambda is a field coefficient;
and distributing the confidence C of the early warning index to the subset corresponding to the dynamically acquired index value belonging interval, and distributing the residual probability 1-C to other subsets.
Further, step S5 specifically includes:
constructing an evidence synthesis formula:
x1, X2, …, Xn denote n subsets of recognition frameworks,
establishing a decision value calculation model:
calculating a decision value g (X) for the subset X1, X2, …, Xn according to a decision value calculation modelq) If:
g(Xq) Max { g ({ red }), g ({ orange }), g ({ green }) }, then XqTo fuse the early warning results, q represents the subset red, orange, or green.
Further, step S6 specifically includes:
finding out the basic confidence degree assigned value m with the maximum focal element corresponding to the early warning resultnIf m isn-mn′And (c) not more than n ', wherein n is not equal to n ', and is a preset threshold value, the indexes corresponding to the evidence n and the evidence n ' are the early warning reasons, otherwise, only the index corresponding to the evidence n is the early warning sourceThus;
and after the early warning result is issued, periodically evaluating the early warning accuracy by adopting an expert judgment method, and adjusting the model parameters according to the evaluation result and the newly added historical data.
The invention has the beneficial effects that: according to the invention, aiming at the problems of low fusion degree of multi-source information of coal and gas outburst, relative solidification of early warning models, insufficient self-analysis and optimization capability, low intelligent level of early warning and the like, a method combining association rules and an evidence theory algorithm is adopted, so that automatic screening of coal and gas outburst early warning indexes, automatic fusion analysis and decision of multi-indexes, automatic tracing of early warning reasons and dynamic updating optimization of the models are realized, intelligent early warning of coal and gas outburst is realized, and the accuracy of early warning results is ensured.
Drawings
The invention is further described below with reference to the following figures and examples:
FIG. 1 is a flow chart of the present invention.
Detailed Description
The invention is described in further detail below with reference to the drawings of the specification:
the invention provides an intelligent early warning method for coal and gas outburst based on multi-source information fusion, which comprises the following steps:
s1, collecting historical data of coal and gas outburst, and carrying out normalization processing on the collected historical data to obtain a historical early warning index;
s2, performing association analysis on the historical early warning indexes by adopting an association rule algorithm, and calculating the support degree and confidence degree of each historical early warning index;
s3, establishing a coal and gas outburst early warning index optimization rule based on the association rule, and performing early warning index optimization;
s4, establishing a confidence coefficient distribution rule of the early warning index;
s5, collecting real-time indexes of coal and gas outburst, calculating the real-time indexes to obtain confidence degrees of the real-time indexes, forming a confidence degree distribution table of the real-time indexes, carrying out evidence synthesis on the real-time indexes by adopting an evidence theory algorithm to obtain a decision result, and distributing early warning results of the coal and gas outburst according to the decision result.
In this embodiment, the method further includes step S6:
s6, analyzing the early warning result by adopting an expert judgment method, recalculating the confidence coefficient of the historical early warning index according to the analysis result and the association rule algorithm, adjusting the confidence coefficient distribution rule, returning to the step S1, and taking the current early warning index as the historical early warning index, specifically:
finding out the basic confidence degree assigned value m with the maximum focal element corresponding to the early warning resultnIf m isn-mn′The index corresponding to the evidence n and the evidence n 'is an early warning reason if the threshold value is not more than n', otherwise, only the index corresponding to the evidence n is the early warning reason;
after the early warning result is issued, an expert judgment method is adopted to periodically evaluate the early warning accuracy, and the model parameters are adjusted according to the evaluation result and the newly added historical data.
In this embodiment, step S2 specifically includes:
s21, determining an association rule item of the historical early warning index:
let the item be imThe term set is I, wherein m is 1,2, …, k, I is { I ═ I1,i2,…,ikItem is represented by an early warning index ZnForming;
if the early warning index Z isnIs a qualitative index, then an early warning index Z is givennIs an item;
if the early warning index Z isnAs a quantitative index, Zn≥Zn0+ L.j or Zn≤Zn0+ l.j is an item, where j ═ 1,2, …, k, Zn0Is an early warning index ZnL is the analysis step length;
let T be a transaction set, which is a non-empty subset of item set I, | T | be item set frequency;
s22, constructing an association rule algorithm model: defining association rulesA is a rule precondition and represents an early warning index, and B is a rule result and represents that the rule result has a prominent danger;
calculating support degree S and confidence degree C:
and dividing the association rules according to the support degree and the confidence degree:
firstly, a rule with high support degree and high confidence level is considered as a strong association rule; secondly, a rule with low support degree and high confidence level is considered as a strong association rule if the rule is a qualitative index, and is considered as a weak association item if the rule is a quantitative index; thirdly, considering the rule as a weak association rule with high support degree and low confidence coefficient; and fourthly, considering the rule as a weak association rule with low support degree and low confidence coefficient. For example:
the early warning indexes comprise:
drill cutting desorption index K1Maximum drill cuttings quantity SmaxGas emission index V, coal thickness change rate M, whether take place power phenomenon D, whether be in structure influence district G etc. wherein, whether take place power phenomenon D, whether be in structure influence district G is qualitative index, as shown in Table 1:
TABLE 1
In table 1, the 1 st to 10 th groups of data are history data, and the 11 th group of data are real-time index data;
in this embodiment, step S3 specifically includes:
determining a minimum support Smin:
determining a minimum confidence Cmin;
Determining a preferred rule:
if the support degree S is larger than or equal to SminIf the support degree of the association rule is high, otherwise, the support degree is low;
if the confidence coefficient C is more than or equal to CminIf the confidence level of the association rule is high, otherwise, the confidence level is low;
screening the early warning indexes according to the optimization rule, wherein the value of each parameter is determined according to the actual state of the site, for example, α is 0.8, Cmin0.7, then Smin=0.48,CminThe parameters set by the association rule item are as in table 2:
TABLE 2
Through the calculation of the method, the confidence coefficient and the critical value of the early warning index based on the association rule are as shown in a table 3:
TABLE 3
In this embodiment, step S4 specifically includes:
s41, establishing a coal and gas outburst early warning grade: green, orange and red grades, and the early warning grade is increased in sequence;
s42, establishing an evidence theory identification framework theta: Θ is { red, orange, green }, and the evidence theorizes that the probability of identifying the frame Θ is 2Θ→[0,1]And satisfies the function p ofAnd isWhere X is a subset of the evidence theory recognition framework and p (X) assigns a value for confidence, then: evidence theory identifies a subset of the framework as: { red }, { orange }, { green }, and Θ, the confidence interval for each subset is:
s43, if the early warning index is a qualitative index:
if the early warning index Z isnWhen the expressed phenomenon appears, the confidence C of the index is assigned to the subset { red } or { orange }, and the residual probability 1-C is assigned to the subset theta;
if the early warning index Z isnWhen the phenomenon is not presented, all probabilities of the early warning index are distributed to the subset theta;
if the early warning index is a quantitative index:
the early warning indexes are divided into 3 intervals: zn∈[Z0,+∞)、Zn∈[λ·Z0,Z0)、Zn∈(-∞,λ·Z0) Wherein Z is0Is an index critical value, and lambda is a field coefficient;
the confidence degree C of the early warning index is assigned to the subset corresponding to the dynamically acquired index value belonging interval, and then the remaining probabilities 1-C are assigned to other subsets, based on the above example, as shown in tables 4 and 5:
TABLE 4 basic confidence assignment rules
TABLE 5 basic confidence coefficient
Coefficient of performance1To4All are confidence distribution coefficients;
in this embodiment, step S5 specifically includes:
constructing an evidence synthesis formula:
establishing a decision value calculation model:
calculating a decision value g (X) for the subset X1, X2, …, Xn according to a decision value calculation modelq) If:
g(Xq) Max { g ({ red }), g ({ orange }), g ({ green }) }, then XqTo fuse the early warning results, q represents the subset red, orange, or green.
Specifically, the method comprises the following steps: the basic probability distribution for group 11 data is shown in table 6:
TABLE 6
TABLE 7
Table 7 shows the evidence synthesis results, and it can be seen from this table that: the subset { red } is a final early warning result, which indicates that the working face has outstanding danger, and the prediction result is accurate after the prediction and the actual working condition verification of the method.
Finally, the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all of them should be covered in the claims of the present invention.
Claims (7)
1. An intelligent early warning method for coal and gas outburst based on multi-source information fusion is characterized in that: the method comprises the following steps:
s1, collecting historical data of coal and gas outburst, and carrying out normalization processing on the collected historical data to obtain a historical early warning index;
s2, performing association analysis on the historical early warning indexes by adopting an association rule algorithm, and calculating the support degree and confidence degree of each historical early warning index;
s3, establishing a coal and gas outburst early warning index optimization rule based on the association rule, and performing early warning index optimization;
s4, establishing a confidence coefficient distribution rule of the early warning index;
and S5, acquiring real-time indexes of coal and gas outburst, calculating the real-time indexes to obtain confidence degrees of the real-time indexes, forming a confidence degree distribution table of the real-time indexes, performing evidence synthesis on the real-time indexes by adopting an evidence theory algorithm to obtain decision results, and issuing early warning results of the coal and gas outburst according to the decision results.
2. The intelligent early warning method for coal and gas outburst based on multi-source information fusion according to claim 1, which is characterized in that: further comprising step S6:
and S6, analyzing the early warning result by adopting an expert judgment method, recalculating the confidence coefficient of the historical early warning index according to the analysis result and the association rule algorithm, adjusting the confidence coefficient distribution rule, and returning to the step S1.
3. The intelligent early warning method for coal and gas outburst based on multi-source information fusion according to claim 1, which is characterized in that: in step S2, the method specifically includes:
s21, determining an association rule item of the historical early warning index:
let the item be imThe term set is I, wherein m is 1,2, …, k, I is { I ═ I1,i2,…,ikItem is represented by an early warning index ZnForming;
if the early warning index Z isnIs a qualitative index, then an early warning index Z is givennIs an item;
if the early warning index Z isnAs a quantitative index, Zn≥Zn0+ L.j or Zn≤Zn0+ l.j is an item, where j ═ 1,2, …, k, Zn0Is an early warning index ZnL is the analysis step length;
let T be a transaction set, which is a non-empty subset of item set I, | T | be item set frequency;
s22, constructing an association rule algorithm model: defining association rulesA is a rule precondition and represents an early warning index, and B is a rule result and represents that the rule result has a prominent danger;
calculating support degree S and confidence degree C:
and dividing the association rules according to the support degree and the confidence degree:
firstly, a rule with high support degree and high confidence level is considered as a strong association rule; secondly, a rule with low support degree and high confidence level is considered as a strong association rule if the rule is a qualitative index, and is considered as a weak association item if the rule is a quantitative index; thirdly, considering the rule as a weak association rule with high support degree and low confidence coefficient; and fourthly, considering the rule as a weak association rule with low support degree and low confidence coefficient.
4. The intelligent early warning method for coal and gas outburst based on multi-source information fusion according to claim 3, characterized in that: step S3 specifically includes:
determining a minimum support Smin:
determining a minimum confidence Cmin;
Determining a preferred rule:
if the support degree S is larger than or equal to SminIf the support degree of the association rule is high, otherwise, the support degree is low;
if the confidence coefficient C is more than or equal to CminIf the confidence level of the association rule is high, otherwise, the confidence level is low;
and screening the early warning indexes according to the optimal rule.
5. The intelligent early warning method for coal and gas outburst based on multi-source information fusion according to claim 4, characterized in that: step S4 specifically includes:
s41, establishing a coal and gas outburst early warning grade: green, orange and red grades, and the early warning grade is increased in sequence;
s42, establishing an evidence theory identification framework theta: Θ is { red, orange, green }, and the evidence theorizes that the probability of identifying the frame Θ is 2Θ→[0,1]And satisfies the function p ofAnd isWhere X is a subset of the evidence theory recognition framework and p (X) assigns a value for confidence, then: evidence theory identifies a subset of the framework as: { red }, { orange }, { green }, and Θ, the confidence interval for each subset is:
s43, if the early warning index is a qualitative index:
if the early warning index Z isnWhen the expressed phenomenon appears, the confidence C of the index is assigned to the subset { red } or { orange }, and the residual probability 1-C is assigned to the subset theta;
if the early warning index Z isnWhen the phenomenon is not presented, all probabilities of the early warning index are distributed to the subset theta;
if the early warning index is a quantitative index:
the early warning indexes are divided into 3 intervals: zn∈[Z0,+∞)、Zn∈[λ·Z0,Z0)、Zn∈(-∞,λ·Z0) Wherein Z is0Is an index critical value, and lambda is a field coefficient;
and distributing the confidence C of the early warning index to the subset corresponding to the dynamically acquired index value belonging interval, and distributing the residual probability 1-C to other subsets.
6. The intelligent early warning method for coal and gas outburst based on multi-source information fusion according to claim 5, characterized in that: step S5 specifically includes:
constructing an evidence synthesis formula:
establishing a decision value calculation model:
calculating a decision value g (X) for the subset X1, X2, …, Xn according to a decision value calculation modelq) If:
g(Xq) Max { g ({ red }), g ({ orange }), g ({ green }) }, then XqTo fuse the early warning results, q represents the subset red, orange, or green.
7. The intelligent early warning method for coal and gas outburst based on multi-source information fusion according to claim 5, characterized in that: step S6 specifically includes:
finding out the basic confidence degree assigned value m with the maximum focal element corresponding to the early warning resultnIf m isn-mn' is less than or equal to, wherein n is not equal to n ', and is a preset threshold value, the indexes corresponding to the evidence n and the evidence n ' are early warning reasons, otherwise, only the index corresponding to the evidence n is the early warning reason;
and after the early warning result is issued, periodically evaluating the early warning accuracy by adopting an expert judgment method, and adjusting the model parameters according to the evaluation result and the newly added historical data.
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