The present invention relates to the technical field of high speed train system safety, and particularly relates to a complex network-based high speed train system safety evaluation method.
With development of high speed railways, safety issues of motor train units have also received extensive attention. For the study on safety of high speed rail trains, the “frequency-consequence” matrix method is more mature and is also a method used most widely. The frequency and the consequence in the matrix method are given according to experience of experts, which are more subjective.
A support vector machine (SVM) has a simple structure, a fast learning speed, good promotion performance, a unique minimal point during optimization solution and the like. The SVM is proposed in order to solve a two-classification problem; for a multi-classification problem, the SVM algorithm has one disadvantage: when a voting result is a tie, a safety level of a sample cannot be judged correctly. Weighted kNN (k neighbors) is re-judging a sample that cannot be classified accurately by the SVM, that is, for k categories, a category to which a sample point is close is judged, and the sample point is classified into the category.
Compared with the high speed rail safety evaluation method relatively common at present, that is, the matrix method, the weighted kNN-SVM-based safety evaluation method eliminates subjective factors in the matrix method from the position of a component in the system and reliability of the component, and thus has significant practical values and promotion significance for evaluation of high speed rail safety.
An objective of the present invention is to provide a complex network-based high speed train system safety evaluation method, including the following steps:
Step 1, constructing a network model G(V, E) of a high speed train according to a physical structure relationship of the high speed train, in which
1.1. components in a high speed train system are abstracted as nodes, that is, V={vi, v2, . . . , vn}, in which V is a set of nodes, vi is a node in the high speed train system, and n is the number of the nodes in the high speed train system;
1.2. physical connection relationships between components are abstracted as connection sides, that is, E={e12, e13, . . . , eij}, i,j≦n; in which E is a set of connection sides, and eij is a connection side between the node i and the node j;
1.3. a functional attribute degree value {tilde over (d)}i of a node is calculated based on the network model of the high speed train: a functional attribute degree of the node i is
{tilde over (d)}i=λi*ki (1)
in which λi is a failure rate of the node i, and ki is the degree of the node i in a complex network theory, that is, the number of sides connected with the node;
Step 2, by mean of analyzing operational fault data of the high speed train and combining a physical structure of the high speed train system, extracting the functional attribute degree value {tilde over (d)}i, the failure rate λi and Mean Time Between Failures (MTBF) of the component as a training sample set, to normalize the training sample set, in which
2.1. a calculation formula of the failure rate λi is
2.2. the MTBF is obtained from fault time recorded in the fault data, that is,
2.3. samples are trained by using a SVM;
dividing safety levels of the samples by using a kNN-SVM; in which
training samples in k safety levels are differentiated in pairs, and an optimal classification face is established for
SVM classifiers respectively, of which an expression is as follows:
in which 1 is the number of samples in the ith safety level and the jth safety level, K(xij, x) is a kernel function, x is a support vector, at is a weight coefficient of the SVM, and bij is an offset coefficient;
3.2. for a component to be tested, a safety level of the component is voted by combining the above two kinds of classifiers and using a voting method; the kind with the most votes is the safety level of the component;
3.3. as an operating environment of the high speed train system is complicated, it is easy to lead to a situation where classification is impossible when classification is carried out by using the SVM; therefore, a weighted kNN-based discrimination function is defined, and safety levels of the components are divided once again, which includes steps as follows:
in a training set {xi, yi}, . . . , {xn, yn}, there is a total of one safety level, that is, ca1, ca2, . . . , ca1, a sample center of the ith safety level is
in which ni is the number of samples of the ith safety level, and the Euclidean distance from a component xj to the sample center of the ith safety level is
in which, in the formula: xjm is an mth feature attribute of a jth sample point in a test sample; and cim is an mth feature attribute in an ith-category sample center;
a distance discrimination function is defined as
tightness of weighted kNN-based different-category samples is defined as
in which m is the number of k neighbors; ui(x) is the tightness membership degree at which a test sample belongs to the ith training data; and ui(x(j)) is the membership degree at which the jth neighbor belongs to the ith safety level, that is,
and
a classification discrimination function of the sample point is
di(x)=si(x)×μi(x) (6)
the tightness di(x) at which a sample belongs to each safety level is calculated, and the category with the greatest value of di(x) is a sample point prediction result.
Safety of the high speed train is divided into levels as follows according to Grade-one and Grade-two repair regulations and fault data records of a motor train unit:
that is, Safety Level 1 corresponding to y=1 is Safe, which includes running states of the train: Not Affected, Continue Running; Safety Level 2 corresponding to y=5 is Safer, which includes running states of the train: Temporary Repair and Odd Repair, Behind Schedule; Safety Level 3 corresponding to y=10 is Not Safe, which includes running states of the train: Out of Operation and Not Out of the Rail Yard.
Beneficial effects of the present invention are as follows: compared with the prior art, the method utilizes a complex network to extract a functional attribute degree of a node, extracts a failure rate, MTBF and other features according to fault data, and carries out training through a SVM; as the SVM has an unclassifiable problem for the multi-classification problem, importance of the position of the node in the system is taken into account; a sample point is checked by introducing a weighted kNN-SVM, influences of the component on safety of the high speed train system is obtained at last, a more accurate classification result can be obtained, judgment on safety of the high speed train is verified, and the verification result shows that the method has high practical values.
The present invention provides a complex network-based high speed train system safety evaluation method, and the present invention is further described below with reference to the accompanying drawings.
A functional attribute degree {tilde over (d)}i=λi·ki of a node is selected as an input quantity from the perspective of the structure of the component based on the network model of the bogie (Step 1.3); a failure rate λi and MTBF are selected as input quantities from the perspective of reliability attribute of the component in combination with operational fault data of the high speed train (Steps 2.1 and 2.2). For the same component in the high speed train bogie system, {tilde over (d)}i, λi and MTBF thereof in different operation kilometers are calculated respectively as a training set. For example, when the train runs to 2450990 kilometers, a gearbox assembly of a node 14 has {tilde over (d)}14,1=0.027004, λ14,1=0.013502, MTBF14,1=150.2262. Safety levels of the high speed train are divided into three levels according to Grade-one and Grade-two repair regulations and fault data records of a motor train unit, that is, y=1 is Safe, y=5 is Safer, and y=10 is Not Safe.
By taking a component gearbox assembly as an example, three safety levels of the gearbox assembly, that is, a total of 90 groups of input quantities, are selected as a training set, SVM training is carried out by using an LIBSVM software package, and the accuracy of the calculation result is only 55.7778%. It is found through analysis that an operating environment of the high speed train is relatively complicated, a situation where classification is impossible often occurs when classification is carried out by using a SVM (as shown in
A sample center
of each of the three levels of the gearbox assembly that affect safety of the system and a distance
from a sample to be tested x(0.02746, 0.01443, 200.75) to the three safety levels are calculated. Then, the following calculation is carried out step by step in the three safety levels: i=1, 2, 3
Finally, a classification discrimination function gi(x)=si(x)×μi(x) of each of the three safety levels is calculated, and it is obtained that a final classification result of a test sample (as shown in
Number | Date | Country | Kind |
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2014 1 0768888 | Dec 2014 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2015/095721 | 11/27/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/091084 | 6/16/2016 | WO | A |
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6212954 | Albertini | Apr 2001 | B1 |
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102521432 | Jun 2012 | CN |
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Number | Date | Country | |
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20170015339 A1 | Jan 2017 | US |