Assuming that there is a set I containing all items, a subset X of   I is called the item set. Supposing the database D = { t 1 , t 2 , … , t m } contains all the fault records. An association rule can be expressed as X → T , which means that if the item set X appears, the target   T will also occur.

The establishment of association rules generally depends on the discovery of the large item sets as well as the frequent rules, and the selection criteria for them are called the significance selecting criteria. The most commonly-used significance selecting criterion is called the support ( s u p p ( X ) ) , which describes the proportion of X in D (Hipp et al., 2000). In addition, there are some evaluation criteria focusing on the selection of frequent rules. The confidence ( c o n f ( X → T ) ) refers to the proportion of X that contains T   simultaneously (Doostan and Chowdhury, 2017); The rule power factor ( r b f ( X → T ) ) measures the weight of confidence by X → T (Hipp et al., 2000); The certainty factor ( c f ( X → T ) ) measures the change degree of the probability of T appearing simultaneously in the rules containing X (Ochin et al., 2016). Based on the aforementioned criteria, if the score of the item sets or rules can meet or above the corresponding thresholds, these item sets and rules will be considered as the large item sets and frequent rules.

Among the input components, there are often some that occur less frequently. However, a part of these rare feature quantity values will also lead to transformer failures, then cause serious losses. Therefore, those HILP components cannot be simply ignored. The standard ARM algorithm employs the same and fixed score calculation methods of significance selecting criteria, which makes the rare variables be discarded directly without any analyses. Therefore, based on the standard significance selecting criteria, this paper designs the weighted significance selecting criteria that consider the rare variables.

In the ARM, large item sets and frequent rules are filtered by a uniform calculation approach which results in the dominance of common components that account for a large proportion of the database. In other words, rare components along with the HILP components will be screened out. In order to properly handle these rare data, this paper establishes four weighted significance selecting criteria.

Firstly, an association rule can be redefined as: X f + X r → T (2) where X f and X r represent the item sets containing common components and rare components, respectively.

If the association rule contains at least one rare element in a feature a j , the weighted significance selecting criteria can be built as: sup p j = | t i ∈ H ( i , 1 ) ; X f ⊆ G ≠ 0 ; H ( i , j ) ∈ X r ≠ ϕ | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ X r ≠ ϕ | × 100 % (3) c o n f j , β = | t i ∈ H ( i , 1 ) ; X f ⊆ G ≠ 0 ; H ( i , j ) ∈ X r ≠ ϕ ; H ( i , n + 1 ) = T ( β ) | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ X r ≠ ϕ | × 100 % (4) r p f j , β = | t i ∈ H ( i , 1 ) ; X f ⊆ G ≠ 0 ; H ( i , j ) ∈ X r ≠ ϕ ; H ( i , n + 1 ) = T ( β ) | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ X r ≠ ϕ | ⋅ c o n f j , β × 100 % (5) c f j , β = ( c o n f j , β − | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ X r ≠ ϕ ; H ( i , n + 1 ) = T ( β ) | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ X r ≠ ϕ | ) ( | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ X r ≠ ϕ ; H ( i , n + 1 ) ≠ T ( β ) | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ X r ≠ ϕ | ) × 100 % (6) where G 1 × n = H ( i , 2 ∼ ( n + 1 ) ) ; | ⋅ | represents the cardinality of the fault event records that meet all the inside conditions; T ( β )   denotes the states under study. For the confidence, rule power factor, and certainty factor, the superscript β shows that there are seven different forms of these criteria corresponding to seven different transformer states.

Since different components in each feature have different impacts on the states of a transformer, further investigation of the relative magnitude of the risk weight of each component is indispensable. In most current studies, the evaluation of risk weights relies on the proportion in a database or the frequency of occurrence. However, they are not equal to the influence of a component on the state of the entire transformer. Therefore, the relative risk weights of each component are determined based on the degree of influence on the transformer itself in this paper.

This paper describes the overall fault risk of a transformer based on the system risk structure theory, and the principle of the CIM is utilized to describe the impact of different components, so as to design the risk weight evaluation model. For the purpose of distinguishing the relative risk weights of rare components, this paper forms two independent processing subspaces of H :   S f   contains all the records, while S j r only includes the records of either rare component in a certain feature a j . In addition, a j f and a j r represent all the common and rare components in that feature, respectively.

The CIM can measure the impact of each component on the overall risks. In this paper, the risk of a component, that is, the risk of an element e j , k , means that a fault event is related to that element e j , k in a feature a j . The overall risk of a transformer indicates the comprehensive likelihood of a failure in that transformer. This paper deploys two CIM indicators. The risk achievement worth (RAW) (Vesely et al., 1983) describes the relative rise in the overall risk due to the presence of elements e j , k , and its mathematical expression is: I RAW ( e j , k ) = 1 − R ( 0 k , p ) 1 − R ( p ) (7) where 1 − R ( 0 k , p ) denotes the overall risk when the element e j , k is confirmed to be related; 1 − R ( p ) represents the overall risk.

Similarly, the risk reduction worth (RRW) (Vesely et al., 1983) represents the relative decline in the overall risk if the element e j , k does not appear, and its mathematical expression is: I RRW ( e j , k ) = 1 − R ( p ) 1 − R ( 1 k , p ) (8) where 1 − R ( 1 k , p ) denotes the overall risk when the element e j , k is ensured to be irrelevant.

In a fault record, even if a component changes, this fault may no longer occur. Ergo, the occurrence of the fault requires that all the corresponding elements of each feature in this record are confirmed to be relevant. Based on this, the mathematical form of the overall risk can be written as: 1 − R ( p ) = 1 − ∏ j = 2 n + 1 R ( 1 k , p ) = 1 − ∏ j = 2 n + 1 ( ∑ i = 2 | t i ∈ S j r | | t i ∈ H ( i , 1 ) ; H ( i , j ) = e j , k ; H ( i , j ) ∈ X r | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ a j | ) (9)

In this paper, the relative risk weight of an element e j , k is composed of two parts, which can be expressed as: ω e j , k = ω j , k f + ω j , k r (10) where ω j , k   f represents the risk caused by common elements, ω j , k r represents the risk from rare elements.

The mathematical expression of ω j , k   f is: ω j , k f = { 0 , if     e j , k ∈ a j f ∑ i = 2 | t i ∈ S f | | H ( i , j ) = e j , k | | m | , if     e j , k ∈ a j r (11)

This paper selects the mean value of the impact of formula (7-8) to measure the risk from rare elements, so ω j , k r can be expressed as: ω j , k r = { ( A RAW + A RRW ) / 2 , if     e j , k ∈ a j r 0 ,   if     e j , k ∈ a j f (12) where A RAW and A RRW illustrates the risks from the risk increase and the risk decrease, respectively, and namely: A RAW = 1 − ∏ k = 1 l ( ∑ i = 2 | t i ∈ S j r | | t i ∈ H ( i , 1 ) ; H ( i , j ) = e j − k ; H ( i , j ) ∈ X r | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ a j | ) 1 − ∏ j = 2 n + 1 ( ∑ i = 2 | t i ∈ S j r | | t i ∈ H ( i , 1 ) ; H ( i , j ) = e j − k ; H ( i , j ) ∈ X r | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ a j | ) A RRW = 1 − ∏ j = 2 n + 1 ( ∑ i = 2 | t i ∈ S j r | | t i ∈ H ( i , 1 ) ; H ( i , j ) = e j − k ; H ( i , j ) ∈ X r | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ a j | ) 1 − ∏ k = 1 l ( ∑ i = 2 | t i ∈ S j r | | t i ∈ H ( i , 1 ) ; H ( i , j ) ≠ e j − k ; H ( i , j ) ∈ X r | | t i ∈ H ( i , 1 ) ; H ( i , j ) ∈ a j | ) (13)

During the application of the diagnosis method, the occurrence of failures varies in different periods. Moreover, with the increase in application time, the parameters ought to be adjusted according to the previous performance to further improve the accuracy of weight evaluations.

In this paper, 1 year is supposed as a research cycle. Therefore, let   D y ∈ D = { D 1 , D 2 , ⋯ , D y , ⋯ , D Z } denote the records of 1 year in the database D , that is, the records of all faults within that year. Thus, the parameters in the model will be dynamically modified per year, which is shown in Figure 1.

To start with, the initial parameters can be determined from the previous knowledge or engineering experiences. Next, the parameters will be amended in line with the diagnosis performance of the previous cycle. If the actual number of faults in the investigated system is higher than the predicted number of faults according to the comparison between the predicted results and the actual consequences at the end of a year y . In this case, the model needs to “identify” more faults in the next period y + 1 , i.e., the thresholds of significance selecting criteria should be reduced. Therefore, the threshold needs to be adjusted downward compared to their foregoing values in y . On the contrary, when the actual number of faults is less than the predicted numbers, the thresholds need to be updated upward. In summary, the dynamic adjustment of the method is achieved by resetting the threshold of the significance selecting criteria. Also, the importance scores solved by the weighted criteria calculation method are updated directly in accordance with the new annual database D y + 1 . By combining these two, the proposed approach can be updated based on the rules via the different years of input data.

In this case study, the transformer maintenance records from a high-voltage transmission system in a central province of China are selected as input data. The total number of sample records is 1,564 which covers the contents of five gases (H₂, CH₄, C₂H₂, C₂H₄, C₂H₆) and relative gas production rates of two (CO, CO₂). Seven states of a transformer (normal operation, low temperature overheating, medium temperature overheating, high temperature overheating, low energy discharge, high energy discharge, and partial discharge) are incorporated as the target.

In this paper, two 10-fold cross-validation test cases are generated: the general case which is conducted separately according to all states of a transformer; the state case that studies the individual influence of the events by each kind of the state.

When comparing the diagnosis results with the test data, the receiver operating characteristic (ROC) and the precision-recall (PR) curves are deployed to validate the performance (Ziege, 2012). On the basis of these two curves, the area under the curve (AUC) (Swets, 2016) is implemented as the performance indicator, and the higher the AUC value is, the more accurate the diagnosis will be.

In the very beginning, this paper takes all types of transformer faults as a whole, and applies the WARM-based DGA method to diagnose whether the transformer is faulty or not, i.e., the transformer has only two states: faulty and normal operation.

To verify the effectiveness of both the significance selecting and risk weight evaluation enhancements in the proposed WARM model, two standard ARM algorithms are taken for comparison: the Relim and the Apriori methods. These two algorithms are different in item searching, recording, and sorting, whereas sharing similar procedures in significance selecting and weight evaluation steps. In that case, two DGA techniques (WARM(Relim), WARM(Apriori)) that adopt the improved significance selecting criteria and risk weight evaluation model but apply the Relim and the Apriori algorithms, respectively, will be compared with the two standard forms (WARM(Relim), ARM(Apriori)). The comparison of the ROC and PR curves of these DGA methods are shown in Figure 2.

It can be concluded from Figure 2 that the WARM method which is based on the refined significance selecting criteria and risk weight evaluation model can achieve more accurate transformer fault diagnoses than the ARM model. It can be concluded that the accuracy of the results obtained by the Relim and the Apriori algorithms is relatively close. That is, these two algorithms cannot notably improve the diagnosis precision compared with each other. However, compared with the DGA method based on the ARM, the AUC of the ROC and PR curves of both two algorithms with the WARM model is raised by 19.6 and 14.1% on average. This indicates that the proposed WARM model can successfully enhance the diagnostic performance for either one of the two algorithms.

Next, the separate diagnoses of all the seven states are carried out, and the comparison is illustrated in Figure 3, where NO-normal operation, LTO-low temperature overheating, MTO-medium temperature overheating, HTO-high temperature overheating, LED-low energy discharge, HED-high energy discharge, and PD-partial discharge are applied.

From Figure 3, the enhancements in diagnoses performance can be achieved via the significance selecting and risk weight evaluation in the WARM model for all the seven transformer conditions. Among them, the diagnosis of the LTO is the most precise one whereas the HED gets the lowest scores in both two evaluations. According to the input database, the HED events seldom happen in recent years while the LTO is one most frequent events. This is in line with the different data volumes of each transformer state, so as the performance. Nevertheless, the significant enhancement of the HED is conducted through the WARM model. Ergo, the benefits of the WARM can be verified especially when the input data is limited. Furthermore, the WARM-based method is also able to operate during some extreme scenarios.