CA2002222A1 - Methods and apparatus for performing system fault diagnosis - Google Patents
Methods and apparatus for performing system fault diagnosisInfo
- Publication number
- CA2002222A1 CA2002222A1 CA002002222A CA2002222A CA2002222A1 CA 2002222 A1 CA2002222 A1 CA 2002222A1 CA 002002222 A CA002002222 A CA 002002222A CA 2002222 A CA2002222 A CA 2002222A CA 2002222 A1 CA2002222 A1 CA 2002222A1
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Classifications
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F11/00—Error detection; Error correction; Monitoring
- G06F11/22—Detection or location of defective computer hardware by testing during standby operation or during idle time, e.g. start-up testing
- G06F11/2257—Detection or location of defective computer hardware by testing during standby operation or during idle time, e.g. start-up testing using expert systems
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F11/00—Error detection; Error correction; Monitoring
- G06F11/30—Monitoring
- G06F11/34—Recording or statistical evaluation of computer activity, e.g. of down time, of input/output operation ; Recording or statistical evaluation of user activity, e.g. usability assessment
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S706/00—Data processing: artificial intelligence
- Y10S706/902—Application using ai with detail of the ai system
- Y10S706/911—Nonmedical diagnostics
Abstract
Abstract of the Disclosure A diagnostic tool based on a hybrid knowledge representation of a system during its operation is compared to an event based representation of the system which comprises a plurality of predefined events. An event is recognized when the collected data matches the event's critical parameter. The recognized event is analyzed and an associated set of ambiguity group effects, which specify components to be re-ranked in an ambiguity group according to an associated ranking effect. Additionally, a symptoms fault model and a failure model can be analyzed to determined symptom-fault relationships and failure modes which are applicable to the system operation. Each applicable system-fault relationship and failure mode is also associated with a set of ambiguity group effects which rerank the ambiguity group. A structural model is analyzed starting with the components in the ambiguity group having the greatest probability of failure. As a result of the analysis, maintenance options specifying tests to be performed on the system are output.
Description
2~ %2 247 -87 .-003 METHODS AND APPARATUS FOR PERFORMINC
S YS TEM FA ULT D IA GN OS I S
Field of the Invention The invention relate~ to method.~ and apparatus for analvzing svstems. More specificall~. it relates to a hybrid knowled~e representation o~ a SY~tem and methods for analyzing the representation to provide faster and imProved analYsis of the system~
Back~round of the Invention As the comPlexitv of man~made sY~tems increase~. the complexitY of the ta~ks involved in maintainin~ ~uch systems also increa~es. The maintenance task3 include, bv wav of example only, fault diagnosis, fault location, performance monitoring, Performance oPtimization and repair. These tasks are typicallY performed bv an expert technician, by analytical diagnostic tool~ or by a combination thereof.
ManY dia~nostic tools are known for use in maintenance tasks, however, thev are all limited in one or more respects. Early dia~nostic tools utilized snapshot monitorin~ wherein an instantaneous picture of the system under test is developed. Another test conceDt used in early dia~nostic tools wa~ stimulus~res~onse testing wherein test eaui~ment i~ used to develop appropriate stimulus waveform3 and thë resPonse of the sy~tem under test is analyzed. In fact, manY srqtems in use todav are ~till maintained and tested b~ dia~nostic tools using these techniaues.
Diagnostic tools using steadY state and stimulus-response testin~ techniques, however. are unable use the full sPectrum of information available about the svstem under test. In particular, these tools makP no use of knowledge concerning the desi~n or the prior maintenance historv of the system under test. These sY~tem~, therefore, do not provide reliable fault diagnosis of , , , .
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svstemis. Furthermore, such ~vistem~ have iseverelY limited abilitv to reason about results obtaine(1 durln~ tei~tin~
or moni tori n~ .
As a result of the llmited reasonini~ abilitY~ expert 5 systemis have been incorporated into various dia~nostic tools. In a common form, the ex~ert sv~tem uses a sur~ace knowledge representation of the sYstem unden test to anal,yze and reason about potential faulti~i in the system. Surface knowled~e repreisentatlons t~rpically 10 associate a iset of symptoms with a set of f`aults which association is f`requently presented in the form of a fault tree. Surface knowledge representation~i also ~requentlv take the form of a set of rulec~ of the I~Then form. Data or information for the ~urface knowled~e 15 representation is usuallY obtained from the expert technician or the sYstem desi~ner.
These systemi~ have had limited succe~sei~ in sim~le systems where maintenance experts have accumulated enou~h experience in maintainin~ the system to provide accurate 20 rules for most of the poi~ible sYstem faults. In cases where the system under test. iq somewhat comPlex~ however.
it is often very difficult to embody the exPert'is exPerience in a set of rules to drive the exDert sYstem, even where the expert hais had sufficient exPerienCe with 25 the complex syistem. See, for example, "The Thinkin~
Machine ~ An Electronic Clone o~ a Skilled Engineer is Very Hard To Createi', in the August 12. 1988 issiue of the Wall Street Journal on page 1, wherein the efforts of the Southern California Edison Co. to develoD an expert 30 system to dia~nose faults in one of their dams is described. The exPert sYstem w~ to be based on ~ set of rules which embodied the knowled~e of a civil en~ineer havina two decades of related experience. After a signif icant investment in time and money and af ter 35 narrowin~ the sco~e of the pro,iect, limited diai~nostic success was achieved, however. the diagnostic tool was not PUt into re~ular use~
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;3-Expert systems based on surface knowledge representations, therefore, require an exhaustive set of a priori rules which accura~ely encompa~3 the sDectrum of the pos~ible faults of the ~ystem l~nder test, to be effective. Furthermore, such expert S,Ystems per~orm poorlY when fault condition~ occur which are beYond the sur~ace knowledge heuristic rule base since there is no knowled~e base upon which further reasonin~ can occur.
Expert ~v~tems based on surface knowled~e repre~entations, therefore, offer limited reasonin~
capabilities.
Expert SYstem~ have also incorporated deep knowled~e representations of system~ under test, wherein the functional and structural qualities of a sYstem's components are qualitatively modeled to show connectivity and behavioral relationships. Thi~ aPProach enables a diagnostic tool to deal with imPrecise behavioral and structural characteristics of a sYStem, such as dynamic changes in connectivity, which can not be addressed in other approaches, thereby offering potential for greater flexibility in reasoning. Such qualitative model~ can represent the operation of a sYstem without an exhau3tive a priori enumeration of all possible failure models, as required in surface knowledge apProaches.
Diagnostic tools based on such qualitative models can, however, easilv become com~utationally unwieldlv since the number o~ comPutation~ require~ to use the qualitative model is proportional to the connectivitv of the system under test. The connectivitv of a system increases a9 a combinatorial function of the number of components~in the system, so that qualitative models which repre~ent complex sYstems havin~ many functions and components become comPutationallv untractable.
Various combinations of the previouslv di~cussed diagnostic tool~ have been ~u~ested. In Report No.
SETR-86~001 of the Software Engineerin~ Technical ReDort Series prepared by the Allied~Signal Aero~pace comPan~ a two layer expert system uqin~ a surface knowled~e , .
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re~resentation embodYin~ heuri~qtic rule~ develoDed by system maintenance exPert~ and a deeP knowled~e representation embodyin~ comDonent behavior and sYstem connectivitv i~ ~u~geqted. It iq al~qo ~u~eqte~ to use reliability stati~qtic~ a~q an ad~junct to the exDert s~stem. The ~u~,e,sted two layer exPert ~qv~qtem would first diagnose a sV~tem based on the heuristic rules of the ~urface knowledge repre~qentation. The deeD knowled~e representation i9 referenced onlY when a failure mode which ls outside the failure~q embodle~ in the rule base is encountered. The suggested two laYer expert svstem.
therefore, does not provide an inte~rated dia~nostic tool. Rather. in most ca~qes such a s~stem i~q dependent on a heuristic surface knowled~e reDresentation and the required exhaustive enumeration of a Priori rules. which can be difficult to develop. Causal reasonina with a deep knowledge repre~entation would be referenced onlv when heuristic reasonina with a surface knowled~e representation fails. The results obtained with such a dia~noqtic tool would onlY be marginally imProved since the knowledge representations are not truly inte~rated.
Furthermore, the suggested diagnostic tool failq to solve the problem of the comDutationally untractable qualitative models in the dee~ knowled~e repre~entation when such models are referred to.
A diagnostic system that combines a surface knowledge expert svstem with a deeP knowledge expert qystem was also su~ested in "The Integrated Dia~nostic Model~Toward~ a Second Generation Dia~nostic ExDert System7', published in July 1986 in the Proceedin~s of the Air Force WorkshoP on Artificial Intelli~ence Applications for Integrated Dia~nostics at Da~es 188 to 197. Thiq diagnostic tool separates the two knowledge representations until a deciqion is to be made. At the time of decision, an executor proces~ arbitrates between the two expert systems to mak~ a deci~ion. Thi~q tool.
therefore, fails to inteRrate the two tYpeq of knowled~e and has problem~ ~imilar to the ~u~ge~ted two laver expert system discussed above.
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A dia~nostic tool which provides an inteRrated knowled~e representation o~ a ~Ystem~ combinln~ a variety of knowledge representations of a system a~ well a~ other system information is needed. Such a diagnostlc tool should provide ~lexible decisions similar to those provided by expert svstems utilizine deeD knowledge representation~, but should also Provide quick and efficient decisions as well a~ imProved dia~nostic deci ~i ons .
Summary of the Invention Accordin~ to the present invention. a dia~nostic tool usin~ a hYbrid knowledae reDresentation of the system under te~t is pre~ented. An event based representation of the sYstem under test comPrises a plurality of event records that ~Pecifv predefined events that can occur in the ~ystem under te~t which are stored as a data base. The event based representation defines the temporal performance of the system under test.
A data acquisition module is provided to collect operational data from the sYStem under test which i~
compared to the event based rePre~entation to recognize predefined events that have occurred in the syste~ under te~t. An event is recognized when the critical parameter~ in the correspondin~ event recor~ are matched to a data sample from the collected oDerational data.
Each predefined event in the event based rePresentation is associated with a 3et of ambi~uitv group effects that 3pecifies components an~ ~ rankin~
effect for each sPecified comDonent. The ambi~uitY ~roup effect3 are a~plied to an ambi~uitv ~roup, which 1s a li3tin~ of com~onents in the svstem under test which are ranked accordin~ to their probability of failure. Every reco~nized event and events which are related to the recognized event~ are analvze~ to determined a ~ub~et o~
the associ2ted set of ambi~uity grouP effects to be aPplied to the ambiguitv ~roup. The analysis involves checkin~ the collected operational data to verifv the , "
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occurrence of affected ~arameter~ as de~ined in reco~nized event~ or in events relate~ t~ th~ recoRnized events. Once the subsets of ambi~uitY Krou~ eff'ect~ i9 determined, the specified component~ are re~ranked in the 5 ambiguity group accordin~ to the agsociated rankin~
effects.
In the preferred embodiment, a sYmD'com~fault model of the ~y~tem under test comprisin~ a pluralitv of symPtom~fault relationshiP3 in a data ba~e is al30 part o~ the hybrid knowledge representation. The oPeration of the sv~tem under test i~ observed and data is formatted by the observer. The observe~ dat~ i~ comPare~ t~ each sYmPtom~fault relation~hiP and anV matches are noted.
Each symptom~ault relationshiP i~ also a~ociated with a set of ambiguity group effects. The ambi~uity ~rouP
effects a~sociated with the matched symptom~fault relationships are selected and the sPecified component~
are re~ranked in the ambiguitv ~roun accordin~ to the rankin~ ef~ect.
A failure model of the svstem under test comPrisin~
a pluralitv of rules in a data ba~ which are associated with defined patterns can al~o be part of the hybrid knowled~e repreqentation. The Pattern~ are defined bV
Boolean combination~ of event criterias which can define anv event recognized, any matched symPtom~fault relationship or any other data which is input to the hYbrid knowled~e representation. Each pattern i~
associated with a set of ambi~uity ~roup effects. Where a pattern is matched, the as~ociated ambi~uitv ~rouD
effect i~ selected to be applied to ambi~uitY group as before.
Any other model or representation of the ~y~kem under test can be also be u~ed bv as~ociatin~ an ambiguity ~roup effect with the result obtained ~rom analyzin~ the model or representation, I'h~ result can then be integrated into the ambi~uit~ ~rouP.
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Each comPonent in the ambi~uitY grouP points to it3 location in a structural model of the sYstem under test. The structural model is analyzed startin~ at the location of the component~ at the toP of the ambi~uitY
group and maintenance options which sPecify oDeration~ to be per~ormed on the system under test are out~ut.
The result3 of the tests performed can be further analyzed. These actual result~ can be comPared to expected results associated with the Performed maintenance option. Each expected re~ult. i~ associated with two sets of ambi~uitv result~. Based on the comparison, the aDpropriate set of ambiguitY grouP
effects are selected to be applied to the ambi~uitv ~rou~.
The components in the ambi~uitv ~roup can be ~rouPed together accordin~ to structural or functional relationships be~ore analYsis of the structural model.
In thi~ way, th0 maintenance oPtion~ can sug~est related oPerations to be performed.
Furthermore, the hybrid knowledge representation need not include everV model of the system under test previously described. Any combination of the event based representation, the symptom~fault model and the failure model with the ~tructural model can be used. The model or models which most accuratelv represent the sYstem under test can, therefore, be ~elected.
Description of the Drawin~s Fi~ure 1 illu~trate~ the steps performed to analYze ~aults in a SYStem in accordance with a preferred embodiment of the Present invention.
Fi~ure 2 illustrates the use of an event based representation of the system under test in accordance with a Preferred embodiment of the present invention.
Fi~ure 3 illustrate~ th~ steP of comParin~ collected data to the event ba~ed representation to perform event recognitlon.
~,~
~8--Figure 4 illustrates the anal~sis of a reco~nized event to select an ambiguitY grouD effect for outDut.
Fi~ure 5 illustrates the use of a ~ymPtom~fault model in accordanc~ with a Preferred embodiment of the 5 present invention.
Fi~ure 6 illustrates ~che use of ~ailure model in accordance with a preferred embodiment of the Present invention.
Fi~ure 7 illustrate~ the effect of amb~uitv ~rouP
effects on the ambiguity group and ambi~uitv ~roup's pointers to a structural model of the system under te~t.
Figure 8 illustrates the ComDar~Son of the actual result3 of a test performed on a sYstem under test to the expected results.
Fi~ure 9 illu3trates the grouping of related components in the ambi~uitv ~rouD prior to the analYsis of the structural model.
Fi~ure 10 shows an Event Structured ComDonent Model.
Description of the Preferred Embodiment The diagnostic tool in the preferred embodiment of the present invention uses a hybrid knowled~e representatlon of a system which integrate.~ causal and heuristic repre~entations of the system to imProve diagnostic and monitorin~ capabilitie.~ an~ to obtain more flexible reasoning in the analv~is of the data from the 3ystem- The causal relationships of the sYStem~ are embedded ln an event based representation of the sv~tem and in a structural model of the qystem. Th~ e~ent based repre~entation provides a temporal definition of ~Ystem performance from which predefine~ events, which can occur during sy~tem oPeration~ are reco~nized. The structural model defines the physical connectivity, hîerarchv and static character of the system on a component by component ba~is. The heuri~tic relation~hip3 o~ the sy~tem are embedded in a rule based sYmDtom~-fault model and in a rule based failure model. These models embodY
the knowledge of the expert technician and/or the svstem de~i~ner and are verv similar to known heuristic systems.
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-, ~9-Figure 1 illustrates the steDS Performed by the diagnostic tool in the analysis of the hvbrid knowled~e representation in accordance with a Dreferred embodiment of the present invention. In steD 100, a Plurallt~ f 5 data samPles are collected from the ~v~tem under test during it~ operation. In steD 102, the collected dat~ is compared to the event based repre~entation of the 3y~tem to perform event recognition. In thi~q ~teP. event~ which are pre~-defined by the event based reDresentation and lO that occur durin~ the operation of the ~ystem under te~t are reco~nized. Each event defined by the event ba3ed representation i~ as~ociated with a Dluralitv of ambi~uity group effects. each of which s~ecifies one or more comPonents from the system under te~t which are 15 either operationally susPect or absolved from susPicion as a result of the event bein~ reco~nized and a rankin~
effect for each comPonent. After analYsis of the recognized event~ and event~ related to the reco~nized events, the approprlate ambi~uity grou~ effects from each recognized event are aPplied in sten 104.
In ~tep 106, the ambi~uitv ~rouD effect~ are applied to an ambi~uitv ~rouP, which i~ a ranked li~t of all ~.Y~tem comPonents. Initiall~. all the comDonent~ in the ambiguity grou~ have the same arbitrarv rankinR, ~av 0.
Step 106 cau~e~ the com~onents in the ambi~uitv grouP to be re;~ranked accordin~ to the rankin~ effect from the ambiguity group effect~ outPut in steP 104. 90 a~ to be ordered accordin~ to their probability of failure.
The heuri~tic relationshiPs sPeoified in a sYmPtom~
fault model of the ~ystem and a failure model of the sy~tem are inte~rated with the steps 100 to 106, in accordance with a preferred embodiment of the invention. In step 108, the oDeration of the svstem under te~t is observed and data i8 collected durin~ the observation. In ~tep 110, the observed data is comDared to a symptom~-fault model which comprises a pluralitv of ~ymptom~fault relation~hiPs. The comPari~on determine~
the ~ubset of symptom~fault relationships from the .
.-?1 0 sYmvtom-fault model which are matched by the ob~erved data and, therefore, exhibite-~ bv the operation of the sVstem under te~t. Each of the Pluralitv of sYm~tom~
fault relation~hip~ in the model i3 associated with a ~et 5 of ambiRuity group effect~ each of which sPeci~ies one or more components and a rankin~ effect for each comPGnent, as before. In step 112, the set of ambi~uitY grouP
effect~ associated with each of the symPtom~fault relationship~ determined in step 110 are apPlied to the ambiguity group in steP 106, so the components sPecified by the ambi~uity ~roUP effect are re-ranked accordin~ to the specified rankin~ effect.
In ~teP 114, a failure model of the svstem under test, comprisin~ a pluralitY of rules, i.s analvzed.
Outputs from the event reco~nition Derformed in steP 102, from the sYmPtom~faUlt~ analysi~ performed in steD 110 or from any other ~ource are comPared to event criteria from the failure model which speci~v Patterns that corresDond to the rules in the model. Each pattern has associated with it a set of ambiguitv ~rouD effects, a~ before. In step 116, the set of ambi~uitv Rroup effects correspondin~ to recognized Datterns from the failure model are output. In step 106, the out~ut set of ambi~uitv group effect.~ are aPplied to the ambi~uitY
group, as previously described.
In step 118, a structural model of the svstem under test that sPecifie~ component connectivitv is analvzed, starting with the comDonents which are ranked at the toD
of the ambi~uitY ~rouD and, therefore, most ~usPect. In step 120, maintenance options are output a~ a result of the analysi~ of the structural model. The maintenance options specifv Possible oPerations which can be performed on a component bv a technician. In sten 122, the results obtalned from Performin~ the sDecified maintenance option~ can be comPared to the exDected results of Performin~ those oPtions. Each exPected result is associated with ambi~uitv grouP effect~, as before. APpropriate ambi~uitv RrouD effects are selected ., .
:
:, for outPut in ste~ 124 for use in steP 106. where the specified components are re~ranked in the ambi~uitv ~roup according to the rankin~ effect.
A more detailed description of the stePs shown in 5 Figure 1 is now provided. Fi~ures 2 through ll illustrate the steps associated with the u~e of th~ event based representation of the svstem and its effect on the ambi~uitv ~rouP.
In step 102, event reco~nition is performed by lO comparin~ the collected data 150 to th~ event ba~ed representation 152 of the s~stem, as shown in Fi~ure 2.
The event based representation 152 Provide.~ a temPoral definition of the performance of the svstem under test.
It comprises a Pluralitv o~ event records 154. 156 and 15 158 stored in a data base, each of which defines an event which can occur durin~ the oPeration of the sv~tem. The level of rePresentation is determined by the inherent te3tabilitv oP the svstem under test. It is onlY
necessary to represent the sYstem to a level at which the ~ystem operation can be measured. Each event record 154 to 158 i9 characterized by the name, Phase and function of the event. at location 160 an~ repre~sented bv a number of Parameter~. These parameters include one or more critical Darameters at location 162 by which the event i9 recognized, affected parameter~ at location 164 which ~qhould be affected bv the occurrence of the event, state vector de~endencies at location 166 which define preconditions that mu~t exist in the sYstem for the event to be recogni~ed and state vector effects at location 30 168.
The data 150 collected from the svstem in steP 100 comprises a pluralitv of data samPles 170. 172 and 174.
This data 150 rePresents the oPerational characteri~qtics of the s~qtem from which the defined event.q of the event based representation 152 are recognized in steP 102.
These sample~q are time ta~ed so that samPle 170 is associated with time t1~ samPle 172 i~q as~ociated with time t2 and so onO Further. calculationq can be .~ , 2~
=12 performed on the collected data 150, and included in the data samples 170 to 174 for u3e in the event reco~nition Prooess of step 102 or the pattern reco~nition process of steD 114, The data 150 can be colleoted by an~ known data acqui~ition technique. In a preferred embodiment, the data 150 i~ collected from the SYstem and time~taR~ed by a proRrammable, intelli~ent acquisition module9 such as product number AVME~9110, manufactured bv Acromag.
This module afford~ a pluralitv of YamPlin~ rate~ as well as a PIurality of channel~ which are proRrammablv selectable. It includes memorv to store the pluralitv of records 154 to 158 of the event based repre9entation 152, memorv to store the collecte~ data 150 and an on board lS microDrocessor which enables the necessary calculations from the data 150 and the sub~eauent event reco~nition of steP 102. By usin~ a Programmable~ intelliRent data acquisition system havin~ sufficient memorv to store the event ba~ed representation 152 and the data 150, real time event recognition in steD 102 i8 obtainable. A
sin~le Acromag acquisition module should be sufficient for most system~. however, if ~reater acquisition capabilitY i~ needed additional modules or a different data acquisition module with greater capacitv can be utilized.
The event reco~nition process of ~teP 102 will now be de~cribed with reference to Fi~ures 2 and 3. Fi~ure 3 illuqtrate~ the event recognition stePs of step 102 in ~reater detail. In step 200, the first event 154 in the event ba~ed repre3entation 152 is selected. In steP 202, the state vector dependencie~ at location 166 in event record 154, which define the Preconditions that must exist in the sYstem under test for the defined event to have occurred. are compared to a historv of event~ that occurred durin~ o~eration of the ~ystem under test. The hi~torv is embodied in a state vector 190 which is a list of the state vector effects from location 168 of the events recognized in qtep 102. The state vector 190 must .
.
- . ~ . , be uPdated every time an event is recognized. At the start of diagnostics, the state vector 190 i~ either emDtv or loaded with initial values.
In steD 204, the state vector dependencies for the 5 first event record 154 and the state vector 190 are analYzed to determin~ if the Preconditions sDecifie~ bY
the ~tate vector dependencie~ have occurred. If the precondition~ are not found, the event 154 is not recognized. In step 206, the event ba~ed representation lO 152 is examined to see i~ ther~ are more event~. If there are, the next event is retrieved in 3teD 208. If there are no more events, the analYsi~ iq ended in steP
210.
If. in steD 204, a match is found between the state vector dependencv of event record 154 and the state vector 190, then the event reco~nition analvsis for event record 154 continue~. In qteD 212, the first, data ~ample 170 from the collected data 150 i9 selected. In steP
214, the data sample 170 is compare~ to the critical parameters found at location 164 in the event record 154. In st~r 216, it, i~ determined whether ther,o is a match between the critical Parameters and the data sample. If there is no match, the collecte~ data 150 is examined in ~tep 218 to ~ee if the la~t data ~amPle from collected data 150 was used. If the last, data samPle was used, then step 206 is rePeated to see if everY event record has been used. If there are more data sample~.
they are retrieved in step 220.
I~, in ste~ 216, a match between the critical parameters of event record 154 and the data samPle 170 is found, then the even~. defined bv event record 154 i 9 declared reco~nized in qtep 222. In step 224, the ~tate vector at location 168 of event record 154 i~3 added to the state vector 190 at location 192. Then step 218 is repeated to see if there are mor~ data samPle~ to be used.
_14_ In this way, all data samDles 170 to 174 from collected data 150 are comPared to the critical parameters from every event record 154 to 158 from the event based representation 152. Fi~ure 2 illustrates the 5 recognition of event 1 defined bv event record 154 and event 2 define~ bv event record 156 bv this Process and output from steP 102. The state vector 190, therefore.
consists of a first s~t o~ state vector effects 192 from event 1 and a second set of state vector effects 194 from l~ event 2.
The matchin~ required bv step 102 is ~imPle one~to4 one matching. The imPlementation of such matchin~ is well known in the art.
As was Dreviously mentione~. each event record 154.
156 and 158 is associated with a Pluralitv of ambi~uitY
group effects 176, 178 and 180, resDectivelv. Each ambi~uitv effect sPecifie~s on~ or more comPonents which are either oDerationallv sus~ect or absolved as a result of the analysis and a rankin~ effect for each of the specified comPonents. Fi~ure 2 illustrates events 154 and 156 as havin~ been recognized in steD 102. A subset of ambi~uitv ~roup effects 182 selected from the ~et of ambiguity grouP effects 176 is outPut with event record 154. Similarlv. a subset of ambi~uitv ~roup effects 184 selected from ambi~uitv ~rouD effects 178 i.q outPut with event record 156.
Fi~ure 4 illustrates the analvsis of a reco~nized event 154 to select the subset of ambiguitv ~rouD effects 182 from the set of ambiguity grouP effects 176 which are to be output from steP 102. The event. record 154 has a plurality of affected parameters 230, 232 and 234 at location 164 and a pluralitv of state vector effects 236 and 238 at location 168. The affected oarameters 230 to 234 define the states of parameters of the sYstem under test which should have been affected in some way by the occurrence of th~ event durin~ o~eration of the sYstem.
The actual state of the affected ~arameters can be checked bv reference to the collected data 150. The ; ~
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15_ state vector effects 236 to 238 define the effects of the reco~nized event defined bv event record 154 which should have occurred in ~he sy~tem. The state vector effects at locationq 236 and 238 are relate~ to the affected 5 parameters at locations 230 to 236 or to the critical Parameters at location3 162 either directlv or bY Boolean oDerators. Referrin~ to Fi~ure 3, it is seen that state vector effect 238 is directlv related to affected parameter 230 by pointer 240. The occurrence of the lO effect specified bv the state vector effect 238 can thereby be confirmed by reference back to the data samDle u~ed to reco~niz~ thP event define~ bv event record 154 or other data samDles as needed and bY comParin~ that data to the comDonents state define~ bv the affected Parameters 230. If the component state defined by the affected parameter 230 is found in the data, the state vector effect 238 is confirmed. If it is not, then the state vector effect 238 iS not confirmed.
Fi~ure 4 al~o shows state vector effect 236 related to two affected parameters 232 and 234 bv a Boolean operator 242 throu~h pointers 244, 246 and 248. AnY
state vector effect can b~ so defined if appropriate.
The Boolean oPerator 242 can define any lo~ical combination of affected Darameters. Stat~ vector effect 25 236 iS confirmed. therefore, bV referencing data from collected data 150 and comparin~ it to affected parameters 232 and 234 to see if the Boolean oDerator 242 is satisfied.
Each state vector effect is associated with sets of ambiguitY group effects, one set for uq~ i~ the effect is confirmed by reference to the approDriate affected parameters and another set for U8~ if the effect iq not confirmed by the reference. State vector effect 236 iS.
therefore, associated with a first set of ambi~uitv ~rouD
effects 250 to be used if the effect 236 i.~ confirmed and a second set of ambi~uitY group effects 252 to be used if the effect i~ not confirmed. State vector effect 238 is similarlY associated with a first set of Darameters 254 "".;
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to be used if the e~fect is confirmed and a second ~et of parameters 256 to be use~ if the effect, i9 not confirmed. The combination of ambiRuitv RrouD effects 250 to 256 comprise the ambiKuitv ~roUP effects 176 5 associated with event record 154. In step 104, the appropriate subsets of ambi~uitv ~rouD effects for each recognized event is selected based on the analvsis of the affected Parameters and the state vector effects as described. Referring to Fi~ure 3, assume the effect specified bv the state vector effect 236 iS confirmed bv reference to affected parameters 232 and 234, SO that the first set of ambi~uitv ~roup effects 250 i9 selected for use with outPut 182. Also assume the effect sPecified by the state vector effect 238 is not confirme~ bv reference to affected parameter 230, so that the second 9et of parameters 256 associated with stat~ vector effect 238 iS
selected for use with output 182.
Each ambiguitv grouP effect 250 to 256 ~pecifies what components are susPect or absolved as a result of the event bein~ recognized and a rank for each component according to the level of susPicion for the com~onent.
In addition to analyzin~ event~ reoo~nized from the event based repre~entation 152 to select approPriate ambiguity grouD effects, event~ related to the recoKnized events can also be analyzed to s0lect ambi~uity ~rouP
effects. For example, if the system under test normallY
pro~resses throu~h a sequence of four event~ but onlv three were reoo~ni~ed, the fourth unreco~nized event mi~ht al30 be used to select ambi~uitv ~roup effects.
Re~errin~ to Fi~ure 3, the heuristic rules embodied in a sYmPtomrfault model and a failure model are integrated into the dia~nostic tool in ~tePs 108 to 112 and in stePs 114 to 116, resuectivelv. Fi~ures 5 and 6 illustrate the these ~tep~ in ~reater detail.
Figure 5 illustrates the use of ~vmPtomnfault model 300 in steD 110. The symptom~-~fault model ~00 comprises a pluralitY of ~Ymptom~fault relationships 302, 304 and 306 which aPplv t~ the sYStem under test. The ~ymptom*fault .
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relationships 302 to 306 are stored in a data ba~e. Such symptom*fault models containin~ ~ set o~ heuristic rules descriPtive of the svmDtom~fault relation~hiPs o~ the 9Ystem under test are well known. The data for these models i9 collected and derived from technical orders, repair manuals9 technician observations, lo~istic~ data or an~ other source of sYstem ~ailure data.
To use the symptom;7fault model 300, the operation of the system under test is observed in steD 108. The observed data 308 is formatted to allow comParison with each svmPtom~fault relationshiP 302 to ~06. In ~tep 110, all of the observed data 308 is comDare~ to each one of the symPtom~fault relationshiPs 302 to ~06 in the symptom~fault model 300 t~ find those relationshiP.~ which match the observed data and, therefore. are applicable to the operation of the system under test.
Each symptom~fault relationshiD ~02, 304 and 306 is associated with a set of ambiguitv ~rouD effects 310. ~12 and 314, resPectivelY, each of which sPecifY one or more components and a rankin~ effect for each of the sPecified components. Where the comParison made in step 110 specifies the applicabilitv of anv of the sYmDtom~fault relationshiPs 302 to 306 to the oPeration of the svstem under test, the associate~ set of ambiguitieq are outPut in step 112. In Fi~ure 5, for examPle~ the symDtom~fault relationship~ 302 and 306 ar~ determined to be a~Plicable to the svstem under test in steP 110, so that the associated sets of ambi~uitv group effects 310 and 314 are outPut.
Fi~ure 6 illustrates the use of the failure model 320 in steP 114 in ~reater detail. The failure model 320 comprises a Plurality of heuristic rules which define potential failures in the sY~tem under test. Failure models are well known and are tyPicallv Presented in the form of If~Then rule3. The failure model 320 of the present invention comPrises a pluralitY of patterns which are associated with each rule. The failure model ~20, therefore, comDrises a PluralitY of Datterns 324, 326 and 328.
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The inPuts 320 used for comDarison again~t the ~attern~ of the failure model 320 are derived from several sources. Event~ recognized in step 102 are utilized to form Event Recognition Records 332 and 334.
Each Event Recognition Record 332 and ~24 al30 has a Pointer that sPecifie~ the location of the data samPle 170 to 174 from which the event was recoRniZed. In thi~
way, the data ~amples 170 to 174 are als~ available for compari~on to the patterng of the ~ailure model 320.
Similarl,y, the symptom~ault relation~hips which were found to exist in step 110 are used to form Pattern reco~nition records 336 to 338.
The pattérns 324 to 328 of the failure model 320 are defined by logical combinations of event criteria which can correspond to the event recognition records 331 to 334, to the Pattern reco~nition records 336 to 338. or to any other inDuts 330 which may be aPDlicable. In step 114, all of the inputs 330 are comDare~ to each Dattern 324 to 328 in the ~ailure model 320. The matchin~
required to perform steD 114 i.~ nificantly more difficult than the matching required to perform event recognition in ste~ 102. A "manv to many" matchin~
strategy is used in the Preferred embodiment because each recognition record 332 to 338 can have manv com~onent parts that must be comDared to a pattern 324 to 328 which mav be defined by manv event criteria. In the ~referred embodiment, CLIPS. an artificial intelli~ence lanRua~e.
is u~ed to implement a matchin~ algorithm base~ on the Rete Network. Other lanRuages which can be used include OPS5 and SOAR.
Each pattern 324, 326 and 328 in the failure model 320 is associated with a set o~ ambi~uitv ~rouD effects 340, 342 and 344, resPectivelv. as before. When the matchin~ Performed in ~t,~n 114 determine~ that ~ Dattern exist~, it is outPut with its as~ociated set of ambi~uitv ~rouP e~ects. In Fi~ure 6, ~or example. ~attern 326 has been recognized 90 that the associated set of ambi~uity group effects 342 is outPut in ~teD 116.
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'~1 9-When the pattern 326 i9 recognized in SteD 114, a new Dattern recognition record 346 i.q develoDe~ an~ added to the input set 330. The matching performed in ~tep 114 continues until all of the Dattern reco~nition records.
includin~ those develo~ed during the matchin~. have been comPared to the failure model 320.
Fi~ure 7 illustrates two sets of ambi~uitv ~roup effects 360 and 362. an ambi~uitv ~roun 364 and a structural model 366 of the system under test. The ambiRuity group 364 comprises a ranked listin~ of sYstem com~onents as sDecified by the sets of ambiguitv ~rouP
effects 360 and 362 and Pointers 368. 370 and 372 which are associated with each comPonent. Initiallv. all comPonents in the ambiRuitv grouD 364 are equall~ ranked at an arbitrarY number. say 0. A~ each model or representation of the sYstem under test is analvze~ and re~analyzed, the ambi~uitY ~roup effects 360 and 362 are Renerated~ each of which specifv one or more system comPonents which are to be re~ranked and the rankin~
effect to be aPplied to the component in its ambiRuitv grouP ranking. Ambi~uitv ~roup effects 360 and 362 each specifY two sYStem comPonentq t~ be rehranked in the ambi~uity group 364 and a ranking effect for each of the two specified components. The rankin~ effect.~ are arbitrary numbers which only have meanin~s relative to other rankin~ effects. Th~ rankin~ effect for a ~iven ambi~uity group effect should. therefore. be chosen to reflect the accuracv of the analysis.
In ste~ 106, each set of ambiguity grouP effects 360 and 362 are aPplie~ t~ the ambi~uitv ~rouD 364.
Initially, all comPonents A, B and N in the arbitrarv grouD have a rank of 0. Ambiguitv ~roup effect ~60 specifies that system comDonents A and B are susPect~ and should be re-ranked with A rankin~ effect of ~10 applied. Ambi~uity ~rou~ effect 362 sDecifies that system oomPonents A and N are not suspected. The rankin~
effect. -10, is applied to lower the ranking of comDonent A to 0, as indicated. ComPonent N is re~ranke~ with a ,~ . . ; .
;
2~2~2 ~20 -ranking effect of -10 aDPlied. The ambi~uity ~roup effects 360 and 362 can b~ ~enerated bY anY of the analysis steps previously discussed or by any other model of the system under test.
Each comPonent A. B and N in the ambi~uitv ~roUP 364 is associated with pointers 368. 370 and ~74.
respectivelv. which point to the locations of the components in the structural model 366. After the processing of all sets of ambiKuitY ~rouD effects 360 and 362, the ambiguitv grouD 364 rank.q each comPonent in the list according to its likelyhood of failure. The structural model 366 can now be analYzed bv referencing the system comPonents at the top of the ambi~uitv group 364, such as component B, and locatin~ the component in the structural model 366 by means of the associated pointer, in this case pointer ~70.
The structural model 366 is similar to known structural models in that it sPecifie~q the sYstem~s comPonent connectivitv and hierarchy. Previous diagnostic tool~s have had difficulty utilizin~ such structural models of comPlex sYstems~ because of the large number of comPutation~ needed t~ analY~e the structural model. The dia~nostic tool of the present invention makes the use of such models more comPutationally attractive than other analytical tools by pointin~ to the location in the structural model comPonent with the ~reatest likelvhood of failure, therebv avoidin~ unnecessarv and len~thv computations.
In addition to the specification of svstem characteristics such a.q connectivitv and hierarchY, the structural model 366 in accordance with a Preferred embodiment of this invention includeq a qualitative descriPtion of the components rePresented. Included in the description i.q a list of maintenance options Possible for each ComDonent. This mi~ht include sPecial te~t or calibration procedures, or replace and rePair procedures. The analYsis of the hi~hest ranked components in the ambiguitv group leadq to thP structural . . , . ,. , . :, ,, ~.
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model 366 and yields one or more of these maintenance options. Fi~ure 7 illustrateq two maintenance o~tions 374 and 376 being outDut as a result of the analYsis.
Associated with each maintenance oPtion is an expected result. Fi~ure 8 illu~trates expected result 378 being associated with maintenance option 374. As before mentioned in describing ste~ 122, the actual result 380 obtained in performin~ the malntenance option 374 can be comPared to the expected results 378. Each expected result 378 is associated with two sets of ambi~uitv groUP effects 382 and 384, a first set 382 for use if the exPected result~ ~78 are confirme~ bv the actual results 380 and a second set 384 for use if the expected results 378 are not confirmed. Th~ sets of ambiguitY grouP effects 382 and 384, as before, specifv components which should be re~ranked in the ambi~uitv ~roup accordin~ to an associated rankin~ effect in steD
106. As a result of the comparison ste~ 122, the approPriate set of ambi~uitv ~roup effects 382 or 384 is output for use in steP 106. Fi~ure 8, for examPle, illustrates the case where the exPected results 378 are confirmed bv the actual results 380, so that the first set of ambiguitv ~roup effects 382 is selected to be an outPut 382 from sten 124. The sten 122 can be repeated every time a maintenance option is performed.
As a further step, once the ranking of component.s in the ambiRuitv group 364 is comPlete, but before the analysis of the structural model 366 in steD 118, the components in the ambi~uitv ~roup 364 can be ~rouped accordin~ to functional or structural relationships. In this way a lo~ical Progression of dia~nosis throu~h the system can Proceed~ so that the maintenance oPtions which are outPut in step 112 do not su~est the testin~ of unrelated comPOnents. This is further illustrated in Fi~ure 9, wherein ambiRuitv ~rouP 400 contains a plurality of components from the fuel sub~system of the system under teCit and a Dluralit~ of comPonents from the electrical sub;system of the system under test, all : ; , .
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havin~ a variety of ranks. Accordin~ to thi~ ~tep, which is performed after the steP 106 but before steP 118, the com~onents which are ~unctionally related to the fuel sub~system are selected to form ~ fir~t ~rouD 402 while the components which are functionallv related to the electrical sub~system are selecte~ to ~orm a second ~rouD
404. The analysi~ of the structural model 366 in steP
118 can then proceed usin~ one of the functionallv related ambi~uitv grouDs 402 or 404. One subrsv3tem at a time can be, therefore, completelv te~ted.
The invention is not limited to the use of the models and representations discussed. Other models.
representations or factors which characterize ths sv~tem can be used bv assiRnin~ a set of ambi~uitv ~rouD efrects to each result obtained from the use of the alternative model t representation or factor. In this way, the most accurate characterization of the system under test or combination of characterization.~ can be use~ to obtain the optimum diagnostic reqult. The assi~ned sets of ambi~uitY ~roup effect.s can then be aDPlie~ to the ambiRuitv ~rouP 364 in steP 106. BY way of examDle onl results obtained from the use of reliabilitv statistics, Failure Modes and Effects analvsis (FMEA) and maintenance historie~ can be used in this manner.
Furthermore, the invention does not require the use of all of the step~ and all o~ the sv3tem reDre~entations or model~ Previously enumerated. If any of the rePresentation~ or models of the system under test are of low qualitY or if anY step yields consistentlY Poor results thev can be omitted fr~m the dia~nosti~ tool.
This mi~ht occur more freauentlY in the case of heuristic rule based knowled~e representations, wherein an adeauate set of rules is often difficult to develoD.
In the event that the previouslv de~cribed steP~ do not diagnose the fault in this system under test, the analysis maY be further exPanded in accordanc~ with an alternate embodiment o~ the present invention, Referrin~
to Figure 10, and Event Structured ComPonent Model 410 i~
. . .
illu3trated. This model 410 is an expansion of the structural model 366 described before and to other known structural models.
The model 410 ComPri~es a de~criPtion of a Plurality of comDonents 412, 414 and 416. The model 410 include~
static characteristic~ at location 418 for each comDonent 412 to 416 a.q doe~q the ~tructured model 366. ThP ~tatic characteristics 418 de~cribe the component repair profile, in Particular th~ testabilitv and acce~ibilit,y of the component. The maintenance opt~ons 418 and 420 which are outDut in ~teD 120 of the preferred embodiment are alqo included here. These characteristic~ 416 can be used by a 3y~tem technician t~ determine wh~t t,~ do next. Further tests on the comDonent can be Derformed if the model in 410 indicate~ that the comDonent i9 testable. Additionally, adiustment~ to the ComDOnent can be made if the model 410 indicate3 the comDonent, is accessible to the technician. The~e static characteristic~ 416 are acce~sed ViA the ambiguitv 2rouP
POinterS in the preferred embodiment of the invention.
These static characteristics 416 can be subsetted alon~
with a static connectivity repre~entation to construct the structural model 366.
The Event Structured COmDonent Model 410 is differentiated from the structural model 366 bv the inclusion oi' dynamic characteristic~ of each comDonent at location~ 422 throu~h 424. The dynamie characteristics at a particular location characterize the comDonents connectivity, hierarchy. performanc~ characteristic~ and function at a ~iven phase or event within the ~vstem under te~t. Th~ connectivitv of the COmDOnent, is characterlzed by sPeCifVin~ the inDuts and OUtDuts to the component and the connective medium. The hierarchv of the component describe~ suPer and subcomPonent~ of the 3~ component. In other word~, the hierarchv of the component de3cribe~ whether the comDonent i 3 part of another ~rouD of component~ or con3ists of a grouP of comPonent~. The Performance characteristic~ of the ComDonent are also included in it~ dynami~ characteristics.
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, To use the Event Structured ComPonent Model 410, the operational historv of the APU contained in the state vector developed in steD 102 i3 analYZed to determine the pha9e of failure of the 9ystem. By knowin~ the normal 9equence o~ events in the o~eration of the system under te~t, and bv com~arin~ ~ t to the recognized events, the phase of failure of the s~stem under test can b~ determined. The Event Structured Component Model 410 can than be accessed by comPonent accordin~ to the ambi~uitY grouD a~ PreViouslY
described. The comPonent in the model 410 is further referenced bv the determined Phase of failure. So, for exam~le, if comPonent 2 at location 414 is determined bY
analysis of the ambi~uitv groun to be the most ~usPect lS ComPonent, that COmDOnent in model 410 is referenced.
If the failure of the sYstem i~ determined to have occurred in phase 1 by analYsis of the state vector obtained in steD 102, then the dynami~ characteristics of phase 1 of the ~econd comDonent at location 422 are accessedO These dynamic characteristic~ are used to recreate what the sY~tem should look like as comPared to the actual operational characteristics of the system.
This procedure can be used to su~gest further component~ to be analYzed throu~h the Event Structured ComPonent Model 410O This search. however, must be limited to prevent computational problems. It mav be limited by data derived during event recognition, by functional and structural connections. bv connectivit~
paths or by components havin~ a low rankin~ in the ambiguitv ~roup.
The dia~nostic tool of the Present invention is applicable to a varietv of systems. The diagnostic tool comPrises a hYbrid knowledge rePre~entation and a series of analytical steps as described herein to use the hybrid knowledge representation. In aPplying the dia~nostic tool, the analytical steps are system independent, so that any of the stePs described herein can be used for any ~ystem. The knowled~e . :
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rePresentations~ however. are svstem deDendent and must be modified t~ represent the system desired to be analvzed.
An examPle of the dia~nostic tool as applied to an Auxiliary Power Unit (APU) for an airplane is now given. The application of the diagnostic tool to an APU
is also described in "APU Maid: An EventeBased Model For Diagnosis", published November 3, 1987 at the AUTOTESTCON meeting, which is incorporated herein bV
reference. Auxiliarv Power Units are ~as turbine engines used for aircraft ~round base suPDort for pneumatic power and generator support and in the air for both suPplemental and emer~ency power support. The APU
can either be used from a ~round cart or installed in the aircraft as Part of the Pneumatic svstem. The APU's engine is comDrised of a comDressor/turbine section, with attachinÆ comPOnentS that make UD the units fuel, bleed air, lubrication and electrical svstems.
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Table 1 illustrates a sin~le data samDle havin~
label DS200 which is collected durin~ the o~eration of the APU. The data samPle Provides 9iX channels of analo~ data, includin~ the time of the data samPIe~ the oil pressure. the compressor discharge pregsure. the fuel pressure, the exhaus~ ~as temDeratur~ and the engine rpm. It also provides 16 channels of di~ital data as indicated.
TABLE 1: DATA SAMPLE DS200 ANALOG
CHANNEL PARAMETER VALUE UNIT
S
1 Poil 2.1 PSI
2 PcomPressor discharÆe O PSI
3 Pfuel 40.0 PSI
S YS TEM FA ULT D IA GN OS I S
Field of the Invention The invention relate~ to method.~ and apparatus for analvzing svstems. More specificall~. it relates to a hybrid knowled~e representation o~ a SY~tem and methods for analyzing the representation to provide faster and imProved analYsis of the system~
Back~round of the Invention As the comPlexitv of man~made sY~tems increase~. the complexitY of the ta~ks involved in maintainin~ ~uch systems also increa~es. The maintenance task3 include, bv wav of example only, fault diagnosis, fault location, performance monitoring, Performance oPtimization and repair. These tasks are typicallY performed bv an expert technician, by analytical diagnostic tool~ or by a combination thereof.
ManY dia~nostic tools are known for use in maintenance tasks, however, thev are all limited in one or more respects. Early dia~nostic tools utilized snapshot monitorin~ wherein an instantaneous picture of the system under test is developed. Another test conceDt used in early dia~nostic tools wa~ stimulus~res~onse testing wherein test eaui~ment i~ used to develop appropriate stimulus waveform3 and thë resPonse of the sy~tem under test is analyzed. In fact, manY srqtems in use todav are ~till maintained and tested b~ dia~nostic tools using these techniaues.
Diagnostic tools using steadY state and stimulus-response testin~ techniques, however. are unable use the full sPectrum of information available about the svstem under test. In particular, these tools makP no use of knowledge concerning the desi~n or the prior maintenance historv of the system under test. These sY~tem~, therefore, do not provide reliable fault diagnosis of , , , .
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svstemis. Furthermore, such ~vistem~ have iseverelY limited abilitv to reason about results obtaine(1 durln~ tei~tin~
or moni tori n~ .
As a result of the llmited reasonini~ abilitY~ expert 5 systemis have been incorporated into various dia~nostic tools. In a common form, the ex~ert sv~tem uses a sur~ace knowledge representation of the sYstem unden test to anal,yze and reason about potential faulti~i in the system. Surface knowled~e repreisentatlons t~rpically 10 associate a iset of symptoms with a set of f`aults which association is f`requently presented in the form of a fault tree. Surface knowledge representation~i also ~requentlv take the form of a set of rulec~ of the I~Then form. Data or information for the ~urface knowled~e 15 representation is usuallY obtained from the expert technician or the sYstem desi~ner.
These systemi~ have had limited succe~sei~ in sim~le systems where maintenance experts have accumulated enou~h experience in maintainin~ the system to provide accurate 20 rules for most of the poi~ible sYstem faults. In cases where the system under test. iq somewhat comPlex~ however.
it is often very difficult to embody the exPert'is exPerience in a set of rules to drive the exDert sYstem, even where the expert hais had sufficient exPerienCe with 25 the complex syistem. See, for example, "The Thinkin~
Machine ~ An Electronic Clone o~ a Skilled Engineer is Very Hard To Createi', in the August 12. 1988 issiue of the Wall Street Journal on page 1, wherein the efforts of the Southern California Edison Co. to develoD an expert 30 system to dia~nose faults in one of their dams is described. The exPert sYstem w~ to be based on ~ set of rules which embodied the knowled~e of a civil en~ineer havina two decades of related experience. After a signif icant investment in time and money and af ter 35 narrowin~ the sco~e of the pro,iect, limited diai~nostic success was achieved, however. the diagnostic tool was not PUt into re~ular use~
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;3-Expert systems based on surface knowledge representations, therefore, require an exhaustive set of a priori rules which accura~ely encompa~3 the sDectrum of the pos~ible faults of the ~ystem l~nder test, to be effective. Furthermore, such expert S,Ystems per~orm poorlY when fault condition~ occur which are beYond the sur~ace knowledge heuristic rule base since there is no knowled~e base upon which further reasonin~ can occur.
Expert ~v~tems based on surface knowled~e repre~entations, therefore, offer limited reasonin~
capabilities.
Expert SYstem~ have also incorporated deep knowled~e representations of system~ under test, wherein the functional and structural qualities of a sYstem's components are qualitatively modeled to show connectivity and behavioral relationships. Thi~ aPProach enables a diagnostic tool to deal with imPrecise behavioral and structural characteristics of a sYStem, such as dynamic changes in connectivity, which can not be addressed in other approaches, thereby offering potential for greater flexibility in reasoning. Such qualitative model~ can represent the operation of a sYstem without an exhau3tive a priori enumeration of all possible failure models, as required in surface knowledge apProaches.
Diagnostic tools based on such qualitative models can, however, easilv become com~utationally unwieldlv since the number o~ comPutation~ require~ to use the qualitative model is proportional to the connectivitv of the system under test. The connectivitv of a system increases a9 a combinatorial function of the number of components~in the system, so that qualitative models which repre~ent complex sYstems havin~ many functions and components become comPutationallv untractable.
Various combinations of the previouslv di~cussed diagnostic tool~ have been ~u~ested. In Report No.
SETR-86~001 of the Software Engineerin~ Technical ReDort Series prepared by the Allied~Signal Aero~pace comPan~ a two layer expert system uqin~ a surface knowled~e , .
, ; . ,, .
re~resentation embodYin~ heuri~qtic rule~ develoDed by system maintenance exPert~ and a deeP knowled~e representation embodyin~ comDonent behavior and sYstem connectivitv i~ ~u~geqted. It iq al~qo ~u~eqte~ to use reliability stati~qtic~ a~q an ad~junct to the exDert s~stem. The ~u~,e,sted two layer exPert ~qv~qtem would first diagnose a sV~tem based on the heuristic rules of the ~urface knowledge repre~qentation. The deeD knowled~e representation i9 referenced onlY when a failure mode which ls outside the failure~q embodle~ in the rule base is encountered. The suggested two laYer expert svstem.
therefore, does not provide an inte~rated dia~nostic tool. Rather. in most ca~qes such a s~stem i~q dependent on a heuristic surface knowled~e reDresentation and the required exhaustive enumeration of a Priori rules. which can be difficult to develop. Causal reasonina with a deep knowledge repre~entation would be referenced onlv when heuristic reasonina with a surface knowled~e representation fails. The results obtained with such a dia~noqtic tool would onlY be marginally imProved since the knowledge representations are not truly inte~rated.
Furthermore, the suggested diagnostic tool failq to solve the problem of the comDutationally untractable qualitative models in the dee~ knowled~e repre~entation when such models are referred to.
A diagnostic system that combines a surface knowledge expert svstem with a deeP knowledge expert qystem was also su~ested in "The Integrated Dia~nostic Model~Toward~ a Second Generation Dia~nostic ExDert System7', published in July 1986 in the Proceedin~s of the Air Force WorkshoP on Artificial Intelli~ence Applications for Integrated Dia~nostics at Da~es 188 to 197. Thiq diagnostic tool separates the two knowledge representations until a deciqion is to be made. At the time of decision, an executor proces~ arbitrates between the two expert systems to mak~ a deci~ion. Thi~q tool.
therefore, fails to inteRrate the two tYpeq of knowled~e and has problem~ ~imilar to the ~u~ge~ted two laver expert system discussed above.
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A dia~nostic tool which provides an inteRrated knowled~e representation o~ a ~Ystem~ combinln~ a variety of knowledge representations of a system a~ well a~ other system information is needed. Such a diagnostlc tool should provide ~lexible decisions similar to those provided by expert svstems utilizine deeD knowledge representation~, but should also Provide quick and efficient decisions as well a~ imProved dia~nostic deci ~i ons .
Summary of the Invention Accordin~ to the present invention. a dia~nostic tool usin~ a hYbrid knowledae reDresentation of the system under te~t is pre~ented. An event based representation of the sYstem under test comPrises a plurality of event records that ~Pecifv predefined events that can occur in the ~ystem under te~t which are stored as a data base. The event based representation defines the temporal performance of the system under test.
A data acquisition module is provided to collect operational data from the sYStem under test which i~
compared to the event based rePre~entation to recognize predefined events that have occurred in the syste~ under te~t. An event is recognized when the critical parameter~ in the correspondin~ event recor~ are matched to a data sample from the collected oDerational data.
Each predefined event in the event based rePresentation is associated with a 3et of ambi~uitv group effects that 3pecifies components an~ ~ rankin~
effect for each sPecified comDonent. The ambi~uitY ~roup effect3 are a~plied to an ambi~uitv ~roup, which 1s a li3tin~ of com~onents in the svstem under test which are ranked accordin~ to their probability of failure. Every reco~nized event and events which are related to the recognized event~ are analvze~ to determined a ~ub~et o~
the associ2ted set of ambi~uity grouP effects to be aPplied to the ambiguitv ~roup. The analysis involves checkin~ the collected operational data to verifv the , "
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occurrence of affected ~arameter~ as de~ined in reco~nized event~ or in events relate~ t~ th~ recoRnized events. Once the subsets of ambi~uitY Krou~ eff'ect~ i9 determined, the specified component~ are re~ranked in the 5 ambiguity group accordin~ to the agsociated rankin~
effects.
In the preferred embodiment, a sYmD'com~fault model of the ~y~tem under test comprisin~ a pluralitv of symPtom~fault relationshiP3 in a data ba~e is al30 part o~ the hybrid knowledge representation. The oPeration of the sv~tem under test i~ observed and data is formatted by the observer. The observe~ dat~ i~ comPare~ t~ each sYmPtom~fault relation~hiP and anV matches are noted.
Each symptom~ault relationshiP i~ also a~ociated with a set of ambiguity group effects. The ambi~uity ~rouP
effects a~sociated with the matched symptom~fault relationships are selected and the sPecified component~
are re~ranked in the ambiguitv ~roun accordin~ to the rankin~ ef~ect.
A failure model of the svstem under test comPrisin~
a pluralitv of rules in a data ba~ which are associated with defined patterns can al~o be part of the hybrid knowled~e repreqentation. The Pattern~ are defined bV
Boolean combination~ of event criterias which can define anv event recognized, any matched symPtom~fault relationship or any other data which is input to the hYbrid knowled~e representation. Each pattern i~
associated with a set of ambi~uity ~roup effects. Where a pattern is matched, the as~ociated ambi~uitv ~rouD
effect i~ selected to be applied to ambi~uitY group as before.
Any other model or representation of the ~y~kem under test can be also be u~ed bv as~ociatin~ an ambiguity ~roup effect with the result obtained ~rom analyzin~ the model or representation, I'h~ result can then be integrated into the ambi~uit~ ~rouP.
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Each comPonent in the ambi~uitY grouP points to it3 location in a structural model of the sYstem under test. The structural model is analyzed startin~ at the location of the component~ at the toP of the ambi~uitY
group and maintenance options which sPecify oDeration~ to be per~ormed on the system under test are out~ut.
The result3 of the tests performed can be further analyzed. These actual result~ can be comPared to expected results associated with the Performed maintenance option. Each expected re~ult. i~ associated with two sets of ambi~uitv result~. Based on the comparison, the aDpropriate set of ambiguitY grouP
effects are selected to be applied to the ambi~uitv ~rou~.
The components in the ambi~uitv ~roup can be ~rouPed together accordin~ to structural or functional relationships be~ore analYsis of the structural model.
In thi~ way, th0 maintenance oPtion~ can sug~est related oPerations to be performed.
Furthermore, the hybrid knowledge representation need not include everV model of the system under test previously described. Any combination of the event based representation, the symptom~fault model and the failure model with the ~tructural model can be used. The model or models which most accuratelv represent the sYstem under test can, therefore, be ~elected.
Description of the Drawin~s Fi~ure 1 illu~trate~ the steps performed to analYze ~aults in a SYStem in accordance with a preferred embodiment of the Present invention.
Fi~ure 2 illustrates the use of an event based representation of the system under test in accordance with a Preferred embodiment of the present invention.
Fi~ure 3 illustrate~ th~ steP of comParin~ collected data to the event ba~ed representation to perform event recognitlon.
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~8--Figure 4 illustrates the anal~sis of a reco~nized event to select an ambiguitY grouD effect for outDut.
Fi~ure 5 illustrates the use of a ~ymPtom~fault model in accordanc~ with a Preferred embodiment of the 5 present invention.
Fi~ure 6 illustrates ~che use of ~ailure model in accordance with a preferred embodiment of the Present invention.
Fi~ure 7 illustrate~ the effect of amb~uitv ~rouP
effects on the ambiguity group and ambi~uitv ~roup's pointers to a structural model of the system under te~t.
Figure 8 illustrates the ComDar~Son of the actual result3 of a test performed on a sYstem under test to the expected results.
Fi~ure 9 illu3trates the grouping of related components in the ambi~uitv ~rouD prior to the analYsis of the structural model.
Fi~ure 10 shows an Event Structured ComDonent Model.
Description of the Preferred Embodiment The diagnostic tool in the preferred embodiment of the present invention uses a hybrid knowled~e representatlon of a system which integrate.~ causal and heuristic repre~entations of the system to imProve diagnostic and monitorin~ capabilitie.~ an~ to obtain more flexible reasoning in the analv~is of the data from the 3ystem- The causal relationships of the sYStem~ are embedded ln an event based representation of the sv~tem and in a structural model of the qystem. Th~ e~ent based repre~entation provides a temporal definition of ~Ystem performance from which predefine~ events, which can occur during sy~tem oPeration~ are reco~nized. The structural model defines the physical connectivity, hîerarchv and static character of the system on a component by component ba~is. The heuri~tic relation~hip3 o~ the sy~tem are embedded in a rule based sYmDtom~-fault model and in a rule based failure model. These models embodY
the knowledge of the expert technician and/or the svstem de~i~ner and are verv similar to known heuristic systems.
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-, ~9-Figure 1 illustrates the steDS Performed by the diagnostic tool in the analysis of the hvbrid knowled~e representation in accordance with a Dreferred embodiment of the present invention. In steD 100, a Plurallt~ f 5 data samPles are collected from the ~v~tem under test during it~ operation. In steD 102, the collected dat~ is compared to the event based repre~entation of the 3y~tem to perform event recognition. In thi~q ~teP. event~ which are pre~-defined by the event based reDresentation and lO that occur durin~ the operation of the ~ystem under te~t are reco~nized. Each event defined by the event ba3ed representation i~ as~ociated with a Dluralitv of ambi~uity group effects. each of which s~ecifies one or more comPonents from the system under te~t which are 15 either operationally susPect or absolved from susPicion as a result of the event bein~ reco~nized and a rankin~
effect for each comPonent. After analYsis of the recognized event~ and event~ related to the reco~nized events, the approprlate ambi~uity grou~ effects from each recognized event are aPplied in sten 104.
In ~tep 106, the ambi~uitv ~rouD effect~ are applied to an ambi~uitv ~rouP, which i~ a ranked li~t of all ~.Y~tem comPonents. Initiall~. all the comDonent~ in the ambiguity grou~ have the same arbitrarv rankinR, ~av 0.
Step 106 cau~e~ the com~onents in the ambi~uitv grouP to be re;~ranked accordin~ to the rankin~ effect from the ambiguity group effect~ outPut in steP 104. 90 a~ to be ordered accordin~ to their probability of failure.
The heuri~tic relationshiPs sPeoified in a sYmPtom~
fault model of the ~ystem and a failure model of the sy~tem are inte~rated with the steps 100 to 106, in accordance with a preferred embodiment of the invention. In step 108, the oDeration of the svstem under te~t is observed and data i8 collected durin~ the observation. In ~tep 110, the observed data is comDared to a symptom~-fault model which comprises a pluralitv of ~ymptom~fault relation~hiPs. The comPari~on determine~
the ~ubset of symptom~fault relationships from the .
.-?1 0 sYmvtom-fault model which are matched by the ob~erved data and, therefore, exhibite-~ bv the operation of the sVstem under te~t. Each of the Pluralitv of sYm~tom~
fault relation~hip~ in the model i3 associated with a ~et 5 of ambiRuity group effect~ each of which sPeci~ies one or more components and a rankin~ effect for each comPGnent, as before. In step 112, the set of ambi~uitY grouP
effect~ associated with each of the symPtom~fault relationship~ determined in step 110 are apPlied to the ambiguity group in steP 106, so the components sPecified by the ambi~uity ~roUP effect are re-ranked accordin~ to the specified rankin~ effect.
In ~teP 114, a failure model of the svstem under test, comprisin~ a pluralitY of rules, i.s analvzed.
Outputs from the event reco~nition Derformed in steP 102, from the sYmPtom~faUlt~ analysi~ performed in steD 110 or from any other ~ource are comPared to event criteria from the failure model which speci~v Patterns that corresDond to the rules in the model. Each pattern has associated with it a set of ambiguitv ~rouD effects, a~ before. In step 116, the set of ambi~uitv Rroup effects correspondin~ to recognized Datterns from the failure model are output. In step 106, the out~ut set of ambi~uitv group effect.~ are aPplied to the ambi~uitY
group, as previously described.
In step 118, a structural model of the svstem under test that sPecifie~ component connectivitv is analvzed, starting with the comDonents which are ranked at the toD
of the ambi~uitY ~rouD and, therefore, most ~usPect. In step 120, maintenance options are output a~ a result of the analysi~ of the structural model. The maintenance options specifv Possible oPerations which can be performed on a component bv a technician. In sten 122, the results obtalned from Performin~ the sDecified maintenance option~ can be comPared to the exDected results of Performin~ those oPtions. Each exPected result is associated with ambi~uitv grouP effect~, as before. APpropriate ambi~uitv RrouD effects are selected ., .
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:, for outPut in ste~ 124 for use in steP 106. where the specified components are re~ranked in the ambi~uitv ~roup according to the rankin~ effect.
A more detailed description of the stePs shown in 5 Figure 1 is now provided. Fi~ures 2 through ll illustrate the steps associated with the u~e of th~ event based representation of the svstem and its effect on the ambi~uitv ~rouP.
In step 102, event reco~nition is performed by lO comparin~ the collected data 150 to th~ event ba~ed representation 152 of the s~stem, as shown in Fi~ure 2.
The event based representation 152 Provide.~ a temPoral definition of the performance of the svstem under test.
It comprises a Pluralitv o~ event records 154. 156 and 15 158 stored in a data base, each of which defines an event which can occur durin~ the oPeration of the sv~tem. The level of rePresentation is determined by the inherent te3tabilitv oP the svstem under test. It is onlY
necessary to represent the sYstem to a level at which the ~ystem operation can be measured. Each event record 154 to 158 i9 characterized by the name, Phase and function of the event. at location 160 an~ repre~sented bv a number of Parameter~. These parameters include one or more critical Darameters at location 162 by which the event i9 recognized, affected parameter~ at location 164 which ~qhould be affected bv the occurrence of the event, state vector de~endencies at location 166 which define preconditions that mu~t exist in the sYstem for the event to be recogni~ed and state vector effects at location 30 168.
The data 150 collected from the svstem in steP 100 comprises a pluralitv of data samPles 170. 172 and 174.
This data 150 rePresents the oPerational characteri~qtics of the s~qtem from which the defined event.q of the event based representation 152 are recognized in steP 102.
These sample~q are time ta~ed so that samPle 170 is associated with time t1~ samPle 172 i~q as~ociated with time t2 and so onO Further. calculationq can be .~ , 2~
=12 performed on the collected data 150, and included in the data samples 170 to 174 for u3e in the event reco~nition Prooess of step 102 or the pattern reco~nition process of steD 114, The data 150 can be colleoted by an~ known data acqui~ition technique. In a preferred embodiment, the data 150 i~ collected from the SYstem and time~taR~ed by a proRrammable, intelli~ent acquisition module9 such as product number AVME~9110, manufactured bv Acromag.
This module afford~ a pluralitv of YamPlin~ rate~ as well as a PIurality of channel~ which are proRrammablv selectable. It includes memorv to store the pluralitv of records 154 to 158 of the event based repre9entation 152, memorv to store the collecte~ data 150 and an on board lS microDrocessor which enables the necessary calculations from the data 150 and the sub~eauent event reco~nition of steP 102. By usin~ a Programmable~ intelliRent data acquisition system havin~ sufficient memorv to store the event ba~ed representation 152 and the data 150, real time event recognition in steD 102 i8 obtainable. A
sin~le Acromag acquisition module should be sufficient for most system~. however, if ~reater acquisition capabilitY i~ needed additional modules or a different data acquisition module with greater capacitv can be utilized.
The event reco~nition process of ~teP 102 will now be de~cribed with reference to Fi~ures 2 and 3. Fi~ure 3 illuqtrate~ the event recognition stePs of step 102 in ~reater detail. In step 200, the first event 154 in the event ba~ed repre3entation 152 is selected. In steP 202, the state vector dependencie~ at location 166 in event record 154, which define the Preconditions that must exist in the sYstem under test for the defined event to have occurred. are compared to a historv of event~ that occurred durin~ o~eration of the ~ystem under test. The hi~torv is embodied in a state vector 190 which is a list of the state vector effects from location 168 of the events recognized in qtep 102. The state vector 190 must .
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- . ~ . , be uPdated every time an event is recognized. At the start of diagnostics, the state vector 190 i~ either emDtv or loaded with initial values.
In steD 204, the state vector dependencies for the 5 first event record 154 and the state vector 190 are analYzed to determin~ if the Preconditions sDecifie~ bY
the ~tate vector dependencie~ have occurred. If the precondition~ are not found, the event 154 is not recognized. In step 206, the event ba~ed representation lO 152 is examined to see i~ ther~ are more event~. If there are, the next event is retrieved in 3teD 208. If there are no more events, the analYsi~ iq ended in steP
210.
If. in steD 204, a match is found between the state vector dependencv of event record 154 and the state vector 190, then the event reco~nition analvsis for event record 154 continue~. In qteD 212, the first, data ~ample 170 from the collected data 150 i9 selected. In steP
214, the data sample 170 is compare~ to the critical parameters found at location 164 in the event record 154. In st~r 216, it, i~ determined whether ther,o is a match between the critical Parameters and the data sample. If there is no match, the collecte~ data 150 is examined in ~tep 218 to ~ee if the la~t data ~amPle from collected data 150 was used. If the last, data samPle was used, then step 206 is rePeated to see if everY event record has been used. If there are more data sample~.
they are retrieved in step 220.
I~, in ste~ 216, a match between the critical parameters of event record 154 and the data samPle 170 is found, then the even~. defined bv event record 154 i 9 declared reco~nized in qtep 222. In step 224, the ~tate vector at location 168 of event record 154 i~3 added to the state vector 190 at location 192. Then step 218 is repeated to see if there are mor~ data samPle~ to be used.
_14_ In this way, all data samDles 170 to 174 from collected data 150 are comPared to the critical parameters from every event record 154 to 158 from the event based representation 152. Fi~ure 2 illustrates the 5 recognition of event 1 defined bv event record 154 and event 2 define~ bv event record 156 bv this Process and output from steP 102. The state vector 190, therefore.
consists of a first s~t o~ state vector effects 192 from event 1 and a second set of state vector effects 194 from l~ event 2.
The matchin~ required bv step 102 is ~imPle one~to4 one matching. The imPlementation of such matchin~ is well known in the art.
As was Dreviously mentione~. each event record 154.
156 and 158 is associated with a Pluralitv of ambi~uitY
group effects 176, 178 and 180, resDectivelv. Each ambi~uitv effect sPecifie~s on~ or more comPonents which are either oDerationallv sus~ect or absolved as a result of the analysis and a rankin~ effect for each of the specified comPonents. Fi~ure 2 illustrates events 154 and 156 as havin~ been recognized in steD 102. A subset of ambi~uitv ~roup effects 182 selected from the ~et of ambiguity grouP effects 176 is outPut with event record 154. Similarlv. a subset of ambi~uitv ~roup effects 184 selected from ambi~uitv ~rouD effects 178 i.q outPut with event record 156.
Fi~ure 4 illustrates the analvsis of a reco~nized event 154 to select the subset of ambiguitv ~rouD effects 182 from the set of ambiguity grouP effects 176 which are to be output from steP 102. The event. record 154 has a plurality of affected parameters 230, 232 and 234 at location 164 and a pluralitv of state vector effects 236 and 238 at location 168. The affected oarameters 230 to 234 define the states of parameters of the sYstem under test which should have been affected in some way by the occurrence of th~ event durin~ o~eration of the sYstem.
The actual state of the affected ~arameters can be checked bv reference to the collected data 150. The ; ~
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15_ state vector effects 236 to 238 define the effects of the reco~nized event defined bv event record 154 which should have occurred in ~he sy~tem. The state vector effects at locationq 236 and 238 are relate~ to the affected 5 parameters at locations 230 to 236 or to the critical Parameters at location3 162 either directlv or bY Boolean oDerators. Referrin~ to Fi~ure 3, it is seen that state vector effect 238 is directlv related to affected parameter 230 by pointer 240. The occurrence of the lO effect specified bv the state vector effect 238 can thereby be confirmed by reference back to the data samDle u~ed to reco~niz~ thP event define~ bv event record 154 or other data samDles as needed and bY comParin~ that data to the comDonents state define~ bv the affected Parameters 230. If the component state defined by the affected parameter 230 is found in the data, the state vector effect 238 is confirmed. If it is not, then the state vector effect 238 iS not confirmed.
Fi~ure 4 al~o shows state vector effect 236 related to two affected parameters 232 and 234 bv a Boolean operator 242 throu~h pointers 244, 246 and 248. AnY
state vector effect can b~ so defined if appropriate.
The Boolean oPerator 242 can define any lo~ical combination of affected Darameters. Stat~ vector effect 25 236 iS confirmed. therefore, bV referencing data from collected data 150 and comparin~ it to affected parameters 232 and 234 to see if the Boolean oDerator 242 is satisfied.
Each state vector effect is associated with sets of ambiguitY group effects, one set for uq~ i~ the effect is confirmed by reference to the approDriate affected parameters and another set for U8~ if the effect iq not confirmed by the reference. State vector effect 236 iS.
therefore, associated with a first set of ambi~uitv ~rouD
effects 250 to be used if the effect 236 i.~ confirmed and a second set of ambi~uitY group effects 252 to be used if the effect i~ not confirmed. State vector effect 238 is similarlY associated with a first set of Darameters 254 "".;
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to be used if the e~fect is confirmed and a second ~et of parameters 256 to be use~ if the effect, i9 not confirmed. The combination of ambiRuitv RrouD effects 250 to 256 comprise the ambiKuitv ~roUP effects 176 5 associated with event record 154. In step 104, the appropriate subsets of ambi~uitv ~rouD effects for each recognized event is selected based on the analvsis of the affected Parameters and the state vector effects as described. Referring to Fi~ure 3, assume the effect specified bv the state vector effect 236 iS confirmed bv reference to affected parameters 232 and 234, SO that the first set of ambi~uitv ~roup effects 250 i9 selected for use with outPut 182. Also assume the effect sPecified by the state vector effect 238 is not confirme~ bv reference to affected parameter 230, so that the second 9et of parameters 256 associated with stat~ vector effect 238 iS
selected for use with output 182.
Each ambiguitv grouP effect 250 to 256 ~pecifies what components are susPect or absolved as a result of the event bein~ recognized and a rank for each component according to the level of susPicion for the com~onent.
In addition to analyzin~ event~ reoo~nized from the event based repre~entation 152 to select approPriate ambiguity grouD effects, event~ related to the recoKnized events can also be analyzed to s0lect ambi~uity ~rouP
effects. For example, if the system under test normallY
pro~resses throu~h a sequence of four event~ but onlv three were reoo~ni~ed, the fourth unreco~nized event mi~ht al30 be used to select ambi~uitv ~roup effects.
Re~errin~ to Fi~ure 3, the heuristic rules embodied in a sYmPtomrfault model and a failure model are integrated into the dia~nostic tool in ~tePs 108 to 112 and in stePs 114 to 116, resuectivelv. Fi~ures 5 and 6 illustrate the these ~tep~ in ~reater detail.
Figure 5 illustrates the use of ~vmPtomnfault model 300 in steD 110. The symptom~-~fault model ~00 comprises a pluralitY of ~Ymptom~fault relationships 302, 304 and 306 which aPplv t~ the sYStem under test. The ~ymptom*fault .
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relationships 302 to 306 are stored in a data ba~e. Such symptom*fault models containin~ ~ set o~ heuristic rules descriPtive of the svmDtom~fault relation~hiPs o~ the 9Ystem under test are well known. The data for these models i9 collected and derived from technical orders, repair manuals9 technician observations, lo~istic~ data or an~ other source of sYstem ~ailure data.
To use the symptom;7fault model 300, the operation of the system under test is observed in steD 108. The observed data 308 is formatted to allow comParison with each svmPtom~fault relationshiP 302 to ~06. In ~tep 110, all of the observed data 308 is comDare~ to each one of the symPtom~fault relationshiPs 302 to ~06 in the symptom~fault model 300 t~ find those relationshiP.~ which match the observed data and, therefore. are applicable to the operation of the system under test.
Each symptom~fault relationshiD ~02, 304 and 306 is associated with a set of ambiguitv ~rouD effects 310. ~12 and 314, resPectivelY, each of which sPecifY one or more components and a rankin~ effect for each of the sPecified components. Where the comParison made in step 110 specifies the applicabilitv of anv of the sYmDtom~fault relationshiPs 302 to 306 to the oPeration of the svstem under test, the associate~ set of ambiguitieq are outPut in step 112. In Fi~ure 5, for examPle~ the symDtom~fault relationship~ 302 and 306 ar~ determined to be a~Plicable to the svstem under test in steP 110, so that the associated sets of ambi~uitv group effects 310 and 314 are outPut.
Fi~ure 6 illustrates the use of the failure model 320 in steP 114 in ~reater detail. The failure model 320 comprises a Plurality of heuristic rules which define potential failures in the sY~tem under test. Failure models are well known and are tyPicallv Presented in the form of If~Then rule3. The failure model 320 of the present invention comPrises a pluralitY of patterns which are associated with each rule. The failure model ~20, therefore, comDrises a PluralitY of Datterns 324, 326 and 328.
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The inPuts 320 used for comDarison again~t the ~attern~ of the failure model 320 are derived from several sources. Event~ recognized in step 102 are utilized to form Event Recognition Records 332 and 334.
Each Event Recognition Record 332 and ~24 al30 has a Pointer that sPecifie~ the location of the data samPle 170 to 174 from which the event was recoRniZed. In thi~
way, the data ~amples 170 to 174 are als~ available for compari~on to the patterng of the ~ailure model 320.
Similarl,y, the symptom~ault relation~hips which were found to exist in step 110 are used to form Pattern reco~nition records 336 to 338.
The pattérns 324 to 328 of the failure model 320 are defined by logical combinations of event criteria which can correspond to the event recognition records 331 to 334, to the Pattern reco~nition records 336 to 338. or to any other inDuts 330 which may be aPDlicable. In step 114, all of the inputs 330 are comDare~ to each Dattern 324 to 328 in the ~ailure model 320. The matchin~
required to perform steD 114 i.~ nificantly more difficult than the matching required to perform event recognition in ste~ 102. A "manv to many" matchin~
strategy is used in the Preferred embodiment because each recognition record 332 to 338 can have manv com~onent parts that must be comDared to a pattern 324 to 328 which mav be defined by manv event criteria. In the ~referred embodiment, CLIPS. an artificial intelli~ence lanRua~e.
is u~ed to implement a matchin~ algorithm base~ on the Rete Network. Other lanRuages which can be used include OPS5 and SOAR.
Each pattern 324, 326 and 328 in the failure model 320 is associated with a set o~ ambi~uitv ~rouD effects 340, 342 and 344, resPectivelv. as before. When the matchin~ Performed in ~t,~n 114 determine~ that ~ Dattern exist~, it is outPut with its as~ociated set of ambi~uitv ~rouP e~ects. In Fi~ure 6, ~or example. ~attern 326 has been recognized 90 that the associated set of ambi~uity group effects 342 is outPut in ~teD 116.
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'~1 9-When the pattern 326 i9 recognized in SteD 114, a new Dattern recognition record 346 i.q develoDe~ an~ added to the input set 330. The matching performed in ~tep 114 continues until all of the Dattern reco~nition records.
includin~ those develo~ed during the matchin~. have been comPared to the failure model 320.
Fi~ure 7 illustrates two sets of ambi~uitv ~roup effects 360 and 362. an ambi~uitv ~roun 364 and a structural model 366 of the system under test. The ambiRuity group 364 comprises a ranked listin~ of sYstem com~onents as sDecified by the sets of ambiguitv ~rouP
effects 360 and 362 and Pointers 368. 370 and 372 which are associated with each comPonent. Initiallv. all comPonents in the ambiRuitv grouD 364 are equall~ ranked at an arbitrarY number. say 0. A~ each model or representation of the sYstem under test is analvze~ and re~analyzed, the ambi~uitY ~roup effects 360 and 362 are Renerated~ each of which specifv one or more system comPonents which are to be re~ranked and the rankin~
effect to be aPplied to the component in its ambiRuitv grouP ranking. Ambi~uitv ~roup effects 360 and 362 each specifY two sYStem comPonentq t~ be rehranked in the ambi~uity group 364 and a ranking effect for each of the two specified components. The rankin~ effect.~ are arbitrary numbers which only have meanin~s relative to other rankin~ effects. Th~ rankin~ effect for a ~iven ambi~uity group effect should. therefore. be chosen to reflect the accuracv of the analysis.
In ste~ 106, each set of ambiguity grouP effects 360 and 362 are aPplie~ t~ the ambi~uitv ~rouD 364.
Initially, all comPonents A, B and N in the arbitrarv grouD have a rank of 0. Ambiguitv ~roup effect ~60 specifies that system comDonents A and B are susPect~ and should be re-ranked with A rankin~ effect of ~10 applied. Ambi~uity ~rou~ effect 362 sDecifies that system oomPonents A and N are not suspected. The rankin~
effect. -10, is applied to lower the ranking of comDonent A to 0, as indicated. ComPonent N is re~ranke~ with a ,~ . . ; .
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2~2~2 ~20 -ranking effect of -10 aDPlied. The ambi~uity ~roup effects 360 and 362 can b~ ~enerated bY anY of the analysis steps previously discussed or by any other model of the system under test.
Each comPonent A. B and N in the ambi~uitv ~roUP 364 is associated with pointers 368. 370 and ~74.
respectivelv. which point to the locations of the components in the structural model 366. After the processing of all sets of ambiKuitY ~rouD effects 360 and 362, the ambiguitv grouD 364 rank.q each comPonent in the list according to its likelyhood of failure. The structural model 366 can now be analYzed bv referencing the system comPonents at the top of the ambi~uitv group 364, such as component B, and locatin~ the component in the structural model 366 by means of the associated pointer, in this case pointer ~70.
The structural model 366 is similar to known structural models in that it sPecifie~q the sYstem~s comPonent connectivitv and hierarchy. Previous diagnostic tool~s have had difficulty utilizin~ such structural models of comPlex sYstems~ because of the large number of comPutation~ needed t~ analY~e the structural model. The dia~nostic tool of the present invention makes the use of such models more comPutationally attractive than other analytical tools by pointin~ to the location in the structural model comPonent with the ~reatest likelvhood of failure, therebv avoidin~ unnecessarv and len~thv computations.
In addition to the specification of svstem characteristics such a.q connectivitv and hierarchY, the structural model 366 in accordance with a Preferred embodiment of this invention includeq a qualitative descriPtion of the components rePresented. Included in the description i.q a list of maintenance options Possible for each ComDonent. This mi~ht include sPecial te~t or calibration procedures, or replace and rePair procedures. The analYsis of the hi~hest ranked components in the ambiguitv group leadq to thP structural . . , . ,. , . :, ,, ~.
. - . .
.
:
~Z~2 ~21~
model 366 and yields one or more of these maintenance options. Fi~ure 7 illustrateq two maintenance o~tions 374 and 376 being outDut as a result of the analYsis.
Associated with each maintenance oPtion is an expected result. Fi~ure 8 illu~trates expected result 378 being associated with maintenance option 374. As before mentioned in describing ste~ 122, the actual result 380 obtained in performin~ the malntenance option 374 can be comPared to the expected results 378. Each expected result 378 is associated with two sets of ambi~uitv groUP effects 382 and 384, a first set 382 for use if the exPected result~ ~78 are confirme~ bv the actual results 380 and a second set 384 for use if the expected results 378 are not confirmed. Th~ sets of ambiguitY grouP effects 382 and 384, as before, specifv components which should be re~ranked in the ambi~uitv ~roup accordin~ to an associated rankin~ effect in steD
106. As a result of the comparison ste~ 122, the approPriate set of ambi~uitv ~roup effects 382 or 384 is output for use in steP 106. Fi~ure 8, for examPle, illustrates the case where the exPected results 378 are confirmed bv the actual results 380, so that the first set of ambiguitv ~roup effects 382 is selected to be an outPut 382 from sten 124. The sten 122 can be repeated every time a maintenance option is performed.
As a further step, once the ranking of component.s in the ambiRuitv group 364 is comPlete, but before the analysis of the structural model 366 in steD 118, the components in the ambi~uitv ~roup 364 can be ~rouped accordin~ to functional or structural relationships. In this way a lo~ical Progression of dia~nosis throu~h the system can Proceed~ so that the maintenance oPtions which are outPut in step 112 do not su~est the testin~ of unrelated comPOnents. This is further illustrated in Fi~ure 9, wherein ambiRuitv ~rouP 400 contains a plurality of components from the fuel sub~system of the system under teCit and a Dluralit~ of comPonents from the electrical sub;system of the system under test, all : ; , .
2~
havin~ a variety of ranks. Accordin~ to thi~ ~tep, which is performed after the steP 106 but before steP 118, the com~onents which are ~unctionally related to the fuel sub~system are selected to form ~ fir~t ~rouD 402 while the components which are functionallv related to the electrical sub~system are selecte~ to ~orm a second ~rouD
404. The analysi~ of the structural model 366 in steP
118 can then proceed usin~ one of the functionallv related ambi~uitv grouDs 402 or 404. One subrsv3tem at a time can be, therefore, completelv te~ted.
The invention is not limited to the use of the models and representations discussed. Other models.
representations or factors which characterize ths sv~tem can be used bv assiRnin~ a set of ambi~uitv ~rouD efrects to each result obtained from the use of the alternative model t representation or factor. In this way, the most accurate characterization of the system under test or combination of characterization.~ can be use~ to obtain the optimum diagnostic reqult. The assi~ned sets of ambi~uitY ~roup effect.s can then be aDPlie~ to the ambiRuitv ~rouP 364 in steP 106. BY way of examDle onl results obtained from the use of reliabilitv statistics, Failure Modes and Effects analvsis (FMEA) and maintenance historie~ can be used in this manner.
Furthermore, the invention does not require the use of all of the step~ and all o~ the sv3tem reDre~entations or model~ Previously enumerated. If any of the rePresentation~ or models of the system under test are of low qualitY or if anY step yields consistentlY Poor results thev can be omitted fr~m the dia~nosti~ tool.
This mi~ht occur more freauentlY in the case of heuristic rule based knowled~e representations, wherein an adeauate set of rules is often difficult to develoD.
In the event that the previouslv de~cribed steP~ do not diagnose the fault in this system under test, the analysis maY be further exPanded in accordanc~ with an alternate embodiment o~ the present invention, Referrin~
to Figure 10, and Event Structured ComPonent Model 410 i~
. . .
illu3trated. This model 410 is an expansion of the structural model 366 described before and to other known structural models.
The model 410 ComPri~es a de~criPtion of a Plurality of comDonents 412, 414 and 416. The model 410 include~
static characteristic~ at location 418 for each comDonent 412 to 416 a.q doe~q the ~tructured model 366. ThP ~tatic characteristics 418 de~cribe the component repair profile, in Particular th~ testabilitv and acce~ibilit,y of the component. The maintenance opt~ons 418 and 420 which are outDut in ~teD 120 of the preferred embodiment are alqo included here. These characteristic~ 416 can be used by a 3y~tem technician t~ determine wh~t t,~ do next. Further tests on the comDonent can be Derformed if the model in 410 indicate~ that the comDonent i9 testable. Additionally, adiustment~ to the ComDOnent can be made if the model 410 indicate3 the comDonent, is accessible to the technician. The~e static characteristic~ 416 are acce~sed ViA the ambiguitv 2rouP
POinterS in the preferred embodiment of the invention.
These static characteristics 416 can be subsetted alon~
with a static connectivity repre~entation to construct the structural model 366.
The Event Structured COmDonent Model 410 is differentiated from the structural model 366 bv the inclusion oi' dynamic characteristic~ of each comDonent at location~ 422 throu~h 424. The dynamie characteristics at a particular location characterize the comDonents connectivity, hierarchy. performanc~ characteristic~ and function at a ~iven phase or event within the ~vstem under te~t. Th~ connectivitv of the COmDOnent, is characterlzed by sPeCifVin~ the inDuts and OUtDuts to the component and the connective medium. The hierarchv of the component describe~ suPer and subcomPonent~ of the 3~ component. In other word~, the hierarchv of the component de3cribe~ whether the comDonent i 3 part of another ~rouD of component~ or con3ists of a grouP of comPonent~. The Performance characteristic~ of the ComDonent are also included in it~ dynami~ characteristics.
, ~, :
. .
, ,.,, ~ :
, To use the Event Structured ComPonent Model 410, the operational historv of the APU contained in the state vector developed in steD 102 i3 analYZed to determine the pha9e of failure of the 9ystem. By knowin~ the normal 9equence o~ events in the o~eration of the system under te~t, and bv com~arin~ ~ t to the recognized events, the phase of failure of the s~stem under test can b~ determined. The Event Structured Component Model 410 can than be accessed by comPonent accordin~ to the ambi~uitY grouD a~ PreViouslY
described. The comPonent in the model 410 is further referenced bv the determined Phase of failure. So, for exam~le, if comPonent 2 at location 414 is determined bY
analysis of the ambi~uitv groun to be the most ~usPect lS ComPonent, that COmDOnent in model 410 is referenced.
If the failure of the sYstem i~ determined to have occurred in phase 1 by analYsis of the state vector obtained in steD 102, then the dynami~ characteristics of phase 1 of the ~econd comDonent at location 422 are accessedO These dynamic characteristic~ are used to recreate what the sY~tem should look like as comPared to the actual operational characteristics of the system.
This procedure can be used to su~gest further component~ to be analYzed throu~h the Event Structured ComPonent Model 410O This search. however, must be limited to prevent computational problems. It mav be limited by data derived during event recognition, by functional and structural connections. bv connectivit~
paths or by components havin~ a low rankin~ in the ambiguitv ~roup.
The dia~nostic tool of the Present invention is applicable to a varietv of systems. The diagnostic tool comPrises a hYbrid knowledge rePre~entation and a series of analytical steps as described herein to use the hybrid knowledge representation. In aPplying the dia~nostic tool, the analytical steps are system independent, so that any of the stePs described herein can be used for any ~ystem. The knowled~e . :
, .
rePresentations~ however. are svstem deDendent and must be modified t~ represent the system desired to be analvzed.
An examPle of the dia~nostic tool as applied to an Auxiliary Power Unit (APU) for an airplane is now given. The application of the diagnostic tool to an APU
is also described in "APU Maid: An EventeBased Model For Diagnosis", published November 3, 1987 at the AUTOTESTCON meeting, which is incorporated herein bV
reference. Auxiliarv Power Units are ~as turbine engines used for aircraft ~round base suPDort for pneumatic power and generator support and in the air for both suPplemental and emer~ency power support. The APU
can either be used from a ~round cart or installed in the aircraft as Part of the Pneumatic svstem. The APU's engine is comDrised of a comDressor/turbine section, with attachinÆ comPOnentS that make UD the units fuel, bleed air, lubrication and electrical svstems.
.
, : . . . ... -:
:. ~' . ~ , .' ~,:
.. . . ~ .
::
- . :: . .
2~:
Table 1 illustrates a sin~le data samDle havin~
label DS200 which is collected durin~ the o~eration of the APU. The data samPle Provides 9iX channels of analo~ data, includin~ the time of the data samPIe~ the oil pressure. the compressor discharge pregsure. the fuel pressure, the exhaus~ ~as temDeratur~ and the engine rpm. It also provides 16 channels of di~ital data as indicated.
TABLE 1: DATA SAMPLE DS200 ANALOG
CHANNEL PARAMETER VALUE UNIT
S
1 Poil 2.1 PSI
2 PcomPressor discharÆe O PSI
3 Pfuel 40.0 PSI
4 EGT (exhaust gas 100.0 F
temPerature) ~RPM (100~ = 39,000 RPM 11 %RPM
OVERSPEED = 44,000 RPM) DIGITAL DISCRETE
CHANNEL PARAMETER VALUE
25 o CENTRIFUGAL SWITCH (static test/REDUN 8) 1 START RELAY/START MOTOR (static test/ REDUN 9) 2 OIL P. DOOR CNTRL (NC) VALVE (static test/REDUN 10) 95% CENT/ON SPEED RELAY (NO) O
BLEED AIR VALVE O
11 APU FUFL RELAY CNTRL (static test/REDUN 7) 0 12 OIL P. SEQ SW (static test/REDUN 14~ 1 13 OIL P. SEQ SW (NO) (static te~t/REDUN 15) 0 FUEL CONTROL VALVE SOLENOID
... .
' :
~27-Table 2 COmDriseS a subset of event records from an event ba.~ed representation of the APU. Four event records which define th~ start of the APU, the start of combu~tion within the APU, the reaction to the combustion and the actual combustion are shown.
TABLE 2: PARTIAL APU EVENT BASED REPRESENTATION
EVI1 i START EVENT
1) STATE VECTOR DEPENDENCIES
2) CRITICAL PARAMETER "START -S~" = l 3) AFFECTED PARAMETERS
"ASR" = 1 "APUrSTART RELAY" = 1 "APU-START MOTOR" = 1 "OVERSPD~TEST~.SOLENOID" = l l5"FHR" = 1 4) STATE VECTOR EFFECTS & AMBIGUITY GROUP EFFECTS (AGE) EV1 ~ 1 START~SW = 1; A OE ~ 10 3 0; AGE + 10 20ASR = 1; AGE ~~ 10 = O; A OE + 10 APU-START RELAY = 1; AGE ~ 10 = O; AGE + 10 APU-START MOTOR = 1: AGE ~ 10 25~ ; A OE + 10 OVERSPEED-TEST.-SOLENOID = 1; A OE ~ 10 = 0~ A OE + 10 FHR = 1: AGE ~i 10 = O; AGE + 10 EV2 ~ COMBUSTION.~START EVENT
1) STATE VECTOR DEPENDENCIES
START~EVENT ~ 1 2) CRITICAL PARAMETERS
P~OIL = 2 - 3. 5 PSI
%RPM = GT 0 .: , ;. l .. . , , .: .
3) AFFECTED PARAMETERS
OIL-P.-SEQ-SW = 1 IGNITION-UNIT = l TIME = LT 7 SEC
4) STATE VECTOR EFFECTS
EV2~1 - OIL~P~SEQ~SW = l: AGE ~ 10 = 0: AGE + 10 EV3 ~ COMBUSTION`-REACT EVENT
1) STATE VECTOR DEPENDENCIES
COMBUSTION~START EVENT ~ 1 2) CRITICAL PARAMETERS
P~FUEL ' GT O PSI
3) AFFECTED PARAMETERS
P`~FUEL = 40 PSI
FUEL CONTROL VALVE SOL = 1 4) STATE VECTOR EFFECTS
EV3 ~ 1 FUEL CONTROL VALVE SOLENOID AND P FVEL
= 1: FUEL CONTROL VALVE SOL, ~ AGE - 10 = 0; FUEL CONTROL VALVE SOL, AGE + 10 1) STATE VECTOR DEPENDENCIES
C0~3USTION~REACT EVENT = l 2) CRITICAL PARAMETER
"EGT" GT 400 F
3) STATE VECTOR EFFECTS
EV4 = 1 IGNITION~UNIT = 1; A OE - 10 = 0 AGE + 10 ` - .: , , ` . , j '.'` ,. - ' :' .
:
'.
-29, Assume that Events 1 and 2 have been reco8nized bY
havin~ their critical Parameters matched bv data samPles prior to DS200. As a result of events 1 and 2 bein~
recognized the state vector effect~ from thos~ event~ have been added to the state vector, as illustrated in Table 3.
The event reco~nition process o~ ste~ 102 ~or event 3 is now described. Assume that the data samDles ~rior to DS200 have alreadY been comPared t~ event 3. Data samPle DS200 is now compared. The first step is to check the state vector dePendencies, which specifY preconditions for the event to have occurred. a~ainst the state vector, which is a historv of reco~nized events.
TABLE 3: STATE VECTOR
EV1 = 1 START,SW = 1 ASR =1 APU-START RELAY = 1 APU~START MOTOR =1 OVERSPEED-TEST~SOLENOID = 1 FHR =1 EV2 =1 OIL~-P-SEQ~SW = 1 EV3 = 1 FUEL~CONTROLrVALVE~SOL = 1 .. . .. . .
=30-The state vector dependencv for Event 3, as indicated by Table 1, is that event 2 (Combugtion Start Event = 1) occurred. Checking the state vector in Table 3, event 2 i~
listed as havin~ occurred (EV2 = 1) so event reco~nition can continue. The critical Darameters of Event 3, fuel Pressure ~reater than 0 PSI (Pfuel GT 0 PSI), is compared to data sample DS200 next. Analo~ channel 3 of DS200 indicates that the ~uel pressure is 40 PSI, greater than 0. Event 3 i5.
therefore, reco~nized.
Event 4 is now checked. The precondition for its bein~
recognized, event 3, i~ in the state vector, so that analysis of the data sam~le DS200 can now occur. The critical parameter for thi~ event is that the exhaust Ras temPerature be ~reater than 4000F. Checkin~ the data samPle DS200 on analo~ channel number 4 it is seen that the temperature is only 100F. This event, therefore, is not recognized. Assume n~ other data samPl~ serve.q to reco~nized Event 4.
The recognized events as well as any events which were not recognized but are relate~ t~ the reco~nize~ event~ are now analyzed to determine which ambi~uitv ~roup effects to use. Referrin~ to event 1 in Table 2, six com~onents which are directlv related to the critical Parameter and the affected ParameterS~ ar~ listed. The aPpropriatR rankin~
effect, in this case, is determined by referencin~ the data samPle DS200 to confirm the state of the affected Darameters defined in the state vector effect. Considering the first affected Parameter Pointe~ t~ bv the statQ vector effect of event 1, the state of the start switch is alreadv known since that was the critical Darameter. Since th~ state of the start switch is 1, the ambi~uitv group effect that specifies a *10 ranking for that comPonent is selected.
Considerin~ the second affected parameter, the state of the APU start rela~, digital channe~ number 9 of DS200 shows a discrete value of 1. This ComDares to the state of the affected ~arameter as listed in event 1, confirmin~ the state vector effect. so then the ambi~uitv ~roup effect that assigns a rankin~ of ~10 to ASR is selected. In a similar .
-.
.;
z~
fashion, it is seen that the ambi~uit~ ~roup effects selected from event 1 should assi~n a rankin~ of 10 to the remaining co~Ponents as well as to the components sDecified in the state vector effects of event 2.
Event 3 has a state vector e~ect defined by the lo~ical combination of the state Or the fuel control valve solenoid and fuel Pressure bein~ ~reater than 40 PSI. To confirm this state vector effect, therefore. both of these affected ParameterS must be confirmed by data samDle DS200. Referin~ to analoe channel 3, the fuel pressur~ is 40 PSI, confirming that affected parameter. Referring to digital channel 15, the fuel control valve solenoid activated (=1), confirmin~ that affected Parameter. Since the logical combination of affected parameterq i.s satisfied.
15 the state vector effect is confirmed. The associated `
ambiguity grouP effect absolvine the fuel control valve solenoid with a ranking effect of ~10 is selected.
Event 4 wa.~ not. recognized durin~ the event recoenition steP. however, it is clearly related to events 1, 2 and 3.
That event is, therefore, also analvzed to determin~ an appropriate ambi~uitv ~roup effect. The state vector effect is directlv related to the ienition unit. Referrine to DS200 in Table 1 it is seen that the ienition unit has a discrete value of 0. The associated ambiguitv ~rou~ that assi~ns a rankin~ effect of +10 is, therefore, selected for use.
.' ' ' ', .', ':' ~"'' , , . .:
~Z;~2 Table 4 i]lustrates symDtom/fault relationshiDs which exist in a sYmPtom/fault model of the APU. The APU
operation is observed and data is entered based on that observation. If we assume that the observe-l data sPecifies that the starter is crankin~ the engine but combustion is not occurring, then the symPtom/fault relationshiP labeled SF10 is selected. The ambi~uity grouD effect associated with SF10 is outPut for use. The ambi~uitv ~rouP effect sPecifies a list of comPonents which are susDect in a ranking effect which is associated with each comPonent.
Table 5 illustrates a failure model which ComPrises two event Pattern~. The firAt event Pattern i~ defined bv three event criteria, EC1, EC2 and EC39 which must all occur for event Pattern 1 to be recogniæed. Event criteria 1 i.q further defined a5 the logical combination of event record 3 and not event record 4~ Event criteria 2 is defined as the Dattern recognition record which results from SF10 bein~ reco~nized.
Event criteria 3 is defined as a Dattern reco~niti ~n record which results from a sDecial test which i~ Performed on the accelerator limiter. Associated with the first event Dattern is an ambiguitv ~roup effect which sDecifies the acceleration limiter as a suspect comPonent and a rankin~ effect of +10.
The second event pattern is also defined by the three event criteria of above. Event criteria 1 an~ event criteria 2 are the same as above. however, event criteria 3 is a Pattern recognition record which results from a sPecia1 test which is performed on the i~nition unit. The ambi~uitv effect assoeiated with the second event pattern sPecifies that the ignition unit is susPect and assi~ns a rankin~ effect of +10. There are manv more event Patterns in an APU failure model, however. onlv two are shown here.
If we assume that the results of the sPecia~ test Performed on the accelerator limiter is ne~ative then event pattern 1 is not recognized. On the other hand if we assume that the result~
of the sPecial test Performed on the i~nition unit is Positive~
then event Pattern 2 is reco~nize~ and the associated ambi~uitv ~roup effect, which s~ecifies the i~nition unit as a susPect component an~ a rankin~ effect of + 10 is outPUt.
: ' ' ' , ~, .
:: -', ~ ' ~ .
TABLE 4: SYMPTOM/FAULT RECORDS
TEXT - "No response from starter when start switch is actuated"
temPerature) ~RPM (100~ = 39,000 RPM 11 %RPM
OVERSPEED = 44,000 RPM) DIGITAL DISCRETE
CHANNEL PARAMETER VALUE
25 o CENTRIFUGAL SWITCH (static test/REDUN 8) 1 START RELAY/START MOTOR (static test/ REDUN 9) 2 OIL P. DOOR CNTRL (NC) VALVE (static test/REDUN 10) 95% CENT/ON SPEED RELAY (NO) O
BLEED AIR VALVE O
11 APU FUFL RELAY CNTRL (static test/REDUN 7) 0 12 OIL P. SEQ SW (static test/REDUN 14~ 1 13 OIL P. SEQ SW (NO) (static te~t/REDUN 15) 0 FUEL CONTROL VALVE SOLENOID
... .
' :
~27-Table 2 COmDriseS a subset of event records from an event ba.~ed representation of the APU. Four event records which define th~ start of the APU, the start of combu~tion within the APU, the reaction to the combustion and the actual combustion are shown.
TABLE 2: PARTIAL APU EVENT BASED REPRESENTATION
EVI1 i START EVENT
1) STATE VECTOR DEPENDENCIES
2) CRITICAL PARAMETER "START -S~" = l 3) AFFECTED PARAMETERS
"ASR" = 1 "APUrSTART RELAY" = 1 "APU-START MOTOR" = 1 "OVERSPD~TEST~.SOLENOID" = l l5"FHR" = 1 4) STATE VECTOR EFFECTS & AMBIGUITY GROUP EFFECTS (AGE) EV1 ~ 1 START~SW = 1; A OE ~ 10 3 0; AGE + 10 20ASR = 1; AGE ~~ 10 = O; A OE + 10 APU-START RELAY = 1; AGE ~ 10 = O; AGE + 10 APU-START MOTOR = 1: AGE ~ 10 25~ ; A OE + 10 OVERSPEED-TEST.-SOLENOID = 1; A OE ~ 10 = 0~ A OE + 10 FHR = 1: AGE ~i 10 = O; AGE + 10 EV2 ~ COMBUSTION.~START EVENT
1) STATE VECTOR DEPENDENCIES
START~EVENT ~ 1 2) CRITICAL PARAMETERS
P~OIL = 2 - 3. 5 PSI
%RPM = GT 0 .: , ;. l .. . , , .: .
3) AFFECTED PARAMETERS
OIL-P.-SEQ-SW = 1 IGNITION-UNIT = l TIME = LT 7 SEC
4) STATE VECTOR EFFECTS
EV2~1 - OIL~P~SEQ~SW = l: AGE ~ 10 = 0: AGE + 10 EV3 ~ COMBUSTION`-REACT EVENT
1) STATE VECTOR DEPENDENCIES
COMBUSTION~START EVENT ~ 1 2) CRITICAL PARAMETERS
P~FUEL ' GT O PSI
3) AFFECTED PARAMETERS
P`~FUEL = 40 PSI
FUEL CONTROL VALVE SOL = 1 4) STATE VECTOR EFFECTS
EV3 ~ 1 FUEL CONTROL VALVE SOLENOID AND P FVEL
= 1: FUEL CONTROL VALVE SOL, ~ AGE - 10 = 0; FUEL CONTROL VALVE SOL, AGE + 10 1) STATE VECTOR DEPENDENCIES
C0~3USTION~REACT EVENT = l 2) CRITICAL PARAMETER
"EGT" GT 400 F
3) STATE VECTOR EFFECTS
EV4 = 1 IGNITION~UNIT = 1; A OE - 10 = 0 AGE + 10 ` - .: , , ` . , j '.'` ,. - ' :' .
:
'.
-29, Assume that Events 1 and 2 have been reco8nized bY
havin~ their critical Parameters matched bv data samPles prior to DS200. As a result of events 1 and 2 bein~
recognized the state vector effect~ from thos~ event~ have been added to the state vector, as illustrated in Table 3.
The event reco~nition process o~ ste~ 102 ~or event 3 is now described. Assume that the data samDles ~rior to DS200 have alreadY been comPared t~ event 3. Data samPle DS200 is now compared. The first step is to check the state vector dePendencies, which specifY preconditions for the event to have occurred. a~ainst the state vector, which is a historv of reco~nized events.
TABLE 3: STATE VECTOR
EV1 = 1 START,SW = 1 ASR =1 APU-START RELAY = 1 APU~START MOTOR =1 OVERSPEED-TEST~SOLENOID = 1 FHR =1 EV2 =1 OIL~-P-SEQ~SW = 1 EV3 = 1 FUEL~CONTROLrVALVE~SOL = 1 .. . .. . .
=30-The state vector dependencv for Event 3, as indicated by Table 1, is that event 2 (Combugtion Start Event = 1) occurred. Checking the state vector in Table 3, event 2 i~
listed as havin~ occurred (EV2 = 1) so event reco~nition can continue. The critical Darameters of Event 3, fuel Pressure ~reater than 0 PSI (Pfuel GT 0 PSI), is compared to data sample DS200 next. Analo~ channel 3 of DS200 indicates that the ~uel pressure is 40 PSI, greater than 0. Event 3 i5.
therefore, reco~nized.
Event 4 is now checked. The precondition for its bein~
recognized, event 3, i~ in the state vector, so that analysis of the data sam~le DS200 can now occur. The critical parameter for thi~ event is that the exhaust Ras temPerature be ~reater than 4000F. Checkin~ the data samPle DS200 on analo~ channel number 4 it is seen that the temperature is only 100F. This event, therefore, is not recognized. Assume n~ other data samPl~ serve.q to reco~nized Event 4.
The recognized events as well as any events which were not recognized but are relate~ t~ the reco~nize~ event~ are now analyzed to determine which ambi~uitv ~roup effects to use. Referrin~ to event 1 in Table 2, six com~onents which are directlv related to the critical Parameter and the affected ParameterS~ ar~ listed. The aPpropriatR rankin~
effect, in this case, is determined by referencin~ the data samPle DS200 to confirm the state of the affected Darameters defined in the state vector effect. Considering the first affected Parameter Pointe~ t~ bv the statQ vector effect of event 1, the state of the start switch is alreadv known since that was the critical Darameter. Since th~ state of the start switch is 1, the ambi~uitv group effect that specifies a *10 ranking for that comPonent is selected.
Considerin~ the second affected parameter, the state of the APU start rela~, digital channe~ number 9 of DS200 shows a discrete value of 1. This ComDares to the state of the affected ~arameter as listed in event 1, confirmin~ the state vector effect. so then the ambi~uitv ~roup effect that assigns a rankin~ of ~10 to ASR is selected. In a similar .
-.
.;
z~
fashion, it is seen that the ambi~uit~ ~roup effects selected from event 1 should assi~n a rankin~ of 10 to the remaining co~Ponents as well as to the components sDecified in the state vector effects of event 2.
Event 3 has a state vector e~ect defined by the lo~ical combination of the state Or the fuel control valve solenoid and fuel Pressure bein~ ~reater than 40 PSI. To confirm this state vector effect, therefore. both of these affected ParameterS must be confirmed by data samDle DS200. Referin~ to analoe channel 3, the fuel pressur~ is 40 PSI, confirming that affected parameter. Referring to digital channel 15, the fuel control valve solenoid activated (=1), confirmin~ that affected Parameter. Since the logical combination of affected parameterq i.s satisfied.
15 the state vector effect is confirmed. The associated `
ambiguity grouP effect absolvine the fuel control valve solenoid with a ranking effect of ~10 is selected.
Event 4 wa.~ not. recognized durin~ the event recoenition steP. however, it is clearly related to events 1, 2 and 3.
That event is, therefore, also analvzed to determin~ an appropriate ambi~uitv ~roup effect. The state vector effect is directlv related to the ienition unit. Referrine to DS200 in Table 1 it is seen that the ienition unit has a discrete value of 0. The associated ambiguitv ~rou~ that assi~ns a rankin~ effect of +10 is, therefore, selected for use.
.' ' ' ', .', ':' ~"'' , , . .:
~Z;~2 Table 4 i]lustrates symDtom/fault relationshiDs which exist in a sYmPtom/fault model of the APU. The APU
operation is observed and data is entered based on that observation. If we assume that the observe-l data sPecifies that the starter is crankin~ the engine but combustion is not occurring, then the symPtom/fault relationshiP labeled SF10 is selected. The ambi~uity grouD effect associated with SF10 is outPut for use. The ambi~uitv ~rouP effect sPecifies a list of comPonents which are susDect in a ranking effect which is associated with each comPonent.
Table 5 illustrates a failure model which ComPrises two event Pattern~. The firAt event Pattern i~ defined bv three event criteria, EC1, EC2 and EC39 which must all occur for event Pattern 1 to be recogniæed. Event criteria 1 i.q further defined a5 the logical combination of event record 3 and not event record 4~ Event criteria 2 is defined as the Dattern recognition record which results from SF10 bein~ reco~nized.
Event criteria 3 is defined as a Dattern reco~niti ~n record which results from a sDecial test which i~ Performed on the accelerator limiter. Associated with the first event Dattern is an ambiguitv ~roup effect which sDecifies the acceleration limiter as a suspect comPonent and a rankin~ effect of +10.
The second event pattern is also defined by the three event criteria of above. Event criteria 1 an~ event criteria 2 are the same as above. however, event criteria 3 is a Pattern recognition record which results from a sPecia1 test which is performed on the i~nition unit. The ambi~uitv effect assoeiated with the second event pattern sPecifies that the ignition unit is susPect and assi~ns a rankin~ effect of +10. There are manv more event Patterns in an APU failure model, however. onlv two are shown here.
If we assume that the results of the sPecia~ test Performed on the accelerator limiter is ne~ative then event pattern 1 is not recognized. On the other hand if we assume that the result~
of the sPecial test Performed on the i~nition unit is Positive~
then event Pattern 2 is reco~nize~ and the associated ambi~uitv ~roup effect, which s~ecifies the i~nition unit as a susPect component an~ a rankin~ effect of + 10 is outPUt.
: ' ' ' , ~, .
:: -', ~ ' ~ .
TABLE 4: SYMPTOM/FAULT RECORDS
TEXT - "No response from starter when start switch is actuated"
5 A OE - + 10 AG - BATTERY/EXTERNAL.-POWER
AIR~INTAKE~DOOR
FUSES
CENTRIFUGAL SWITCH
APU.START-RELAY
ASR
STARTER~MOTOR
STARTER~SWITCH
PHASE O
TEXT - "Starter rotates onlY while start switch is depressed"
AGE ~ 10 AG - ASR
FHR
WIRING
BATTERY/EXTERNAL~.POWE2 SF10 (selected) TEXT - "Starter cranks engine but combustion does not occur"
AGE - + 10 AG - FUEL-SUPPLY
WING-TANK~FUEL~VALVE
FUEL-PUMP
ACCELERATION~LIMITER
FUEL~CONTROL-VALVE~SOLENOID
IGNITION~UNIT
OIL~P`-SEQ-SWITCH
OIL-SUPPLY
OIL~-PUMP
OIL~FILTER
TURBINE~ASSEMBLY
- - , . . .
..
.:
TABLE 5: E~AILURE I~ EL
EP1 = ECI AND EC2 ANY EC3 ECI .i ER3 AND NOT ER 4 EC2 - PR(S/Fl O) 5 EC3 ~ PR (sPecial test Acceleration~limiter - 3) AOE . ACCE~RATION LIMI~R, ~lO
EP2 = ECl AND EC2 AND EC3 EC2 - PR(S/F10) EC3 ~ PR (sPecial test IGNITION~UNIT - 4) AGE
IGNITION-UNIT, +10 If we collect all of the ambi~uitY ~roup effects from each reco~nized and analvzed event record, from each reco~nized svmPtom/fault relationship and from each recognized event pattern from the ~ailure model and aDPlY
the ranking effects, the ambi~uitv ~rouD as shown in Table 6 results. The elements ranked at -10 were all specifie~ once by any of the event records. The oil Dressure seauence switch which is ranked at O was specifie~ a~ not bein~
suspect as the result of event 2 bein~ recognized, however, was suspected because of the recognition of the sYmptom/fault relationship labeled SF10. The fuel control valve solenoid was ranked at O because it was susPected with a rankin~ effect of +10 as a result of the sYmDtom-fault relationship, SF10, and it was absolved from SusPicion with a ranking effect of -10 as a result of the analvsis of Event 30 3. The combined rankin~ effect of +10 and a ~10 is zero.
The components ranked at +10 resulted from the reco~nition of the symptom/fault relationship, SF10, from the symptom/fault model. The component ranked ~20 was sDecified as being suspect as a result of the analysis of event 4 and 35 as a result of the recognition of event pattern 2 from the vary model.
, .
~2;~;22 TABLE 6: AMBIGUITY GROUP
AMBIGUITY GRO~ RANKING (ALL COMPONE~S ARE RANKED THE AGE AFFECT THE
+20 IGNITION-UNIT (IMPLICATED BY BOTH EVENT RECOGNITION AND THE
+10 FUEL-SUPPLY
WING~TANKrFUEL-VALVE
FUEL-PUMP
ACCELERATION~LIMITER
OILæUPPLY
OIL rp~
OIL~FILTER
TURBINE~ASSEMBLY
O OIL~-P-SEQ~SWITCH
FUEL-CONTROL~VALVE~SOLENOID
-10 START~SW
ASR
START RELAY
START MOTOR
OVERSPEED TEST SOLENOIDS
FHR
OIL~P-SEQ~SW
FUEL CONTROL VALVE
Each ComDonent in the ambi~uitv ~roup rankin~ is further associated with a pointer, which i~ not shown. This pointer is used to select the associated location of the component and a structural model of the APU. Th~ structural model i9 then analyzed and maintenance oDtions for the APU
are outDUt.
This example is intended to be illustrative and is not intended to show every feature of the invention.
. . .;
.. . . ~ , .
, . :
AIR~INTAKE~DOOR
FUSES
CENTRIFUGAL SWITCH
APU.START-RELAY
ASR
STARTER~MOTOR
STARTER~SWITCH
PHASE O
TEXT - "Starter rotates onlY while start switch is depressed"
AGE ~ 10 AG - ASR
FHR
WIRING
BATTERY/EXTERNAL~.POWE2 SF10 (selected) TEXT - "Starter cranks engine but combustion does not occur"
AGE - + 10 AG - FUEL-SUPPLY
WING-TANK~FUEL~VALVE
FUEL-PUMP
ACCELERATION~LIMITER
FUEL~CONTROL-VALVE~SOLENOID
IGNITION~UNIT
OIL~P`-SEQ-SWITCH
OIL-SUPPLY
OIL~-PUMP
OIL~FILTER
TURBINE~ASSEMBLY
- - , . . .
..
.:
TABLE 5: E~AILURE I~ EL
EP1 = ECI AND EC2 ANY EC3 ECI .i ER3 AND NOT ER 4 EC2 - PR(S/Fl O) 5 EC3 ~ PR (sPecial test Acceleration~limiter - 3) AOE . ACCE~RATION LIMI~R, ~lO
EP2 = ECl AND EC2 AND EC3 EC2 - PR(S/F10) EC3 ~ PR (sPecial test IGNITION~UNIT - 4) AGE
IGNITION-UNIT, +10 If we collect all of the ambi~uitY ~roup effects from each reco~nized and analvzed event record, from each reco~nized svmPtom/fault relationship and from each recognized event pattern from the ~ailure model and aDPlY
the ranking effects, the ambi~uitv ~rouD as shown in Table 6 results. The elements ranked at -10 were all specifie~ once by any of the event records. The oil Dressure seauence switch which is ranked at O was specifie~ a~ not bein~
suspect as the result of event 2 bein~ recognized, however, was suspected because of the recognition of the sYmptom/fault relationship labeled SF10. The fuel control valve solenoid was ranked at O because it was susPected with a rankin~ effect of +10 as a result of the sYmDtom-fault relationship, SF10, and it was absolved from SusPicion with a ranking effect of -10 as a result of the analvsis of Event 30 3. The combined rankin~ effect of +10 and a ~10 is zero.
The components ranked at +10 resulted from the reco~nition of the symptom/fault relationship, SF10, from the symptom/fault model. The component ranked ~20 was sDecified as being suspect as a result of the analysis of event 4 and 35 as a result of the recognition of event pattern 2 from the vary model.
, .
~2;~;22 TABLE 6: AMBIGUITY GROUP
AMBIGUITY GRO~ RANKING (ALL COMPONE~S ARE RANKED THE AGE AFFECT THE
+20 IGNITION-UNIT (IMPLICATED BY BOTH EVENT RECOGNITION AND THE
+10 FUEL-SUPPLY
WING~TANKrFUEL-VALVE
FUEL-PUMP
ACCELERATION~LIMITER
OILæUPPLY
OIL rp~
OIL~FILTER
TURBINE~ASSEMBLY
O OIL~-P-SEQ~SWITCH
FUEL-CONTROL~VALVE~SOLENOID
-10 START~SW
ASR
START RELAY
START MOTOR
OVERSPEED TEST SOLENOIDS
FHR
OIL~P-SEQ~SW
FUEL CONTROL VALVE
Each ComDonent in the ambi~uitv ~roup rankin~ is further associated with a pointer, which i~ not shown. This pointer is used to select the associated location of the component and a structural model of the APU. Th~ structural model i9 then analyzed and maintenance oDtions for the APU
are outDUt.
This example is intended to be illustrative and is not intended to show every feature of the invention.
. . .;
.. . . ~ , .
, . :
Claims (24)
1. A method for diagnosing faults in a system under test, comprising the steps of:
analyzing a first representation of said system under test to obtain a first list of suspect components and a ranking for each of said suspect component that indicates a level of suspicion;
pointing to a component in a structural model of said system under test according to said ranked list of suspect components;
analyzing said structural model starting at said component; and outputting a maintenance option to be performed on said system as a result of said analysis.
analyzing a first representation of said system under test to obtain a first list of suspect components and a ranking for each of said suspect component that indicates a level of suspicion;
pointing to a component in a structural model of said system under test according to said ranked list of suspect components;
analyzing said structural model starting at said component; and outputting a maintenance option to be performed on said system as a result of said analysis.
2. The method as claimed in claim 1, wherein said first representation is an event based representation that defines the temporal performance of said system under test.
3. The method as claimed in claim 1, wherein said first representation is a heuristic rule based model of said system under test.
4. The method as claimed in claim 1, further comprising the steps of:
before pointing to said structural model, analyzing a second representation of said system under test to obtain a second list of suspect components and a ranking for each of said suspect components on said second list which indicates a level of suspicion:
integrating said first list of suspect components and rankings with said second list of suspect components and rankings to obtain a integrated group of ranked suspect components.
before pointing to said structural model, analyzing a second representation of said system under test to obtain a second list of suspect components and a ranking for each of said suspect components on said second list which indicates a level of suspicion:
integrating said first list of suspect components and rankings with said second list of suspect components and rankings to obtain a integrated group of ranked suspect components.
5. The method as claimed in claim 4, wherein said first representation is an event based representation of said system under test and said second representation is a heuristic rule based model of said system under test.
6. The method as claimed in claim 1, further comprising the steps of:
group related components from said first list of suspect components prior to pointing to said component in said structural model.
group related components from said first list of suspect components prior to pointing to said component in said structural model.
7. The method as claimed in claim 6, wherein functionally related components are grouped together.
8. The method as claimed in claim 6, wherein structurally related components are grouped together.
9. The method as claimed in claim 1, further comprising the step of:
analyzing the result of performing said maintenance option and adjusting said list of suspect components accordingly to obtain a re-ranked list of suspect components;
pointing to a second component in said structural model according to said reranked list of suspect components; and analyzing said structural model starting at said second component and outputting a new maintenance option.
analyzing the result of performing said maintenance option and adjusting said list of suspect components accordingly to obtain a re-ranked list of suspect components;
pointing to a second component in said structural model according to said reranked list of suspect components; and analyzing said structural model starting at said second component and outputting a new maintenance option.
10. A method for diagnosing faults in a system under test, comprising the steps of:
analyzing a first representation of said system under test to obtain a first list of suspect components and a ranking for each suspected component that indicates a level of suspicion;
analyzing a second representation of said system under test to obtain a second list of suspected components and a ranking for each suspected components that indicates a level of suspicion;
obtaining an integrated list of suspect components and a ranking for each of said suspected components from said first list and second list;
grouping related components within said integrated list of suspect components;
pointing to a component in a structural model of said system under test according to one of the grouped lists of suspect components;
analyzing said structural model starting at said component; and outputting a maintenance option to be performed on said system under test as a result of said analysis.
analyzing a first representation of said system under test to obtain a first list of suspect components and a ranking for each suspected component that indicates a level of suspicion;
analyzing a second representation of said system under test to obtain a second list of suspected components and a ranking for each suspected components that indicates a level of suspicion;
obtaining an integrated list of suspect components and a ranking for each of said suspected components from said first list and second list;
grouping related components within said integrated list of suspect components;
pointing to a component in a structural model of said system under test according to one of the grouped lists of suspect components;
analyzing said structural model starting at said component; and outputting a maintenance option to be performed on said system under test as a result of said analysis.
11. The method as claimed in claim 10, further comprising the step of:
analyzing the result of performing said maintenance option and adjusting said list of suspect components accordingly to obtain a re-ranked list of suspect component;
pointing to a second component in said structural model according to said reranked list of components: and analyzing said structural model starting at said second component and outputting a new maintenance option to be performed on said system.
analyzing the result of performing said maintenance option and adjusting said list of suspect components accordingly to obtain a re-ranked list of suspect component;
pointing to a second component in said structural model according to said reranked list of components: and analyzing said structural model starting at said second component and outputting a new maintenance option to be performed on said system.
12. A method for diagnosing faults in a system under test, comprising the steps of:
comparing a plurality of data samples collected from said system under test during its operation to data in an event based representation to recognize events which occurred in said operation;
ranking a list of components in said system according to the recognized events;
pointing to component in a structural model of said system according to said ranked list of components;
analyzing said structural model starting at said component; and outputting a maintenance option to be performed on said system as a result of analyzing said component model.
comparing a plurality of data samples collected from said system under test during its operation to data in an event based representation to recognize events which occurred in said operation;
ranking a list of components in said system according to the recognized events;
pointing to component in a structural model of said system according to said ranked list of components;
analyzing said structural model starting at said component; and outputting a maintenance option to be performed on said system as a result of analyzing said component model.
13. The method as claimed in claim 1, wherein said event based representation defines the temporal performance of said system under test.
14. The method as claimed in claim 13, wherein said event based representation of said system includes a plurality of defined events, each of which includes at least one critical parameter and wherein one of said defined events is recognized when said collected data samples match a critical parameter from said one of said plurality of defined events.
15. The method as claimed in claim 1, further comprising the steps of:
analyzing the result of performing said maintenance option and adjusting said ranking of said list of components;
pointing to a new entry point in said event structured component model according to said reranked list of components; and analyzing said event structured component model at said new entry point and outputting a new maintenance option to be performed on said system.
analyzing the result of performing said maintenance option and adjusting said ranking of said list of components;
pointing to a new entry point in said event structured component model according to said reranked list of components; and analyzing said event structured component model at said new entry point and outputting a new maintenance option to be performed on said system.
16. The method as claimed in claim 1, further comprising the step of:
grouping related components which are pointed to in said structural model prior to outputting said maintenance options.
grouping related components which are pointed to in said structural model prior to outputting said maintenance options.
17. The method as claimed in claim 16, wherein functionally related components are grouped together.
18. The method as claimed in claim 16, wherein structurally related components are grouped together.
19. The method as claimed in claim 12, further comprising the steps of:
prior to pointing to a component in said structural component model, comparing data observed from said system during its operation to a symptom-fault model of said system to find a subset of applicable symptom-fault relationships from said model; and adjusting said ranking of said list of components accordingly.
prior to pointing to a component in said structural component model, comparing data observed from said system during its operation to a symptom-fault model of said system to find a subset of applicable symptom-fault relationships from said model; and adjusting said ranking of said list of components accordingly.
20. The method as claimed in claim 12, further comprising the steps of:
prior to pointing to a component in said structural model, from said recognized events and from said collected data samples to a failure model; and adjusting said ranking of said list of components accordingly.
prior to pointing to a component in said structural model, from said recognized events and from said collected data samples to a failure model; and adjusting said ranking of said list of components accordingly.
21. The method as claimed in claim 19, further comprising the steps of:
prior to pointing to a component in structural model, from said recognized events and from said collected data samples to a failure model: and adjusting said ranking of said list of components accordingly.
prior to pointing to a component in structural model, from said recognized events and from said collected data samples to a failure model: and adjusting said ranking of said list of components accordingly.
22. A fault diagnostic tool for a system under test, comprising:
data acquisition means for collecting data from said system under test during its operation to obtain operational data;
an event record data base for providing data representative of a plurality of predefined events that occur during operation of said system under test;
first comparison means for comparing said operational data to said event record data base to recognize any of said predefined events that occurred during operation of said system under test:
memory means for storing a listing of a plurality of components from said system under test in order according to their probability of failure, wherein said components and said order are specified by said predefined events recognized by said comparison means;
a structural data base for providing data representative of said system under test's structure: and analysis means for analyzing said structural data base according to said listing and for outputting suggested operations to be performed on said system under test.
data acquisition means for collecting data from said system under test during its operation to obtain operational data;
an event record data base for providing data representative of a plurality of predefined events that occur during operation of said system under test;
first comparison means for comparing said operational data to said event record data base to recognize any of said predefined events that occurred during operation of said system under test:
memory means for storing a listing of a plurality of components from said system under test in order according to their probability of failure, wherein said components and said order are specified by said predefined events recognized by said comparison means;
a structural data base for providing data representative of said system under test's structure: and analysis means for analyzing said structural data base according to said listing and for outputting suggested operations to be performed on said system under test.
23. A fault diagnostic tool as claimed in claim 22, further comprising:
a first heuristic data base for providing data representative of a plurality of symptom-fault relationships for said system under test; and second comparison means for comparing data observed from said system under test to said first heuristic data base to recognize a subset of said plurality of symptom-fault relationship and to control said listing in said memory means according to components and ranking effects associated with said recognized subset of symptom-fault relationships.
a first heuristic data base for providing data representative of a plurality of symptom-fault relationships for said system under test; and second comparison means for comparing data observed from said system under test to said first heuristic data base to recognize a subset of said plurality of symptom-fault relationship and to control said listing in said memory means according to components and ranking effects associated with said recognized subset of symptom-fault relationships.
24. A fault diagnostic tool as claimed in claim 23, further comprising:
a second heuristic data base for providing data representative of a plurality of failure modes for said symptom under test; and third comparison means for comparing said second heuristic data base to said operational data, to said predefined events recognized by said first comparison means and to said subset of symptom-fault relationships recognized by said second comparison means and to control said listing in said memory means according to components and ranks associated with any recognized failure modes.
a second heuristic data base for providing data representative of a plurality of failure modes for said symptom under test; and third comparison means for comparing said second heuristic data base to said operational data, to said predefined events recognized by said first comparison means and to said subset of symptom-fault relationships recognized by said second comparison means and to control said listing in said memory means according to components and ranks associated with any recognized failure modes.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US07/266,722 US5099436A (en) | 1988-11-03 | 1988-11-03 | Methods and apparatus for performing system fault diagnosis |
| US266,722 | 1994-06-24 |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA2002222A1 true CA2002222A1 (en) | 1990-05-03 |
Family
ID=23015740
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA002002222A Abandoned CA2002222A1 (en) | 1988-11-03 | 1989-11-03 | Methods and apparatus for performing system fault diagnosis |
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| Country | Link |
|---|---|
| US (1) | US5099436A (en) |
| CA (1) | CA2002222A1 (en) |
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