%0 Conference Paper %1 jimenez-roa2021fault %A Jimenez-Roa, Lisandro A. %A Heskes, Tom %A Stoelinga, Marielle %B Proceedings of the 31st European Safety and Reliability Conference (ESREL 2021) %D 2021 %I Research Publishing Services %K 62c25-compound-decision-problems-in-statistical-decision-theory 68u35-information-systems 90b25-reliability-availability-maintenance-inspection 90c40-markov-and-semi-markov-decision-processes 91b06-decision-theory fault-tree-analysis %R 10.3850/978-981-18-2016-8_241-cd %T Fault Trees, Decision Trees, And Binary Decision Diagrams: A Systematic Comparison %U https://rpsonline.com.sg/proceedings/9789811820168/html/241.xml %X In reliability engineering, we need to understand system dependencies, cause-effect relations, identify critical components, and analyze how they trigger failures. Three prominent graph models commonly used for these purposes are fault trees (FTs), decision trees (DTs), and binary decision diagrams (BDDs). These models are popular because they are easy to interpret, serve as a communication tool between stakeholders of various backgrounds, and support decision-making processes. Moreover, these models help to understand real-world problems by computing reliability metrics, minimum cut sets, logic rules, and displaying dependencies. Nevertheless, it is unclear how these graph models compare. Thus, the goal of this paper is to understand the similarities and differences through a systematic comparison based on their (i) purpose and application, (ii) structural representation, (iii) analysis methods, (iv) construction, and (v) benefits & limitations. Furthermore, we use a running example based on a Container Seal Design to showcase the models in practice. Our results show that, given that FTs, DTs and BDDs have different purposes and application domains, they adopt different structural representations and analysis methodologies that entail a variety of benefits and limitations, the latter can be addressed via conversion methods or extensions. Specific remarks are that BDDs can be considered as a compact representation of binary DTs, since the former allow sub-node sharing, which makes BDDs more efficient at representing logical rules than binary DTs. It is possible to obtain cut sets from BDDs and DTs and construct a FT using the (con/dis)junctive normal form, although this may result in a sub-optimal FT structure.

@inproceedings{jimenez-roa2021fault, abstract = {In reliability engineering, we need to understand system dependencies, cause-effect relations, identify critical components, and analyze how they trigger failures. Three prominent graph models commonly used for these purposes are fault trees (FTs), decision trees (DTs), and binary decision diagrams (BDDs). These models are popular because they are easy to interpret, serve as a communication tool between stakeholders of various backgrounds, and support decision-making processes. Moreover, these models help to understand real-world problems by computing reliability metrics, minimum cut sets, logic rules, and displaying dependencies. Nevertheless, it is unclear how these graph models compare. Thus, the goal of this paper is to understand the similarities and differences through a systematic comparison based on their (i) purpose and application, (ii) structural representation, (iii) analysis methods, (iv) construction, and (v) benefits & limitations. Furthermore, we use a running example based on a Container Seal Design to showcase the models in practice. Our results show that, given that FTs, DTs and BDDs have different purposes and application domains, they adopt different structural representations and analysis methodologies that entail a variety of benefits and limitations, the latter can be addressed via conversion methods or extensions. Specific remarks are that BDDs can be considered as a compact representation of binary DTs, since the former allow sub-node sharing, which makes BDDs more efficient at representing logical rules than binary DTs. It is possible to obtain cut sets from BDDs and DTs and construct a FT using the (con/dis)junctive normal form, although this may result in a sub-optimal FT structure.}, added-at = {2024-07-05T05:34:20.000+0200}, author = {Jimenez-Roa, Lisandro A. and Heskes, Tom and Stoelinga, Marielle}, biburl = {https://www.bibsonomy.org/bibtex/23cb940df10ff4395fcb231ce1c4318eb/gdmcbain}, booktitle = {Proceedings of the 31st European Safety and Reliability Conference (ESREL 2021)}, collection = {ESREL}, doi = {10.3850/978-981-18-2016-8_241-cd}, eventdate = {19-23 Sep. 2021}, eventtitle = {31st European Safety and Reliability Conference}, interhash = {5741766e0fb24ea0bb0b2d9382dbbb97}, intrahash = {3cb940df10ff4395fcb231ce1c4318eb}, keywords = {62c25-compound-decision-problems-in-statistical-decision-theory 68u35-information-systems 90b25-reliability-availability-maintenance-inspection 90c40-markov-and-semi-markov-decision-processes 91b06-decision-theory fault-tree-analysis}, publisher = {Research Publishing Services}, series = {ESREL}, timestamp = {2024-07-05T05:49:45.000+0200}, title = {Fault Trees, Decision Trees, And Binary Decision Diagrams: A Systematic Comparison}, url = {https://rpsonline.com.sg/proceedings/9789811820168/html/241.xml}, venue = {Angers}, year = 2021 }