Knowledge Graphs (KGs) represent the convergence of data and knowledge as factual statements; they allow for the enrichment of decision-making semantically. Symbolic inductive learning enables uncovering relevant patterns, expressed, for example, as Horn clauses. Albeit powerful, existing symbolic inductive learning frameworks may mine many rules, being difficult for a user to extract actionable insights. This demo illustrates a pipeline to analyze mined logical rules toward discovering meaningful insights. The demo puts into perspective the role of semantic types in guiding the exploration of mined rules. Participants will observe strategies to traverse the mined logical statements and how the outcomes reveal patterns in the prescription of lung cancer treatments. A video is available online (https://www.youtube.com/watch?v=CN4a3kUjfJ4 &ab\_channel=TIBSDMGroup), a Jupyter notebook executes a live demos (https://mybinder.org/v2/gh/SDM-TIB/DIGGER-ESWC2023Demo/HEAD?labpath=Mining\%20Symbolic\%20Rules\%20To\%20Explain\%20Lung\%20Cancer\%20Treatments.ipynb), and source-code is available in GitHub (https://github.com/SDM-TIB/Mining\_Symbolic\_Rules\_ESWC2023Demo).
%0 Conference Paper
%1 10.1007/978-3-031-43458-7_13
%A Purohit, Disha
%A Vidal, Maria-Esther
%B The Semantic Web: ESWC 2023 Satellite Events
%C Cham
%D 2023
%E Pesquita, Catia
%E Skaf-Molli, Hala
%E Efthymiou, Vasilis
%E Kirrane, Sabrina
%E Ngonga, Axel
%E Collarana, Diego
%E Cerqueira, Renato
%E Alam, Mehwish
%E Trojahn, Cassia
%E Hertling, Sven
%I Springer Nature Switzerland
%K myown from:gabydler
%P 69--74
%R https://doi.org/10.1007/978-3-031-43458-7_13
%T Mining Symbolic Rules to Explain Lung Cancer Treatments
%X Knowledge Graphs (KGs) represent the convergence of data and knowledge as factual statements; they allow for the enrichment of decision-making semantically. Symbolic inductive learning enables uncovering relevant patterns, expressed, for example, as Horn clauses. Albeit powerful, existing symbolic inductive learning frameworks may mine many rules, being difficult for a user to extract actionable insights. This demo illustrates a pipeline to analyze mined logical rules toward discovering meaningful insights. The demo puts into perspective the role of semantic types in guiding the exploration of mined rules. Participants will observe strategies to traverse the mined logical statements and how the outcomes reveal patterns in the prescription of lung cancer treatments. A video is available online (https://www.youtube.com/watch?v=CN4a3kUjfJ4 &ab\_channel=TIBSDMGroup), a Jupyter notebook executes a live demos (https://mybinder.org/v2/gh/SDM-TIB/DIGGER-ESWC2023Demo/HEAD?labpath=Mining\%20Symbolic\%20Rules\%20To\%20Explain\%20Lung\%20Cancer\%20Treatments.ipynb), and source-code is available in GitHub (https://github.com/SDM-TIB/Mining\_Symbolic\_Rules\_ESWC2023Demo).
%@ 978-3-031-43458-7
@inproceedings{10.1007/978-3-031-43458-7_13,
abstract = {Knowledge Graphs (KGs) represent the convergence of data and knowledge as factual statements; they allow for the enrichment of decision-making semantically. Symbolic inductive learning enables uncovering relevant patterns, expressed, for example, as Horn clauses. Albeit powerful, existing symbolic inductive learning frameworks may mine many rules, being difficult for a user to extract actionable insights. This demo illustrates a pipeline to analyze mined logical rules toward discovering meaningful insights. The demo puts into perspective the role of semantic types in guiding the exploration of mined rules. Participants will observe strategies to traverse the mined logical statements and how the outcomes reveal patterns in the prescription of lung cancer treatments. A video is available online (https://www.youtube.com/watch?v=CN4a3kUjfJ4 {\&}ab{\_}channel=TIBSDMGroup), a Jupyter notebook executes a live demos (https://mybinder.org/v2/gh/SDM-TIB/DIGGER-ESWC2023Demo/HEAD?labpath=Mining{\%}20Symbolic{\%}20Rules{\%}20To{\%}20Explain{\%}20Lung{\%}20Cancer{\%}20Treatments.ipynb), and source-code is available in GitHub (https://github.com/SDM-TIB/Mining{\_}Symbolic{\_}Rules{\_}ESWC2023Demo).},
added-at = {2024-02-15T15:10:02.000+0100},
address = {Cham},
author = {Purohit, Disha and Vidal, Maria-Esther},
biburl = {https://www.bibsonomy.org/bibtex/23542c3b257dcd8ca20ec5056d15f85d9/l3s},
booktitle = {The Semantic Web: ESWC 2023 Satellite Events},
doi = {https://doi.org/10.1007/978-3-031-43458-7_13},
editor = {Pesquita, Catia and Skaf-Molli, Hala and Efthymiou, Vasilis and Kirrane, Sabrina and Ngonga, Axel and Collarana, Diego and Cerqueira, Renato and Alam, Mehwish and Trojahn, Cassia and Hertling, Sven},
interhash = {7980197949c8bb604083b3a1fafd7cce},
intrahash = {3542c3b257dcd8ca20ec5056d15f85d9},
isbn = {978-3-031-43458-7},
keywords = {myown from:gabydler},
pages = {69--74},
publisher = {Springer Nature Switzerland},
timestamp = {2024-02-15T15:10:02.000+0100},
title = {Mining Symbolic Rules to Explain Lung Cancer Treatments},
year = 2023
}