TY - GEN
T1 - EL Embeddings: Geometric construction of models for the description logic EL++
AU - Kulmanov, Maxat
AU - Liu-Wei, Wang
AU - Yan, Yuan
AU - Hoehndorf, Robert
N1 - KAUST Repository Item: Exported on 2020-10-01
PY - 2019/7/28
Y1 - 2019/7/28
N2 - An embedding is a function that maps entities from one algebraic structure into another while preserving certain characteristics. Embeddings are being used successfully for mapping relational data or text into vector spaces where they can be used for machine learning, similarity search, or similar tasks. We address the problem of finding vector space embeddings for theories in the Description Logic $\mathcal{EL}^{++}$ that are also models of the TBox. To find such embeddings, we define an optimization problem that characterizes the model-theoretic semantics of the operators in $\mathcal{EL}^{++}$ within $\Re^n$, thereby solving the problem of finding an interpretation function for an $\mathcal{EL}^{++}$ theory given a particular domain $\Delta$. Our approach is mainly relevant to large $\mathcal{EL}^{++}$ theories and knowledge bases such as the ontologies and knowledge graphs used in the life sciences. We demonstrate that our method can be used for improved prediction of protein--protein interactions when compared to semantic similarity measures or knowledge graph embeddings.
AB - An embedding is a function that maps entities from one algebraic structure into another while preserving certain characteristics. Embeddings are being used successfully for mapping relational data or text into vector spaces where they can be used for machine learning, similarity search, or similar tasks. We address the problem of finding vector space embeddings for theories in the Description Logic $\mathcal{EL}^{++}$ that are also models of the TBox. To find such embeddings, we define an optimization problem that characterizes the model-theoretic semantics of the operators in $\mathcal{EL}^{++}$ within $\Re^n$, thereby solving the problem of finding an interpretation function for an $\mathcal{EL}^{++}$ theory given a particular domain $\Delta$. Our approach is mainly relevant to large $\mathcal{EL}^{++}$ theories and knowledge bases such as the ontologies and knowledge graphs used in the life sciences. We demonstrate that our method can be used for improved prediction of protein--protein interactions when compared to semantic similarity measures or knowledge graph embeddings.
UR - http://hdl.handle.net/10754/659960
UR - https://www.ijcai.org/proceedings/2019/845
UR - http://www.scopus.com/inward/record.url?scp=85074950139&partnerID=8YFLogxK
U2 - 10.24963/ijcai.2019/845
DO - 10.24963/ijcai.2019/845
M3 - Conference contribution
SN - 9780999241141
SP - 6103
EP - 6109
BT - Proceedings of the Twenty-Eighth International Joint Conference on Artificial Intelligence
PB - International Joint Conferences on Artificial Intelligence Organization
ER -