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Published byEugene Hawkins Modified over 9 years ago
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Working Group 4 Creative Systems for Knowledge Management in Life Sciences
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Purpose of this Talk We are researching methods which we believe could provide non-standard solutions to complex problems We need concrete problems to identify possible interactions between the working groups
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Structure of Talk Individual research directions General techniques for creative reasoning A case study
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Computational Bioinformatics Laboratory, Imperial College London Progol system –Learning of concepts in bioinformatics –Theory behind, and implementation of ILP –Applications: Predictive toxicology, secondary structure in proteins, learning metabolic pathways HR system –Discovering in mathematics (and bioinformatics) –Theory behind, and implementation of ATF –Applications: Adding to databases: Integer sequences, TPTP library Finding invariants, inventing CSP constraints, tutorials Scientific Discovery via integration of techniques
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Centre for Computational Creativity City University, London Formal frameworks for describing and reasoning about creative behaviour –Compare seach methods and outcomes –Define value etc and reason about properties of definitions Pattern discovery and matching technogies for multidimensional datasets –Discover/locate geometrically identical structural regions, possibly with gaps in multi-D data –Example: 3D representations of atoms in space for pharmacophore bonding models
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University of A Corunha Hybrid Society (HS) Development framework to validate and to allow the learning of various computational models of tasks which require creativity and a social behaviour HS is based on machines and humans living together in a virtual and “egalitarian” society Solves the problem of Value in a dynamic context. Allows the comparison of different computer paradigms and systems. Allow the collaboration between humans and computer systems Allows the use of adaptive techniques such us Evolutionary Computation and Artificial Neural Networks
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Creative Systems Group University of Coimbra Computational Models of Creativity –Analogy –Evolution –Conceptual Blending Models of Surprise Hybrid Societies for Creativity Assessment
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University of Edinburgh Lakatos-style reasoning: -Experts interact to build a common theory -Counterexamples used to modify conjectures; clarify concepts; improve proofs - Ways of evaluating machine creativity
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Universidad Complutense de Madrid Ongoing research work: –Knowledge intensive CBR CBRArm: framework for CBR + ontologies –Generating narrative and metaphorical texts, NLG architectures, CBR for text generation –CBR for Knowledge Management Java documentation, helpdesks –Information Filtering + User Modeling –Computer games
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Creative Reasoning Reasoning in non-standard ways to produce: –“interesting”/valued/unexpected outputs –emergent complex behaviour Reconceptualise existing knowledge structures to get new knowledge structures with added value –using in a different way than they were intended –lateral connections that weren’t there already Heuristic reasoning –Including sound and unsound methods Post hoc verification –value measurements for the domain are a pre-requisite
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General Techniques Conceptual blending Metaphorical/analogical reasoning Inductive inference Hypothesis repair Evolutionary methods
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Conceptual Blending
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Metaphorical Reasoning
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Inductive Inference Predictive Induction –Know the positives/negatives of a concept –Search for a concept which fits categorisation Use examples as evidence for predictive accuracy Cross validate results Descriptive Induction –Search for rules which associate background predicates, using data as empirical evidence –(Sometimes) use deduction to prove rules found
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Hypothesis Repair Using a counterexample to repair a faulty hypothesis by: –Generalising from counterexample to a property then stating the exception in the hypothesis –Generalising from the positives and then limiting the hypothesis to these
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Evolutionary Methods Exploration of complex search spaces –in non-uniform ways –Based on biologically inspired evolutionary notions such as gene recombination, mutation, fitness functions –Dynamically adaptive systems
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Potential Applications Levels of discovery –You know what you are looking for, But you don’t know what it looks like –You don’t know what you are looking for But you know you are looking for something –You didn’t know you were even looking for anything Levels of search –At the object level (millions/billions of data points) –At the semantics level (tens of thousands of terms) –At the meta-level (scores of techniques)
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Possible (General) Application: Ontology Maintenance Ontologies standardise concepts –And standardise relationships between them Many areas see the need for ontologies –Including scientific domains such as life sciences Very important that the ontology represents current scientific thinking Need to continually maintain ontology –New nodes –New links Need to continually interpret ontology –Large scale structures
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Case Study – Gene Ontology ~14,000 terms from biology/genetics –Process, function, structure –Structured into hierarchies using isa/partof Each term has genes associated –~ 1.3 million genes (from, e.g., GenBank) Aims to unify biology –Databases are in a bad state Different interpretations/notations/standards
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Gene Ontology (Example)
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Methods for Ontology Maintenance Mining rules between concepts using inductive techniques (adds edges) –Project to use HR for this in progress –Project to use Progol to learn terminology Conceptual blending –Invent new concepts (nodes) Metaphorical reasoning –Look at structure to reorganise links Hypothesis repair –Explain genes which are seemingly misclassified
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Proactive and Reactive Applications Proactive –Attempt to make discoveries in GO –Give value added when someone submits a new term to the ontology Reactive –A new gene is added which (using sequence alignments) is associated with “wrong” concept –Creatively re-organise ontology to fix problem
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The Bottom Line We have solutions but not problems –With respect to Life Sciences Our application domains are disparate –But our methods are general We’re already thinking about certain tasks/problems in life sciences –Predictive toxicology –Protein structure prediction And we’re inventing our own problems –Maintaining the Gene Ontology But we really need to discuss what it is that standard techniques do not yet give you –And see what creative systems/techniques can do
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