Jeff Clune
Clune, Jeff, ?-....
VIAF ID: 310629078 (Personal)
Permalink: http://viaf.org/viaf/310629078
Preferred Forms
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100 1 _ ‡a Clune, Jeff
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100 1 _ ‡a Clune, Jeff, ‡d ?-....
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100 0 _ ‡a Jeff Clune
4xx's: Alternate Name Forms (1)
Works
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Curiosity-driven AI for Science: Automated Discovery of Self-Organized Structures |
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Curiosity Search: Producing Generalists by Encouraging Individuals to Continually Explore and Acquire Skills throughout Their Lifetime |
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Designing neural networks through neuroevolution |
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Diffusion-based neuromodulation can eliminate catastrophic forgetting in simple neural networks. |
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Digital evolution with avida |
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The Emergence of Canalization and Evolvability in an Open-Ended, Interactive Evolutionary System |
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The Evolution of Division of Labor |
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The evolutionary origins of modularity |
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Evolving coordinated quadruped gaits with the HyperNEAT generative encoding |
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Evolving neural networks that are both modular and regular |
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First return, then explore |
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How a Generative Encoding Fares as Problem-Regularity Decreases |
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How evolution learns to generalise: Using the principles of learning theory to understand the evolution of developmental organisation. |
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How should intelligence be abstracted in AI research, 2013: |
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How transferable are features in deep neural networks? |
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IA curieuse au service de la science : découverte automatisée de structures auto-organisées. |
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Improving Exploration in Evolution Strategies for Deep Reinforcement Learning via a Population of Novelty-Seeking Agents |
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Improving HybrID: How to best combine indirect and direct encoding in evolutionary algorithms |
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Improving the accessibility and transferability of machine learning algorithms for identification of animals in camera trap images: MLWIC2 |
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Investigating whether hyperNEAT produces modular neural networks |
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Natural selection fails to optimize mutation rates for long-term adaptation on rugged fitness landscapes |
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Neural modularity helps organisms evolve to learn new skills without forgetting old skills |
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On the Performance of Indirect Encoding Across the Continuum of Regularity |
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Ontogeny tends to recapitulate phylogeny in digital organisms |
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Problem decomposition using indirect reciprocity in evolved populations |
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Reports on the 2013 AAAI Fall Symposium Series |
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Robots that can adapt like animals. |
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Selective pressures for accurate altruism targeting: evidence from digital evolution for difficult-to-test aspects of inclusive fitness theory |
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The sensitivity of HyperNEAT to different geometric representations of a problem |
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The Surprising Creativity of Digital Evolution: A Collection of Anecdotes from the Evolutionary Computation and Artificial Life Research Communities |
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Synthesizing the preferred inputs for neurons in neural networks via deep generator networks |
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Understanding Neural Networks via Feature Visualization: A Survey |
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WebAL Comes of Age: A Review of the First 21 Years of Artificial Life on the Web. |
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