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Ph.D de

Ph.D
Group : Learning and Optimization

Recurrent Neural Networks and Reinforcement Learning

Starts on 01/10/2016
Advisor : OLLIVIER, Yann

Funding : Contrat doctoral spécifique normalien ou polytechnicien
Affiliation : Université Paris-Saclay
Laboratory : LRI - AO

Defended on 07/10/2019, committee :
Directeur de thèse :
- OLLIVIER Yann, CNRS

Rapporteurs :
- M. Joan BRUNA, Université de New York
- M. Pascal VINCENT, Université de Montréal

Examinateurs :
- Mme Anne VILNAT, Université Paris-Sud
- M. Francis BACH, École Normale Supérieure
- M. Jean-Philippe VERT, Mines ParisTech

Research activities :

Abstract :
An intelligent agent immerged in its environment must be able to both
understand and interact with the world. Understanding the environment requires
processing sequences of sensorial inputs. Interacting with the environment
typically involves issuing actions, and adapting those actions to strive
towards a given goal, or to maximize a notion of reward. This view of a two
parts agent-environment interaction motivates the two parts of this thesis: recurrent
neural networks are powerful tools to make sense of complex and diverse
sequences of inputs, such as those resulting from an agent-environment
interaction; reinforcement learning is the field of choice to direct the
behavior of an agent towards a goal. This thesis aim is to provide theoretical
and practical insights in those two domains. In the field of recurrent
networks, this thesis contribution is twofold: we introduce two new,
theoretically grounded and scalable learning algorithms that can be used online.
Besides, we advance understanding of gated recurrent networks, by examining their
invariance properties. In the field of reinforcement learning, our main
contribution is to provide guidelines to design time discretization robust
algorithms. All these contributions are theoretically grounded, and backed up
by experimental results.

Ph.D. dissertations & Faculty habilitations
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MICRO VISUALIZATIONS: DESIGN AND ANALYSIS OF VISUALIZATIONS FOR SMALL DISPLAY SPACES
The topic of this habilitation is the study of very small data visualizations, micro visualizations, in display contexts that can only dedicate minimal rendering space for data representations. For several years, together with my collaborators, I have been studying human perception, interaction, and analysis with micro visualizations in multiple contexts. In this document I bring together three of my research streams related to micro visualizations: data glyphs, where my joint research focused on studying the perception of small-multiple micro visualizations, word-scale visualizations, where my joint research focused on small visualizations embedded in text-documents, and small mobile data visualizations for smartwatches or fitness trackers. I consider these types of small visualizations together under the umbrella term ``micro visualizations.'' Micro visualizations are useful in multiple visualization contexts and I have been working towards a better understanding of the complexities involved in designing and using micro visualizations. Here, I define the term micro visualization, summarize my own and other past research and design guidelines and outline several design spaces for different types of micro visualizations based on some of the work I was involved in since my PhD.