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8 - A joint learning approach for situated language generation

from Part III - Handling uncertainty

Published online by Cambridge University Press:  05 July 2014

Nina Dethlefs
Affiliation:
Heriot-Watt University
Heriberto Cuayáhuitl
Affiliation:
Heriot-Watt University
Amanda Stent
Affiliation:
AT&T Research, Florham Park, New Jersey
Srinivas Bangalore
Affiliation:
AT&T Research, Florham Park, New Jersey
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Summary

Introduction

Interactive systems are increasingly situated: they have knowledge about the non-linguistic context of the interaction, including aspects related to location, time, and the user (Byron and Fosler-Lussier, 2006; Kelleher et al., 2006; Stoia et al., 2006; Raux and Nakano, 2010; Garoufi and Koller, 2011; Janarthanam et al., 2012). This extra knowledge makes it possible for the Natural Language Generation (NLG) components of these systems to be more adaptive, changing their output to suit the larger context. Adaptive NLG systems for situated interaction aim to produce the most effective utterance for each user in each physical and discourse context. At each stage of the generation process (what to say or content selection, how to structure content or utterance planning, and how to express content or surface realization), the best choices depend on the physical and linguistic context, which is constantly changing. Consequently, it is key to successful interaction that adaptive NLG systems constantly monitor the physical environment, the dialogue history, and the user's preferences and behaviors. As the representations of each of these will necessarily be incomplete and error-prone, adaptive NLG systems must also be able to model uncertainty in the generation process.

A designer of adaptive NLG systems faces at least two challenges. The first challenge is to identify the set of contextual features that are relevant to decision making in a specific generation situation. The second challenge is to develop a method for selecting a (near-)optimal choice in any given situation from a set of competing ones that may initially appear as viable alternatives. Complicating these challenges is the fact that individual generation decisions are tightly interrelated, so the best decision at one stage may easily depend on others.

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Publisher: Cambridge University Press
Print publication year: 2014

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