924 research outputs found
Variations in language use:The influence of linguistic and social factors
One of the significant characteristics of language is flexibility. On the one hand, people have various ways to convey certain information to a given addressee. For example, when quoting previous utterances, people can use direct quotations (direct speech) or indirect quotations (indirect speech), depending on which perspective they are taking. On the other hand, people talk about the same things in different ways depending on with whom they are communicating with. For instance, people talk more politely when communicating with individuals who are more powerful compared to individuals who are peers or less powerful. In this dissertation, I focused on factors that contribute to decisions between different ways of communication. To investigate this question, I took the use of direct and indirect speech as a cut-in point. I first examined how linguistic and social factors influenced the use of direct and indirect speech in a narrative task. I further explored the influence of social factors on language production in other contexts (e.g., offline vs. online communication). Taken together, findings from this dissertation suggest that both intrinsic characteristics of the utterance itself and extrinsic characteristics, such as psychological distance between speaker and listener and the listener’s knowledge level, play a role in language production processes
Low-Multi-Rank High-Order Bayesian Robust Tensor Factorization
The recently proposed tensor robust principal component analysis (TRPCA)
methods based on tensor singular value decomposition (t-SVD) have achieved
numerous successes in many fields. However, most of these methods are only
applicable to third-order tensors, whereas the data obtained in practice are
often of higher order, such as fourth-order color videos, fourth-order
hyperspectral videos, and fifth-order light-field images. Additionally, in the
t-SVD framework, the multi-rank of a tensor can describe more fine-grained
low-rank structure in the tensor compared with the tubal rank. However,
determining the multi-rank of a tensor is a much more difficult problem than
determining the tubal rank. Moreover, most of the existing TRPCA methods do not
explicitly model the noises except the sparse noise, which may compromise the
accuracy of estimating the low-rank tensor. In this work, we propose a novel
high-order TRPCA method, named as Low-Multi-rank High-order Bayesian Robust
Tensor Factorization (LMH-BRTF), within the Bayesian framework. Specifically,
we decompose the observed corrupted tensor into three parts, i.e., the low-rank
component, the sparse component, and the noise component. By constructing a
low-rank model for the low-rank component based on the order- t-SVD and
introducing a proper prior for the model, LMH-BRTF can automatically determine
the tensor multi-rank. Meanwhile, benefiting from the explicit modeling of both
the sparse and noise components, the proposed method can leverage information
from the noises more effectivly, leading to an improved performance of TRPCA.
Then, an efficient variational inference algorithm is established for
parameters estimation. Empirical studies on synthetic and real-world datasets
demonstrate the effectiveness of the proposed method in terms of both
qualitative and quantitative results
Predator-prey survival pressure is sufficient to evolve swarming behaviors
The comprehension of how local interactions arise in global collective
behavior is of utmost importance in both biological and physical research.
Traditional agent-based models often rely on static rules that fail to capture
the dynamic strategies of the biological world. Reinforcement learning has been
proposed as a solution, but most previous methods adopt handcrafted reward
functions that implicitly or explicitly encourage the emergence of swarming
behaviors. In this study, we propose a minimal predator-prey coevolution
framework based on mixed cooperative-competitive multiagent reinforcement
learning, and adopt a reward function that is solely based on the fundamental
survival pressure, that is, prey receive a reward of if caught by
predators while predators receive a reward of . Surprisingly, our analysis
of this approach reveals an unexpectedly rich diversity of emergent behaviors
for both prey and predators, including flocking and swirling behaviors for
prey, as well as dispersion tactics, confusion, and marginal predation
phenomena for predators. Overall, our study provides novel insights into the
collective behavior of organisms and highlights the potential applications in
swarm robotics
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