Your search keyword '"Complexification"' showing total 3 results

1. Quantum-Inspired Complex-Valued Language Models for Aspect-Based Sentiment Classification.

Author

Zhao, Qin, Hou, Chenguang, and Xu, Ruifeng

Subjects

*SENTIMENT analysis, *HILBERT space, *VECTOR spaces, *TASK analysis, *CLASSIFICATION, *LANGUAGE & languages, *QUANTUM theory

Abstract

Aiming at classifying the polarities over aspects, aspect-based sentiment analysis (ABSA) is a fine-grained task of sentiment analysis. The vector representations of current models are generally constrained to real values. Based on mathematical formulations of quantum theory, quantum language models have drawn increasing attention. Words in such models can be projected as physical particles in quantum systems, and naturally represented by representation-rich complex-valued vectors in a Hilbert Space, rather than real-valued ones. In this paper, the Hilbert Space representation for ABSA models is investigated and the complexification of three strong real-valued baselines are constructed. Experimental results demonstrate the effectiveness of complexification and the outperformance of our complex-valued models, illustrating that the complex-valued embedding can carry additional information beyond the real embedding. Especially, a complex-valued RoBERTa model outperforms or approaches the previous state-of-the-art on three standard benchmarking datasets. [ABSTRACT FROM AUTHOR]

Published

2022

2. Quantum-Inspired Complex-Valued Language Models for Aspect-Based Sentiment Classification

Author

Qin Zhao, Chenguang Hou, and Ruifeng Xu

Subjects

quantum language model, complexification, aspect-based sentiment analysis, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Aiming at classifying the polarities over aspects, aspect-based sentiment analysis (ABSA) is a fine-grained task of sentiment analysis. The vector representations of current models are generally constrained to real values. Based on mathematical formulations of quantum theory, quantum language models have drawn increasing attention. Words in such models can be projected as physical particles in quantum systems, and naturally represented by representation-rich complex-valued vectors in a Hilbert Space, rather than real-valued ones. In this paper, the Hilbert Space representation for ABSA models is investigated and the complexification of three strong real-valued baselines are constructed. Experimental results demonstrate the effectiveness of complexification and the outperformance of our complex-valued models, illustrating that the complex-valued embedding can carry additional information beyond the real embedding. Especially, a complex-valued RoBERTa model outperforms or approaches the previous state-of-the-art on three standard benchmarking datasets.

Published

2022

3. The Spontaneous Origin of New Levels in a Scalar Hierarchy

Author

Stanley N. Salthe

Subjects

Hierarchy (mathematics), Entropy production, media_common.quotation_subject, scalar hierarchy, Disequilibrium, Scalar (physics), Complexification, General Physics and Astronomy, Second law of thermodynamics, lcsh:Astrophysics, Aristotelian causal categories, Dissipation, entropy production, lcsh:QC1-999, Classical mechanics, lcsh:QB460-466, medicine, finality, lcsh:Q, medicine.symptom, lcsh:Science, Order of magnitude, lcsh:Physics, Mathematics, media_common

Abstract

Given a background of universal thermodynamic disequilibrium, I suggest that the interpolation of new levels in a material scale hierarchy is favored when the entropy production of a local region would be increased by such structural complexification. This would involve the separation by order of magnitude of the average dynamical rate of the new level compared to those of the resulting contiguous levels from which it became disentangled, thereby facilitating laminar flows. Here the Second Law of thermodynamics is understood as a final cause, which can be expressed in this creative way when the surrounding superstructure has a form allowing it to mediate this change (by, e.g., focusing kinetics, etc.), and given, as well, sufficiently differentiated local energy gradients to materially support the increased local dissipation.

Published

2004