Online Algorithm for Robots to Learn Object Concepts and Language Model

Nishihara, Joe; Nagaoka, Tomoaki; Nagai, Takayuki

doi:10.1109/tcds.2016.2552579

Cited by 24 publications

(21 citation statements)

References 30 publications

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“…A further advancement of such cognitive systems allows the robots to find meanings of words by treating a linguistic input as another modality [13][14][15]. Cognitive models have recently become more complex in realizing various cognitive capabilities: grammar acquisition [16], language model learning [17], hierarchical concept acquisition [18,19], spatial concept acquisition [20], motion skill acquisition [21], and task planning [7] (see Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

Neuro-SERKET: Development of Integrative Cognitive System Through the Composition of Deep Probabilistic Generative Models

et al. 2020

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This paper describes a framework for the development of an integrative cognitive system based on probabilistic generative models (PGMs) called Neuro-SERKET. Neuro-SERKET is an extension of SERKET, which can compose elemental PGMs developed in a distributed manner and provide a scheme that allows the composed PGMs to learn throughout the system in an unsupervised way. In addition to the head-to-tail connection supported by SERKET, Neuro-SERKET supports tail-totail and head-to-head connections, as well as neural network-based modules, i.e., deep generative models. As an example of a Neuro-SERKET application, an integrative model was developed by composing a variational autoencoder (VAE), a Gaussian mixture model (GMM), latent Dirichlet allocation (LDA), and automatic speech recognition (ASR). The model is called VAE + GMM + LDA + ASR. The performance of VAE + GMM + LDA + ASR and the validity of Neuro-SERKET were demonstrated through a multimodal categorization task using image data and a speech signal of numerical digits.

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Section: Introductionmentioning

confidence: 99%

Neuro-SERKET: Development of Integrative Cognitive System Through the Composition of Deep Probabilistic Generative Models

et al. 2020

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“…Creating a robot that can learn language from its own sensorimotor experience alone is one of our challenges, which is an essential element for the understanding of symbol emergence in cognitive systems. Many studies have been exploring the challenge in modeling language acquisition in developmental process using neural networks [91], [124], [152] and probabilistic models [5], [88], [153], [154].…”

Section: Language Acquisition By a Robotmentioning

confidence: 99%

Symbol Emergence in Cognitive Developmental Systems: A Survey

Taniguchi

Piater

Wörgötter

et al. 2019

IEEE Trans. Cogn. Dev. Syst.

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Humans use signs, e.g., sentences in a spoken language, for communication and thought. Hence, symbol systems like language are crucial for our communication with other agents and adaptation to our real-world environment. The symbol systems we use in our human society adaptively and dynamically change over time. In the context of artificial intelligence (AI) and cognitive systems, the symbol grounding problem has been regarded as one of the central problems related to symbols. However, the symbol grounding problem was originally posed to connect symbolic AI and sensorimotor information and did not consider many interdisciplinary phenomena in human communication and dynamic symbol systems in our society, which semiotics considered. In this paper, we focus on the symbol emergence problem, addressing not only cognitive dynamics but also the dynamics of symbol systems in society, rather than the symbol grounding problem. We first introduce the notion of a symbol in semiotics from the humanities, to leave the very narrow idea of symbols in symbolic AI. Furthermore, over the years, it became more and more clear that symbol emergence has to be regarded as a multifaceted problem. Therefore, secondly, we review the history of the symbol emergence problem in different fields, including both biological and artificial systems, showing their mutual relations. We summarize the discussion and provide an integrative viewpoint and comprehensive overview of symbol emergence in cognitive systems. Additionally, we describe the challenges facing the creation of cognitive systems that can be part of symbol emergence systems. Fig. 1. Robot in a home environment that has to deal with complex manipulation, planning, and interaction via semiotic communication with human users.

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“…The NPYLM is an unsu-pervised morphological analysis method based on a statistical model that enables word segmentation exclusively from phoneme sequences (Mochihashi et al 2009). In addition, Nishihara et al (2017) was able to reduce phoneme recognition errors by applying PFoMDLA to inferences using a particle filter instead of oMLDA. In these studies, online learning was realized as an algorithm in unsupervised machine learning.…”

Section: Improvement Of Online Learning Based On Particle Filters In mentioning

confidence: 99%

Improved and scalable online learning of spatial concepts and language models with mapping

et al. 2020

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We propose a novel online learning algorithm, called SpCoSLAM 2.0, for spatial concepts and lexical acquisition with high accuracy and scalability. Previously, we proposed SpCoSLAM as an online learning algorithm based on unsupervised Bayesian probabilistic model that integrates multimodal place categorization, lexical acquisition, and SLAM. However, our original algorithm had limited estimation accuracy owing to the influence of the early stages of learning, and increased computational complexity with added training data. Therefore, we introduce techniques such as fixed-lag rejuvenation to reduce the calculation time while maintaining an accuracy higher than that of the original algorithm. The results show that, in terms of estimation accuracy, the proposed algorithm exceeds the original algorithm and is comparable to batch learning. In addition, the calculation time of the proposed algorithm does not depend on the amount of training data and becomes constant for each step of the scalable algorithm. Our approach will contribute to the realization of long-term spatial language interactions between humans and robots.

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Online Algorithm for Robots to Learn Object Concepts and Language Model

Cited by 24 publications

References 30 publications

Neuro-SERKET: Development of Integrative Cognitive System Through the Composition of Deep Probabilistic Generative Models

Neuro-SERKET: Development of Integrative Cognitive System Through the Composition of Deep Probabilistic Generative Models

Symbol Emergence in Cognitive Developmental Systems: A Survey

Improved and scalable online learning of spatial concepts and language models with mapping

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