Exploring Early Number Abilities With Multimodal Transformers

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Alice Hein, Klaus Diepold
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引用次数: 0

Abstract

Early number skills represent critical milestones in children's cognitive development and are shaped over years of interacting with quantities and numerals in various contexts. Several connectionist computational models have attempted to emulate how certain number concepts may be learned, represented, and processed in the brain. However, these models mainly used highly simplified inputs and focused on limited tasks. We expand on previous work in two directions: First, we train a model end-to-end on video demonstrations in a synthetic environment with multimodal visual and language inputs. Second, we use a more holistic dataset of 35 tasks, covering enumeration, set comparisons, symbolic digits, and seriation. The order in which the model acquires tasks reflects input length and variability, and the resulting trajectories mostly fit with findings from educational psychology. The trained model also displays symbolic and non-symbolic size and distance effects. Using techniques from interpretability research, we investigate how our attention-based model integrates cross-modal representations and binds them into context-specific associative networks to solve different tasks. We compare models trained with and without symbolic inputs and find that the purely non-symbolic model employs more processing-intensive strategies to determine set size.

Abstract Image

利用多模式转换器探索早期数字能力
早期的数字技能是儿童认知发展的重要里程碑,是多年来在各种情境中与数量和数字互动形成的。一些联结主义计算模型试图模拟某些数字概念是如何在大脑中学习、表示和处理的。然而,这些模型主要使用高度简化的输入,并且只关注有限的任务。我们从两个方向扩展了之前的工作:首先,我们在一个具有多模态视觉和语言输入的合成环境中,通过视频演示对模型进行端到端训练。其次,我们使用了一个包含 35 项任务的更全面的数据集,涵盖了枚举、集合比较、符号数字和序列化。模型获取任务的顺序反映了输入的长度和可变性,由此产生的轨迹大多符合教育心理学的研究结果。训练后的模型还显示出符号和非符号的大小和距离效应。利用可解释性研究的技术,我们研究了基于注意力的模型如何整合跨模态表征,并将它们绑定到特定语境的联想网络中,以解决不同的任务。我们比较了有符号输入和无符号输入的模型,发现纯粹的非符号模型在确定集合大小时采用了更密集的处理策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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