A Neuro-vector-symbolic Architecture for Solving Raven's Progressive Matrices

Hersche, Michael; Zeqiri, Mustafa; Benini, Luca; Sebastian, Abu; Rahimi, Abbas

doi:10.48550/arxiv.2203.04571

Cited by 4 publications

(12 citation statements)

References 21 publications

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“…All of the previously described studies have two limitations: First, they assume the perception system provides the symbolic representations that support the reasoning for solving Raven's Progressive Matrices test, and, second, they only support the progression rule. [144] addressed these limitations by positioning VSA/HDC as a common language between a neural network (to solve the perception issue) and a symbolic logical reasoning engine (to support more rules). Specifically, it exploited the superposition of multiplicative bindings in a neural network to describe raw sensory visual objects in a panel and used Fourier Holographic Reduced Representations (FHRR) to efficiently emulate a symbolic logical reasoning with a rich set of rules [144].…”

Section: Cognitive Modelingmentioning

confidence: 99%

A Survey on Hyperdimensional Computing aka Vector Symbolic Architectures, Part II: Applications, Cognitive Models, and Challenges

et al. 2023

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This is Part II of the two-part comprehensive survey devoted to a computing framework most commonly known under the names Hyperdimensional Computing and Vector Symbolic Architectures (HDC/VSA). Both names refer to a family of computational models that use high-dimensional distributed representations and rely on the algebraic properties of their key operations to incorporate the advantages of structured symbolic representations and vector distributed representations. Holographic Reduced Representations [322, 327] is an influential HDC/VSA model that is well-known in the machine learning domain and often used to refer to the whole family. However, for the sake of consistency, we use HDC/VSA to refer to the field. Part I of this survey [223] covered foundational aspects of the field, such as the historical context leading to the development of HDC/VSA, key elements of any HDC/VSA model, known HDC/VSA models, and the transformation of input data of various types into high-dimensional vectors suitable for HDC/VSA. This second part surveys existing applications, the role of HDC/VSA in cognitive computing and architectures, as well as directions for future work. Most of the applications lie within the Machine Learning/Artificial Intelligence domain, however, we also cover other applications to provide a complete picture. The survey is written to be useful for both newcomers and practitioners.

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Section: Cognitive Modelingmentioning

confidence: 99%

A Survey on Hyperdimensional Computing aka Vector Symbolic Architectures, Part II: Applications, Cognitive Models, and Challenges

et al. 2023

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“…Neuro-symbolic approach and the next approach are data-driven approach, whereas the first two approaches are knowledge-based approaches. Examples of neuro-symbolic models for solving RPM-like tasks include ALANS2, PrAE, VAE-GPP, TRIVR, LoGe, and NVSA (Zhang et al, 2020(Zhang et al, , 2021Shi et al, 2021;He et al, 2021;Yu et al, 2021;Hersche et al, 2022).…”

Section: Neuro-symbolic Approachmentioning

confidence: 99%

Deep Non-Monotonic Reasoning for Visual Abstract Reasoning Tasks

Yang¹,

Sanyal²,

Michelson³

et al. 2023

Preprint

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While achieving unmatched performance on many welldefined tasks, deep learning models have also been used to solve visual abstract reasoning tasks, which are relatively less well-defined, and have been widely used to measure human intelligence. However, current deep models struggle to match human abilities to solve such tasks with minimum data but maximum generalization. One limitation is that current deep learning models work in a monotonic way, i.e., treating different parts of the input in essentially fixed orderings, whereas people repeatedly observe and reason about the different parts of the visual stimuli until the reasoning process converges to a consistent conclusion, i.e., non-monotonic reasoning. This paper proposes a non-monotonic computational approach to solve visual abstract reasoning tasks. In particular, we implemented a deep learning model using this approach and tested it on the RAVEN dataset-a dataset inspired by the Raven's Progressive Matrices test. Results show that the proposed approach is more effective than existing monotonic deep learning models, under strict experimental settings that represent a difficult variant of the RAVEN dataset problem.

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“…5.5 7.1 7.9 9.5 9.5 9.5 6. 5 www.nature.com/scientificreports/ implementation on average achieves 1.24x and 1.31x energy improvement compared to 2-bit and 3-bit implementations, respectively. These improvements are associated with the higher ML and DL voltages (see Supplementary Fig.…”

Section: Fefet Mcam Demonstrationmentioning

confidence: 99%

Achieving software-equivalent accuracy for hyperdimensional computing with ferroelectric-based in-memory computing

Kazemi

Müller

Sharifi

et al. 2022

Sci Rep

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Hyperdimensional computing (HDC) is a brain-inspired computational framework that relies on long hypervectors (HVs) for learning. In HDC, computational operations consist of simple manipulations of hypervectors and can be incredibly memory-intensive. In-memory computing (IMC) can greatly improve the efficiency of HDC by reducing data movement in the system. Most existing IMC implementations of HDC are limited to binary precision which inhibits the ability to match software-equivalent accuracies. Moreover, memory arrays used in IMC are restricted in size and cannot immediately support the direct associative search of large binary HVs (a ubiquitous operation, often over 10,000+ dimensions) required to achieve acceptable accuracies. We present a multi-bit IMC system for HDC using ferroelectric field-effect transistors (FeFETs) that simultaneously achieves software-equivalent-accuracies, reduces the dimensionality of the HDC system, and improves energy consumption by 826x and latency by 30x when compared to a GPU baseline. Furthermore, for the first time, we experimentally demonstrate multi-bit, array-level content-addressable memory (CAM) operations with FeFETs. We also present a scalable and efficient architecture based on CAMs which supports the associative search of large HVs. Furthermore, we study the effects of device, circuit, and architectural-level non-idealities on application-level accuracy with HDC.

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A Neuro-vector-symbolic Architecture for Solving Raven's Progressive Matrices

Cited by 4 publications

References 21 publications

A Survey on Hyperdimensional Computing aka Vector Symbolic Architectures, Part II: Applications, Cognitive Models, and Challenges

A Survey on Hyperdimensional Computing aka Vector Symbolic Architectures, Part II: Applications, Cognitive Models, and Challenges

Deep Non-Monotonic Reasoning for Visual Abstract Reasoning Tasks

Achieving software-equivalent accuracy for hyperdimensional computing with ferroelectric-based in-memory computing

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