Autonomous Learning With High-Dimensional Computing Architecture Similar to Von Neumann's.

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Bibliographic Details
Title: Autonomous Learning With High-Dimensional Computing Architecture Similar to Von Neumann's.
Authors: Kanerva, Pentti (AUTHOR)
Source: Neural Computation. Jul2026, Vol. 38 Issue 7, p1117-1134. 18p.
Subjects: Computer architecture, Biologically inspired computing, Automaticity (Learning process), Cognitive robotics, Computational neuroscience, Von Neumann, John, 1903-1957, Artificial intelligence
Abstract: We model human and animal learning by computing with high-dimensional vectors (e.g., D = 10,000). The architecture resembles traditional (von Neumann) computing with numbers, but the instructions refer to vectors and operate on them in superposition. The architecture includes a high-capacity memory for vectors, counterpart of the random-access memory (RAM) for numbers. The model's ability to learn from data reminds us of deep learning, but with an architecture closer to biology. The architecture agrees with an idea from psychology that human memory and learning involve a short-term working memory and a long-term data store. Neuroscience provides us with a model of the long-term memory, namely, the cortex of the cerebellum. With roots in psychology, biology, and traditional computing, a theory of computing with vectors can help us understand how brains compute. Application to learning by robots seems inevitable, but there is likely to be more, including language. Ultimately we want to compute with no more material and energy than brains use. To that end, we need a mathematical theory that agrees with psychology and biology and is suitable for nano-technology. We also need to exercise the theory in large-scale experiments. The analogy with traditional computing suggests that the architecture be programmable in terms of variables, values, and data structures, the very things that have made traditional computing ubiquitous and that seem worth learning from and emulating. [ABSTRACT FROM AUTHOR]
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Database: Psychology and Behavioral Sciences Collection
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