The neural mechanisms supporting flexible relational inferences, especially in novel situations, are a major focus of current research. In the complementary learning systems framework, pattern separation in the hippocampus allows rapid learning in novel environments, while slower learning in neocortex accumulates small weight changes to extract systematic structure from well-learned environments. In this work, we adapt this framework to a task from a recent fMRI experiment where novel transitive inferences must be made according to implicit relational structure. We show that computational models capturing the basic cognitive properties of these two systems can explain relational transitive inferences in both familiar and novel environments,...
It is proposed that the distinction between basic and higher cognitive processes can be captured by ...
Higher-order relations are important for various cognitive tasks, such as analogical transfer. The c...
Patterns of correlated activity among brain regions reflect functionally relevant networks that are ...
© 2019 Neural information processing systems foundation. All rights reserved. Graph neural networks ...
& The hippocampus is critical for encoding and retrieving semantic and episodic memories. Animal...
Connectionist architectures constitute a popular method for modelling animal associative learning pr...
Relational integration is required when multiple explicit representations of relations between entit...
A novel, five-term relational reasoning paradigm was employed during functional magnetic resonance i...
Humans have a remarkable capacity to understand and act in situations they have not encountered befo...
The neuronal processes underlying reasoning and the related working memory subsystems were examined ...
ABSTRACT—Human mental representations are both flexi-ble and structured—properties that, together, p...
Real-world entities (e.g., people and places) are often connected via relations, forming multi-relat...
We introduce a novel method for relational learning with neural networks. The contributions of this ...
Relational data is ubiquitous in modern-day computing, and drives several key applications across mu...
Many complex processes can be viewed as dynamical systems of interacting agents. In many cases, only...
It is proposed that the distinction between basic and higher cognitive processes can be captured by ...
Higher-order relations are important for various cognitive tasks, such as analogical transfer. The c...
Patterns of correlated activity among brain regions reflect functionally relevant networks that are ...
© 2019 Neural information processing systems foundation. All rights reserved. Graph neural networks ...
& The hippocampus is critical for encoding and retrieving semantic and episodic memories. Animal...
Connectionist architectures constitute a popular method for modelling animal associative learning pr...
Relational integration is required when multiple explicit representations of relations between entit...
A novel, five-term relational reasoning paradigm was employed during functional magnetic resonance i...
Humans have a remarkable capacity to understand and act in situations they have not encountered befo...
The neuronal processes underlying reasoning and the related working memory subsystems were examined ...
ABSTRACT—Human mental representations are both flexi-ble and structured—properties that, together, p...
Real-world entities (e.g., people and places) are often connected via relations, forming multi-relat...
We introduce a novel method for relational learning with neural networks. The contributions of this ...
Relational data is ubiquitous in modern-day computing, and drives several key applications across mu...
Many complex processes can be viewed as dynamical systems of interacting agents. In many cases, only...
It is proposed that the distinction between basic and higher cognitive processes can be captured by ...
Higher-order relations are important for various cognitive tasks, such as analogical transfer. The c...
Patterns of correlated activity among brain regions reflect functionally relevant networks that are ...