Flexible multitask computation in recurrent networks utilizes shared dynamical motifs

Flexible action selection requires cognitive control mechanisms capable of mapping the same inputs to different output actions depending on the context. From a neural state-space perspective, this requires a control representation that separates similar input neural states by context. Additionally, for action selection to be robust and time-invariant, information must be stable in time, enabling efficient readout. Here, using EEG decoding methods, we investigate how the geometry and dynamics of control representations constrain flexible action selection in the human brain. Participants performed a context-dependent action selection task. A forced response procedure probed action selection different states in neural trajectories. The result shows that before successful responses, there is a transient expansion of representational dimensionality that separated conjunctive subspaces. Further, the dynamics stabilizes in the same time window, with entry into this stable, high-dimensional state predictive of individual trial performance. These results establish the neural geometry and dynamics the human brain needs for flexible control over behavior.

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Compositional pretraining improves computational efficiency and matches animal behavior on complex tasks

Hocker,

Constantinople,

Savin

2024

Preprint

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Recurrent neural networks (RNN) are ubiquitously used in neuroscience to capture both neural dynamics and behaviors of living systems. However, when it comes to complex cognitive tasks, traditional methods for training RNNs can fall short in capturing crucial aspects of animal behavior. To address this challenge, we leverage a commonly used (though rarely appreciated) approach from the experimental neuroscientist's toolkit: behavioral shaping. Taking as target a temporal wagering task previously studied in rats, we designed a pretraining curriculum of simpler cognitive tasks that are prerequisites for performing it well. These pretraining tasks are not simplified versions of the temporal wagering task, but rather reflect relevant sub-computations. We show that this approach is required for RNNs to adopt similar strategies as rats, including long-timescale inference of latent states, which conventional pretraining approaches fail to capture. Mechanistically, our pretraining supports the development of key dynamical systems features needed for implementing both inference and value-based decision making. Overall, our approach addresses a gap in neural network model training by incorporating inductive biases of animals, which is important when modeling complex behaviors that rely on computational abilities acquired from past experiences.

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Flexible multitask computation in recurrent networks utilizes shared dynamical motifs

Cited by 11 publications

References 56 publications

Where physics and biology meet

Where physics and biology meet

A transient high-dimensional geometry affords stable conjunctive subspaces for efficient action selection

Compositional pretraining improves computational efficiency and matches animal behavior on complex tasks

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