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Stability through plasticity: Finding robust memories through representational drift.

Maanasa Natrajan1,2,3,4, James E Fitzgerald1,3,4,5,6

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Summary
This summary is machine-generated.

Representational drift uncovers robust neural representations that are hard to learn. Combining drift with an allocation procedure balances learnability and robustness, resolving a key trade-off in memory storage.

Keywords:
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Area of Science:

  • Neuroscience
  • Computational Neuroscience
  • Machine Learning

Background:

  • Memories are stored in synapses, with learning altering synaptic weights.
  • Altered synaptic weights can interfere with existing memories, creating a plasticity-stability trade-off.
  • Neural representations can change without learning, a phenomenon called representational drift.

Purpose of the Study:

  • Investigate whether representational drift yields unique or advantageous neural representations.
  • Determine if drift explores representations different from learned ones.
  • Clarify the role of drift in memory stability and plasticity.

Main Methods:

  • Defined the nonlinear solution space manifold of synaptic weights.
  • Simulated representational drift as diffusion within this manifold.
  • Introduced a novel allocation procedure to shift representations.

Main Results:

  • Representational drift uncovers noise-robust representations with inactive/saturated neurons.
  • These drift-explored solutions are entropically favored but difficult to learn due to lack of gradients.
  • The allocation procedure shifts representations into a learning-conducive regime.

Conclusions:

  • Representational drift discovers robust, albeit hard-to-learn, neural representations.
  • Combining drift with allocation resolves the learnability-robustness trade-off.
  • This approach offers a novel strategy for memory storage and continual learning.