Opening the Black Box: Low-Dimensional Dynamics in High-Dimensional Recurrent Neural Networks
Stanford University · Columbia University
Abstract
Recurrent neural networks (RNNs) are useful tools for learning nonlinear relationships between time-varying inputs and outputs with complex temporal dependencies. Recently developed algorithms have been successful at training RNNs to perform a wide variety of tasks, but the resulting networks have been treated as black boxes: their mechanism of operation remains unknown. Here we explore the hypothesis that fixed points, both stable and unstable, and the linearized dynamics around them, can reveal crucial aspects of how RNNs implement their computations. Further, we explore the utility of linearization in areas of phase space that are not true fixed points but merely points of very slow movement. We present a…
Citation impact
- FWCI
- 29.62
- Percentile
- 100%
- References
- 36
Authors
2Topics & keywords
- Recurrent neural network
- Linearization
- Computer science
- Generator (circuit theory)
- Fixed point
- Nonlinear system
- Simple (philosophy)
- Computation