A Learning Analog Neural Network Chip with Continuous-Time Recurrent Dynamics
- Creators
- Cauwenberghs, Gert
Abstract
We present experimental results on supervised learning of dynamical features in an analog VLSI neural network chip. The recurrent network, containing six continuous-time analog neurons and 42 free parameters (connection strengths and thresholds), is trained to generate time-varying outputs approximating given periodic signals presented to the network. The chip implements a stochastic perturbative algorithm, which observes the error gradient along random directions in the parameter space for error-descent learning. In addition to the integrated learning functions and the generation of pseudo-random perturbations, the chip provides for teacher forcing and long-term storage of the volatile parameters. The network learns a 1 kHz circular trajectory in 100 sec. The chip occupies 2mm x 2mm in a 2μm CMOS process, and dissipates 1.2 m W.
Additional Information
© 1994 Morgan Kaufmann. Fabrication of the CMOS chip was provided through the DARPA/NSF MOSIS service. Financial support by the NIPS Foundation largely covered the expenses of attending the conference.Attached Files
Published - 778-a-learning-analog-neural-network-chip-with-continuous-time-recurrent-dynamics.pdf
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Additional details
- Eprint ID
- 55570
- Resolver ID
- CaltechAUTHORS:20150305-163505478
- NIPS Foundation
- Created
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2015-03-06Created from EPrint's datestamp field
- Updated
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2019-10-03Created from EPrint's last_modified field