Title: |
Solving a steady-state PDE using spiking networks and neuromorphic hardware |
Authors: |
Smith, J. Darby, Severa, William, Hill, Aaron J., Reeder, Leah, Franke, Brian, Lehoucq, Richard B., Parekh, Ojas D., Aimone, James B. |
Publication Year: |
2020 |
Collection: |
Computer Science |
Subject Terms: |
Computer Science - Neural and Evolutionary Computing, Computer Science - Computational Engineering, Finance, and Science |
More Details: |
The widely parallel, spiking neural networks of neuromorphic processors can enable computationally powerful formulations. While recent interest has focused on primarily machine learning tasks, the space of appropriate applications is wide and continually expanding. Here, we leverage the parallel and event-driven structure to solve a steady state heat equation using a random walk method. The random walk can be executed fully within a spiking neural network using stochastic neuron behavior, and we provide results from both IBM TrueNorth and Intel Loihi implementations. Additionally, we position this algorithm as a potential scalable benchmark for neuromorphic systems. Comment: Submitted to 2020 International Conference on Neuromorphic Systems (2020 ICONS) |
Document Type: |
Working Paper |
Access URL: |
http://arxiv.org/abs/2005.10904 |
Accession Number: |
edsarx.2005.10904 |
Database: |
arXiv |