Title :
Neuromorphic hardware for rapid sparse coding
Author :
Shapero, S. ; Hasler, P.
Abstract :
Sparse coding is an important optimization problem in many signal processing applications. A neuromorphic system based on the Locally Competitive Algorithm (LCA) is proposed to solve an overcomplete ℓ1 sparse coding problem. The system includes integrate and fire (IF) neurons and current-based synapses. A network of 18 neurons with 12 inputs is implemented on the RASP 2.9v chip, a Field Programmable Analog Array (FPAA) with directly programmable floating gate elements. The circuit successfully solves the optimization problem, converging to within 4.8% RMS of a digital solver, with an objective cost only 1.7% higher on average. The active circuit consumes 559 μA of current at 2.4V, and converges on solutions in 25 μs.
Keywords :
active networks; bioelectric phenomena; competitive algorithms; encoding; field programmable analogue arrays; medical signal processing; neurophysiology; optimisation; FPAA; LCA; RASP 2.9v chip; active circuit; active circuit consumes; current 559 muA; current-based synapses; digital solver; field programmable analog array; fire neurons; integrate neurons; locally competitive algorithm; neuromorphic hardware; neuron network; optimization problem; programmable floating gate elements; rapid sparse coding; signal processing; time 25 mus; voltage 2.4 V; Artificial neural networks; Field programmable analog arrays; Logic gates; Neurons; FPAA; LCA; Sparse approximation; integrate and fire neurons; non-linear optimization;
Conference_Titel :
Biomedical Circuits and Systems Conference (BioCAS), 2012 IEEE
Conference_Location :
Hsinchu
Print_ISBN :
978-1-4673-2291-1
Electronic_ISBN :
978-1-4673-2292-8
DOI :
10.1109/BioCAS.2012.6418413
