Title :
A partial model of cortical memory based on disinhibition
Abstract :
Describes a series of sparsely connected network architectures for auto-associative and serial memory. Some of the architectures (P-nets) form projective spaces which are subject to mathematical analysis and may be suitable for the construction of engineered devices. Others (R-nets) are randomized architectures whose properties may be inferred from the properties of P-nets, and may be useful as partial models of the mammalian cerebral cortex. A single learning and recall algorithm is given which is suitable for all of the various architectures. The simple algorithm employs binary (“clipped”) Hebbian synapses (or approximations thereof), binary neurons (or approximations thereof), and disinhibition rather than potentiation of excitatory synapses. Two layer P-nets with 1000 synapses per neuron and nearly 106 neurons per layer are shown have storage capacities of at least 1.5×106 training vectors with 20 active neurons each
Keywords :
content-addressable storage; learning (artificial intelligence); neural net architecture; neurophysiology; physiological models; P-nets; R-nets; active neurons; auto-associative memory; binary Hebbian synapses; binary neurons; cortical memory; disinhibition; engineered devices; learning algorithm; mammalian cerebral cortex; mathematical analysis; partial model; projective spaces; randomized architectures; recall algorithm; serial memory; sparsely connected network architectures; storage capacities; training vectors; Analytical models; Biological neural networks; Biological system modeling; Cerebral cortex; Computer architecture; Evolution (biology); Hippocampus; Mathematical analysis; Neurofeedback; Neurons;
Conference_Titel :
Neural Networks, 1999. IJCNN '99. International Joint Conference on
Conference_Location :
Washington, DC
Print_ISBN :
0-7803-5529-6
DOI :
10.1109/IJCNN.1999.831445
