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Literature DB >> 3395634

Adaptive timing in neural networks: the conditioned response.

Abstract

A conditioned response not only reflects knowledge of an association between two events, a CS and a US, it also reflects knowledge about the timing of these events. A neural network and set of learning rules that generates appropriately timed conditioned response waveforms is presented. The model is capable of simulating some of the basic temporal properties of conditioned responses exhibited in biological systems, including (1) decreasing onset latency during acquisition training, (2) peak amplitude occurring at the temporal locus of the US, (3) inhibition of delay, and (4) trace conditioning. The model is also capable of simulating complex CR waveforms under certain conditions, and these simulations are compared with the results of behavioral experiments. The temporally adaptive responses are achieved by virtue of stimulus trace processes that are built into the network architecture.

Entities: Chemical

Mesh：

Year: 1988 PMID： 3395634 DOI： 10.1007/bf00361347

Source DB: PubMed Journal: Biol Cybern ISSN： 0340-1200 Impact factor: 2.086

18 in total

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2. Hebbian synapses in hippocampus.

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6. Is there a cell-biological alphabet for simple forms of learning?

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7. Is the cerebellar cortex a biological clock in the millisecond range?

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8. Simulation of anticipatory responses in classical conditioning by a neuron-like adaptive element.

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10. Single-cell neuronal model for associative learning.

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32 in total

1. Temporal discrimination using different feature--target intervals in classical conditioning of the rabbit's nictitating membrane response.

Authors: E J Kehoe; K G Boesenberg
Journal: Anim Learn Behav Date: 2002-08

2. Temporal characteristics of the predictive synchronous firing modeled by spike-timing-dependent plasticity.

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3. Control of rabbit nictitating membrane movements. I. A computer model of the retractor bulbi muscle and the associated orbital mechanics.

Authors: G T Bartha; R F Thompson
Journal: Biol Cybern Date: 1992 Impact factor: 2.086

Adaptive timing in neural networks: the conditioned response.

1. A micromolar approach to behavior theory.

2. Hebbian synapses in hippocampus.

3. A model of hippocampal learning during classical conditioning.

4. Hippocampal long-term potentiation is induced by pairing single afferent volleys with intracellularly injected depolarizing current pulses.

5. Modeling the neural substrates of associative learning and memory: a computational approach.

6. Is there a cell-biological alphabet for simple forms of learning?

7. Is the cerebellar cortex a biological clock in the millisecond range?

8. Simulation of anticipatory responses in classical conditioning by a neuron-like adaptive element.

9. Toward a modern theory of adaptive networks: expectation and prediction.

10. Single-cell neuronal model for associative learning.

1. Temporal discrimination using different feature--target intervals in classical conditioning of the rabbit's nictitating membrane response.

2. Temporal characteristics of the predictive synchronous firing modeled by spike-timing-dependent plasticity.

3. Control of rabbit nictitating membrane movements. I. A computer model of the retractor bulbi muscle and the associated orbital mechanics.

Review 4. Timing of omitted events: an analysis of temporal control of inhibitory behavior.

5. Repeated acquisitions and extinctions in classical conditioning of the rabbit nictitating membrane response.

Review 6. Computational models of timing mechanisms in the cerebellar granular layer.

7. Altering the synchrony of stimulus trace processes: tests of a neural-network model.

8. On the origin of personal causal theories.

9. The role of temporal variables in inhibition produced through extinction.

10. Time course of classically conditioned Purkinje cell response is determined by initial part of conditioned stimulus.