Difference between revisions of "BiologicalArchitectureSubsymbolic"
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== Overview == | == Overview == | ||
− | + | * mind connections can be divided into aggregating and direct | |
+ | * aggregating connections reduce level of details, constructing abstracts - object-bound, body-bound or spatial | ||
+ | ** abstracts are also known as symbolic elements | ||
+ | ** abstracts help to create complex behavior by means of integrating many modalities and static and dynamic aspects of environment | ||
+ | * direct (subsymbolic) connections create behaviour without aggregation | ||
+ | ** most simple is environment-bound muscle power control: gamma-motoneuron -> muscle -> nucleus proprius -> alpha-motoneuron | ||
+ | ** major non-aggregating circuit is muscle control by touch: skin -> dorsal column nuclei -> ventroposterolateral thalamic nucleus -> S1 -> M1 -> muscle |
Revision as of 10:48, 29 November 2015
Biological Life Research
Home -> BiologicalLifeResearch -> BiologicalArchitecture -> BiologicalArchitectureSubsymbolic
This page covers biological principles of subsymbolic implementation.
Overview
- mind connections can be divided into aggregating and direct
- aggregating connections reduce level of details, constructing abstracts - object-bound, body-bound or spatial
- abstracts are also known as symbolic elements
- abstracts help to create complex behavior by means of integrating many modalities and static and dynamic aspects of environment
- direct (subsymbolic) connections create behaviour without aggregation
- most simple is environment-bound muscle power control: gamma-motoneuron -> muscle -> nucleus proprius -> alpha-motoneuron
- major non-aggregating circuit is muscle control by touch: skin -> dorsal column nuclei -> ventroposterolateral thalamic nucleus -> S1 -> M1 -> muscle