Abstract
Growing neuropsychological and neurophysiological evidence suggests that the visual cortex uses parts-based representations to encode, store and retrieve relevant objects. In such a scheme, objects are represented as a set of spatially distributed local features, or parts, arranged in stereotypical fashion. To encode the local appearance and to represent the relations between the constituent parts, there has to be an appropriate memory structure formed by previous experience with visual objects. Here, we propose a model how a hierarchical memory structure supporting efficient storage and rapid recall of parts-based representations can be established by an experience-driven process of self-organization. The process is based on the collaboration of slow bidirectional synaptic plasticity and homeostatic unit activity regulation, both running at the top of fast activity dynamics with winner-take-all character modulated by an oscillatory rhythm. These neural mechanisms lay down the basis for cooperation and competition between the distributed units and their synaptic connections. Choosing human face recognition as a test task, we show that, under the condition of open-ended, unsupervised incremental learning, the system is able to form memory traces for individual faces in a parts-based fashion. On a lower memory layer the synaptic structure is developed to represent local facial features and their interrelations, while the identities of different persons are captured explicitly on a higher layer. An additional property of the resulting representations is the sparseness of both the activity during the recall and the synaptic patterns comprising the memory traces.
Highlights
A working hypothesis of cognitive neuroscience states that the higher functions of the brain require coordinated interplay of multiple cortical areas distributed over the brain-wide network
We propose a model how a hierarchical memory structure supporting efficient storage and rapid recall of parts-based representations can be established by an experience-driven process of self-organization.The process is based on the collaboration of slow bidirectional synaptic plasticity and homeostatic unit activity regulation, both running at the top of fast activity dynamics with winner-take-all character modulated by an oscillatory rhythm.These neural mechanisms lay down the basis for cooperation and competition between the distributed units and their synaptic connections
To identify potential neural mechanisms that are responsible for the formation of parts-based representations in visual memory, we examined the process of experience-driven structure selforganization in a model of layered memory
Summary
A working hypothesis of cognitive neuroscience states that the higher functions of the brain require coordinated interplay of multiple cortical areas distributed over the brain-wide network. It is widely held that processes responsible for memory formation rely on activity-dependent modification of the synaptic transmission and on regulation of the intrinsic properties of single neurons (Bear, 1996; Miyashita, 1988; Zhang and Linden, 2003). It is far from clear how these local processes could be orchestrated for memorizing complex visual objects composed of many spatially distributed subparts arranged in stereotypic relations. This seems to be a neuronal basis for the parts-based representation that the visual system employs to construct objects from their constituent part elements (Ullman et al, 2002; Hayworth and Biederman, 2006)
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