Ritz R, Gerstner W, Fuentes U, van Hemmen J L
Department of Physics, Technical University of Munich, Germany.
Biol Cybern. 1994;71(4):349-58. doi: 10.1007/BF00239622.
Feature linking and pattern separation are shown to be performed as simultaneous processes by a highly connected auto-associative network of spiking neurons (spike response model). In principle, many (e.g., with nine) patterns can be separated, but with a biological set of parameters the number is limited to four. The patterns have been learned by an asymmetric hebbian rule that can handle a low activity which may vary from pattern to pattern (in a range between 4% and 7%). Spikes are generated by a threshold process and--with some delay--transmitted to postsynaptic neurons. There they evoke an excitatory or inhibitory postsynaptic potential (EPSP or IPSP). Spike emission is followed by an absolute refractory period (1 ms) and activates an inhibitory delay loop that prevents continuous firing. Three different network topologies are discussed, i.e., a structureless fully connected system, a network composed of two 'hemispheres', and finally a hierarchical network with four subsystems that represent different 'functions' and interact via feedforward and feedback connections. Functional feedback turns out to be essential for context-sensitive binding. The coherence between the two hemispheres is dependent on the interhemispheric delays. If these are on average too large, the two hemispheres oscillate coherently by themselves but phase-shifted by half a period with respect to each other.
特征链接和模式分离被证明是由一个高度连接的脉冲神经元自联想网络(脉冲响应模型)同时执行的过程。原则上,可以分离许多(例如九个)模式,但在一组生物学参数下,数量限制为四个。这些模式是通过一种不对称赫布规则学习得到的,该规则可以处理可能因模式而异的低活动(在4%到7%的范围内)。脉冲由阈值过程产生,并在经过一定延迟后传递到突触后神经元。在那里,它们会引发兴奋性或抑制性突触后电位(EPSP或IPSP)。脉冲发放之后是绝对不应期(1毫秒),并激活一个抑制性延迟环路,以防止持续放电。文中讨论了三种不同的网络拓扑结构,即无结构的全连接系统、由两个“半球”组成的网络,以及最后一个具有四个子系统的层次网络,这四个子系统代表不同的“功能”,并通过前馈和反馈连接进行交互。事实证明,功能反馈对于上下文敏感绑定至关重要。两个半球之间的相干性取决于半球间延迟。如果这些延迟平均过大,两个半球会各自相干振荡,但彼此之间相位相差半个周期。
