Learning in a geometric model of place cell firing

Hippocampus 68:317-330) have observed that the spatially selective firing of pyramidal cells in the CAI field of the rat hippocampus tends to advance to earlier phases of the electroencephalogram theta rhythm as a rat passes through the place field of a cell. We present here a neural network model b

## Abstract To ask if the properties of spatial learning supported by the hippocampus are distinct from the properties of conditioning, we conducted a blocking‐like experiment in which the measured variable was not a conditioned response but rather the ability of a novel visual stimulus to control

## Abstract We show that a model of the hippocampus introduced recently by Scarpetta et al. (2002, Neural Computation 14(10):2371–2396) explains the theta phase precession phenomena. In our model, the theta phase precession comes out as a consequence of the associative‐memory‐like network dynamics,

Entrainment of output action potentials from repetitively firing pacemaker cells, brought about by regularly spaced excitatory or inhibitory postsynaptic inputs, is a well-known phenomenon. Synchronization of neural firing patterns by extremely low frequency (ELF) external electric fields has also b

Our model of the spatial and temporal aspects of place cell firing and their role in rat navigation is reviewed. The model provides a candidate mechanism, at the level of individual cells, by which place cell information concerning self-localization could be used to guide navigation to previously vi

## Abstract The hippocampus has long been thought essential for implementing a cognitive map of the environment. However, almost 30 years since place cells were found in rodent hippocampal field CA1, it is still unclear how such an allocentric representation arises from an egocentrically perceived