Abstract
In the present study, a new architecture for the generation of grid cells (GC) was implemented on a real robot. In order to test this model a simple place cell (PC) model merging visual PC activity and GC was developed. GC were first built from a simple “several to one” projection (similar to a modulo operation) performed on a neural field coding for path integration (PI). Robotics experiments raised several practical and theoretical issues. To limit the important angular drift of PI, head direction information was introduced in addition to the robot proprioceptive signal coming from the wheel rotation. Next, a simple associative learning between visual place cells and the neural field coding for the PI has been used to recalibrate the PI and to limit its drift. Finally, the parameters controlling the shape of the PC built from the GC have been studied. Increasing the number of GC obviously improves the shape of the resulting place field. Yet, other parameters such as the discretization factor of PI or the lateral interactions between GC can have an important impact on the place field quality and avoid the need of a very large number of GC. In conclusion, our results show our GC model based on the compression of PI is congruent with neurobiological studies made on rodent. GC firing patterns can be the result of a modulo transformation of PI information. We argue that such a transformation may be a general property of the connectivity from the cortex to the entorhinal cortex. Our model predicts that the effect of similar transformations on other kinds of sensory information (visual, tactile, auditory, etc…) in the entorhinal cortex should be observed. Consequently, a given EC cell should react to non-contiguous input configurations in non-spatial conditions according to the projection from its different inputs.
Highlights
In robotics, getting a robust localization is crucial to achieve navigational tasks
Results of Experiment 3 The results presented on Figure 7 — demonstrate that the precision of the generated grids highly depends on the size of the recalibration area which itself depends on the visual place cells (VPC) properties and on the competition mechanism to select the winning cell
If a VPC has been learned near the center of the environment, its place field can be really larger than if it has been learned near a border of the environment
Summary
In robotics, getting a robust localization is crucial to achieve navigational tasks. Simultaneous Localization and Mapping (SLAM) is a problem that has concentrated much of the research effort in autonomous robot navigation for more than 20 years (Chatila and Laumond, 1985; Durrant-Whyte and Bailey, 2006). The complexity of EKF is quadratic with respect to the landmark’s number and it behaves badly in large environment. This algorithm is very sensitive to bad associations. To cope with these limitations, numerous methods have been proposed. One can refer to Thrun et al (2005) and Thrun (2008) for a review
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