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. 2021 Sep 27;17(9):e1009434. doi: 10.1371/journal.pcbi.1009434

Fig 3. aLB cells exhibit robustness against unstable or ephemeral cues, and can incorporate novel cues.

Fig 3

(A) Single environment (same as Fig 1B) with the ‘blue’ cue moving along the cylinder with 90 deg/s anticlockwise during training (left). Global representation of aLB cells tested on the unstable scenery with ‘blue’ cue moving by 90 deg/s anticlockwise (middle, εaLB = 0) and the stabilised scenery with ‘blue’ cue fixed after learning has stopped (right, εaLB = 0.5). (B) Single environment (same as Fig 1B) with the ‘blue’ cue teleporting to a random position on the cylinder every 10 seconds (left). Global representation of aLB cells tested on the unstable scenery with ‘blue’ cue teleporting every 10 seconds (middle, εaLB = 0) and the stabilised scenery with ‘blue’ cue fixed after learning has stopped (right, εaLB = 0.5). (C) Two sceneries (within the same environment) with the ‘red-blue’ scenery (Sc. I) and a ‘red-blue-green’ scenery (Sc. II). The agent stays in each scenery for 400 seconds (once from Sc. I to Sc. II and back to Sc. I), with feature-specific visual input signals in Sc. II (bottom). (D) Following the learning phase, the model is tested on the ‘red-blue’ scenery (i.e. Sc. I, top), the ‘red-blue-green’ scenery (i.e. Sc. II, middle), and the ‘green’ scenery (i.e. Sc. II with ‘red-blue’ scenery excluded, bottom). Stable unimodal aLB representations emerge in all cases (also see S3 Fig), with different sets of active cells in Sc. I vs. Sc. II (S4 Fig). Warmer colors represent higher firing rates of aLB cells. Abbreviations: HD: head direction; aLB: abstract landmark bearing; ego.: egocentric.