| Q57068049 | A Map-like Micro-Organization of Grid Cells in the Medial Entorhinal Cortex |
| Q47350553 | A Multiplexed, Heterogeneous, and Adaptive Code for Navigation in Medial Entorhinal Cortex. |
| Q42063689 | A biologically inspired hierarchical goal directed navigation model |
| Q50684210 | A feedforward model for the formation of a grid field where spatial information is provided solely from place cells. |
| Q42051157 | A goal-directed spatial navigation model using forward trajectory planning based on grid cells |
| Q57048804 | A hierarchical anti-Hebbian network model for the formation of spatial cells in three-dimensional space |
| Q38589110 | A hybrid oscillatory interference/continuous attractor network model of grid cell firing |
| Q35990354 | A model combining oscillations and attractor dynamics for generation of grid cell firing |
| Q42703015 | A single-cell spiking model for the origin of grid-cell patterns |
| Q98306024 | A theory of joint attractor dynamics in the hippocampus and the entorhinal cortex accounts for artificial remapping and grid cell field-to-field variability |
| Q21145367 | Accurate path integration in continuous attractor network models of grid cells |
| Q41530845 | An Analysis of Waves Underlying Grid Cell Firing in the Medial Enthorinal Cortex |
| Q89742656 | An uncertainty principle for neural coding: Conjugate representations of position and velocity are mapped onto firing rates and co-firing rates of neural spike trains |
| Q37998502 | Attractor dynamics of spatially correlated neural activity in the limbic system. |
| Q51762028 | Compromised Grid-Cell-like Representations in Old Age as a Key Mechanism to Explain Age-Related Navigational Deficits. |
| Q37922313 | Computational models of grid cells |
| Q27322767 | Continuous attractor network model for conjunctive position-by-velocity tuning of grid cells |
| Q39168473 | Continuous attractor network models of grid cell firing based on excitatory-inhibitory interactions |
| Q42788571 | Coordinated learning of grid cell and place cell spatial and temporal properties: multiple scales, attention and oscillations |
| Q30497347 | Coupled noisy spiking neurons as velocity-controlled oscillators in a model of grid cell spatial firing |
| Q38382886 | Current questions on space and time encoding |
| Q41889357 | DC-shifts in amplitude in-field generated by an oscillatory interference model of grid cell firing |
| Q43164335 | Differences in Visual-Spatial Input May Underlie Different Compression Properties of Firing Fields for Grid Cell Modules in Medial Entorhinal Cortex |
| Q92611000 | Entorhinal velocity signals reflect environmental geometry |
| Q47720988 | Environmental boundaries as a mechanism for correcting and anchoring spatial maps |
| Q27335138 | Evaluation of the oscillatory interference model of grid cell firing through analysis and measured period variance of some biological oscillators |
| Q38770922 | Framing the grid: effect of boundaries on grid cells and navigation. |
| Q28081822 | Grid Cells and Place Cells: An Integrated View of their Navigational and Memory Function |
| Q48409122 | Grid alignment in entorhinal cortex |
| Q34433030 | Grid cell firing patterns may arise from feedback interaction between intrinsic rebound spiking and transverse traveling waves with multiple heading angles |
| Q38219358 | Grid cells and cortical representation |
| Q98664996 | Grid cells are modulated by local head direction |
| Q30939904 | Grid cells in 3-D: Reconciling data and models |
| Q37330276 | Grid cells: the position code, neural network models of activity, and the problem of learning |
| Q34450934 | Head direction is coded more strongly than movement direction in a population of entorhinal neurons. |
| Q40203989 | How does the modular organization of entorhinal grid cells develop? |
| Q50766083 | How environment and self-motion combine in neural representations of space. |
| Q56808720 | Inferring circuit mechanisms from sparse neural recording and global perturbation in grid cells |
| Q91701285 | Inhibitory Connectivity Dominates the Fan Cell Network in Layer II of Lateral Entorhinal Cortex |
| Q89625924 | Inter- and intra-animal variation in the integrative properties of stellate cells in the medial entorhinal cortex |
| Q42736476 | Membrane potential dynamics of grid cells |
| Q38812056 | Modelling effects on grid cells of sensory input during self-motion |
| Q38005119 | Models of grid cell spatial firing published 2005-2011 |
| Q42788573 | Neuronal rebound spiking, resonance frequency and theta cycle skipping may contribute to grid cell firing in medial entorhinal cortex |
| Q42361873 | Noise promotes independent control of gamma oscillations and grid firing within recurrent attractor networks |
| Q42788567 | Oscillatory neurocomputing with ring attractors: a network architecture for mapping locations in space onto patterns of neural synchrony |
| Q89971252 | Overview of computational models of hippocampus and related structures: Introduction to the special issue |
| Q83836743 | Phase precession and variable spatial scaling in a periodic attractor map model of medial entorhinal grid cells with realistic after-spike dynamics |
| Q38682053 | Place and Grid Cells in a Loop: Implications for Memory Function and Spatial Coding. |
| Q64099833 | Position Estimation Based on Grid Cells and Self-Growing Self-Organizing Map |
| Q28655034 | Principles of goal-directed spatial robot navigation in biomimetic models |
| Q36689773 | Rebound spiking in layer II medial entorhinal cortex stellate cells: Possible mechanism of grid cell function. |
| Q100458781 | Recurrent amplification of grid-cell activity |
| Q41037658 | Size Matters: How Scaling Affects the Interaction between Grid and Border Cells. |
| Q27334340 | Solving navigational uncertainty using grid cells on robots |
| Q41944285 | Specific evidence of low-dimensional continuous attractor dynamics in grid cells |
| Q47828403 | Stellate Cells in the Medial Entorhinal Cortex Are Required for Spatial Learning. |
| Q38792532 | Ten Years of Grid Cells |
| Q38832825 | The Art of Grid Fields: Geometry of Neuronal Time |
| Q30628073 | The functional micro-organization of grid cells revealed by cellular-resolution imaging |
| Q41913178 | The input-output transformation of the hippocampal granule cells: from grid cells to place fields. |
| Q38115099 | Theta rhythm and the encoding and retrieval of space and time. |
| Q26801522 | Using Grid Cells for Navigation |
| Q83229058 | Velocity coupling of grid cell modules enables stable embedding of a low dimensional variable in a high dimensional neural attractor |
| Q36020496 | Voltage dependence of subthreshold resonance frequency in layer II of medial entorhinal cortex |