| review article | Q7318358 |
| scholarly article | Q13442814 |
| P6179 | Dimensions Publication ID | 1009484325 |
| P356 | DOI | 10.1038/81469 |
| P698 | PubMed publication ID | 11127837 |
| P5875 | ResearchGate publication ID | 12200740 |
| P2093 | author name string | Snyder LH | |
| Pouget A | |||
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| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 1192-1198 | |
| P577 | publication date | 2000-11-01 | |
| P1433 | published in | Nature Neuroscience | Q1535359 |
| P1476 | title | Computational approaches to sensorimotor transformations | |
| P478 | volume | 3 Suppl |
| Q46044246 | 3D Visual Response Properties of MSTd Emerge from an Efficient, Sparse Population Code |
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| Q34992391 | Brain Activation Related to Combinations of Gaze Position, Visual Input, and Goal-Directed Hand Movements |
| Q36823187 | Brevity of haptic force perturbations induces heightened adaptive sensitivity |
| Q40033887 | Characteristics of Eye-Position Gain Field Populations Determine Geometry of Visual Space |
| Q33893818 | Characteristics of Implicit Sensorimotor Adaptation Revealed by Task-irrelevant Clamped Feedback. |
| Q30523787 | Coding of the reach vector in parietal area 5d. |
| Q64094998 | Cognition in Sensorimotor Control: Interfacing With the Posterior Parietal Cortex |
| Q48236882 | Combined adaptiveness of specific motor cortical ensembles underlies learning. |
| Q47837067 | Common and specific neural correlates underlying the spatial congruency effect induced by the egocentric and allocentric reference frame. |
| Q57176826 | Computational Principles of Supervised Learning in the Cerebellum |
| Q34461799 | Computational approaches to motor control |
| Q37735824 | Confidence and certainty: distinct probabilistic quantities for different goals |
| Q42561857 | Coordinate transformation approach to social interactions. |
| Q34175860 | Coordinate transformations for eye and arm movements in the brain |
| Q47931677 | Decoding sound level in the marmoset primary auditory cortex |
| Q47093677 | Detecting the relevance to performance of whole-body movements |
| Q39923811 | Differential Functionality of Right and Left Parietal Activity in Controlling a Motor Vehicle |
| Q35151536 | Dissociation of initial trajectory and final position errors during visuomotor adaptation following unilateral stroke |
| Q44225841 | Diverse coordinate frames on sensorimotor areas in visuomotor transformation |
| Q33708190 | Effects of task and coordinate frame of attention in area 7a of the primate posterior parietal cortex |
| Q51642792 | Efficient computation and cue integration with noisy population codes. |
| Q51899979 | Error generalization as a function of velocity and duration: human reaching movements. |
| Q37325398 | Eye-centered representation of optic flow tuning in the ventral intraparietal area |
| Q52003842 | Fast remapping of sensory stimuli onto motor actions on the basis of contextual modulation. |
| Q36533184 | Feedback-dependent generalization |
| Q36103267 | Flexible Reference Frames for Grasp Planning in Human Parietofrontal Cortex(1,2,3). |
| Q88102051 | Flexible egocentric and allocentric representations of heading signals in parietal cortex |
| Q30842974 | Flexible motor adjustment of pecking with an artificially extended bill in crows but not in pigeons. |
| Q34414847 | From artificial neural networks to spiking neuron populations and back again. |
| Q51908423 | From numerosity to ordinal rank: a gain-field model of serial order representation in cortical working memory. |
| Q30460825 | From sensorimotor inhibition to freudian repression: insights from psychosis applied to neurosis |
| Q34391231 | Generalization of stochastic visuomotor rotations |
| Q84624185 | Generalization of visuomotor adaptation to different muscles is less efficient: Experiment and model |
| Q29395920 | How Basal Ganglia Outputs Generate Behavior |
| Q46888526 | Human Posterior Parietal Cortex Flexibly Determines Reference Frames for Reaching Based on Sensory Context |
| Q48313766 | Human parietal "reach region" primarily encodes intrinsic visual direction, not extrinsic movement direction, in a visual motor dissociation task. |
| Q30494458 | Idiosyncratic and systematic aspects of spatial representations in the macaque parietal cortex |
| Q48220422 | Impaired visuomotor generalization by inconsistent attentional contexts |
| Q74291517 | Inner space: reference frames |
| Q28660740 | Interference and shaping in sensorimotor adaptations with rewards |
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| Q52016875 | Learning cross-modal spatial transformations through spike timing-dependent plasticity. |
| Q30484432 | Links from complex spikes to local plasticity and motor learning in the cerebellum of awake-behaving monkeys |
| Q44443301 | MSTd neuronal basis functions for the population encoding of heading direction |
| Q92480537 | Mechanisms underlying gain modulation in the cortex |
| Q48624252 | Mechanisms underlying spatial representation revealed through studies of hemispatial neglect |
| Q48860501 | Mixed Body/Hand Reference Frame for Reaching in 3D Space in Macaque Parietal Area PEc. |
| Q53833298 | Modeling spatial effects in visual-tactile saccadic reaction time. |
| Q28240873 | Motor adaptation to single force pulses: sensitive to direction but insensitive to within-movement pulse placement and magnitude |
| Q34308325 | Motor memory is encoded as a gain-field combination of intrinsic and extrinsic action representations |
| Q42123150 | Motor task variation induces structural learning |
| Q41993937 | Multimodal integration in rostral fastigial nucleus provides an estimate of body movement |
| Q48276867 | Multimodal spatial representations engaged in human parietal cortex during both saccadic and manual spatial orienting |
| Q38687458 | Multiple Coordinate Systems and Motor Strategies for Reaching Movements When Eye and Hand Are Dissociated in Depth and Direction |
| Q44645638 | Multiplicative Gain Changes Are Induced by Excitation or Inhibition Alone |
| Q51886849 | Multiplicative gain modulation arises through unsupervised learning in a predictive coding model of cortical function. |
| Q89442816 | Neural Mechanisms of High-Level Vision |
| Q89813677 | Neural coding of action in three dimensions: Task- and time-invariant reference frames for visuospatial and motor-related activity in parietal area V6A |
| Q93075075 | Neural correlates of sparse coding and dimensionality reduction |
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| Q37246442 | Neural model for learning-to-learn of novel task sets in the motor domain |
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| Q50682633 | New visuomotor maps are immediately available to the opposite limb. |
| Q78318958 | Noninformative vision improves haptic spatial perception |
| Q28253709 | Normalization as a canonical neural computation |
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| Q51099435 | Occam's Razor in sensorimotor learning. |
| Q35055660 | Online adaptation and over-trial learning in macaque visuomotor control |
| Q48595410 | Paying attention through eye movements: a computational investigation of the premotor theory of spatial attention |
| Q46263277 | Perceptual stability--going with the flow |
| Q92023677 | Position-theta-phase model of hippocampal place cell activity applied to quantification of running speed modulation of firing rate |
| Q47120099 | Predicting non-linear dynamics by stable local learning in a recurrent spiking neural network |
| Q48249578 | Preparatory activity in motor cortex reflects learning of local visuomotor skills |
| Q28274571 | Rapid reshaping of human motor generalization |
| Q37683550 | Recovering stimulus locations using populations of eye-position modulated neurons in dorsal and ventral visual streams of non-human primates |
| Q46738301 | Reference frames for reach planning in macaque dorsal premotor cortex |
| Q36794382 | Region-Specific Summation Patterns Inform the Role of Cortical Areas in Selecting Motor Plans |
| Q48579087 | Rule-dependent shifting of sensorimotor representation in the primate prefrontal cortex |
| Q60049102 | Self-organising coordinate transformation with peaked and monotonic gain modulation in the primate dorsal visual pathway |
| Q40061433 | Sensorimotor transformation via sparse coding |
| Q35991886 | Sensory integration for reaching: models of optimality in the context of behavior and the underlying neural circuits |
| Q30446065 | Shared action spaces: a basis function framework for social re-calibration of sensorimotor representations supporting joint action |
| Q33211414 | Short-term plasticity of the visuomotor map during grasping movements in humans |
| Q34345884 | Simulating the cortical 3D visuomotor transformation of reach depth |
| Q44338146 | Space coding for sensorimotor transformations can emerge through unsupervised learning |
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| Q34163414 | Spatial intuition in elementary arithmetic: a neurocomputational account |
| Q33378903 | Spatial modulation of primate inferotemporal responses by eye position |
| Q40453423 | Spatial transformations between superior colliculus visual and motor response fields during head-unrestrained gaze shifts. |
| Q30455204 | Spatiotemporal architecture of cortical receptive fields and its impact on multisensory interactions. |
| Q98565515 | Spatiotemporal transformations for gaze control |
| Q48493311 | Spikernels: predicting arm movements by embedding population spike rate patterns in inner-product spaces |
| Q97418246 | Spiking neurons with spatiotemporal dynamics and gain modulation for monolithically integrated memristive neural networks |
| Q31148590 | Spontaneous muscle twitches during sleep guide spinal self-organization. |
| Q30463814 | Steering by hearing: a bat's acoustic gaze is linked to its flight motor output by a delayed, adaptive linear law. |
| Q33528990 | Structure learning in a sensorimotor association task |
| Q46168204 | Target selection signals for arm reaching in the posterior parietal cortex. |
| Q41850327 | Target size matters: target errors contribute to the generalization of implicit visuomotor learning |
| Q37698167 | Temporal analysis of reference frames in parietal cortex area 5d during reach planning |
| Q48489758 | Temporal stability of reference frames in monkey area V6A during a reaching task in 3D space |
| Q36617022 | The "other" transformation required for visual-auditory integration: representational format |
| Q30359506 | The Role of Architectural and Learning Constraints in Neural Network Models: A Case Study on Visual Space Coding. |
| Q48545074 | The Structure and Acquisition of Sensorimotor Maps |
| Q43081068 | The advantage of flexible neuronal tunings in neural network models for motor learning |
| Q40265495 | The brain's router: a cortical network model of serial processing in the primate brain |
| Q30386158 | The dominance of haptics over audition in controlling wrist velocity during striking movements. |
| Q48626112 | The functional role of the cerebellum in visually guided tracking movement |
| Q50260554 | The influence of proprioceptive state on learning control of reach dynamics |
| Q36991186 | The neural basis of depth perception from motion parallax |
| Q36905062 | The postsaccadic unreliability of gain fields renders it unlikely that the motor system can use them to calculate target position in space |
| Q51896665 | The representation of perceived shape similarity and its role for category learning in monkeys: a modeling study. |
| Q35994770 | The representations of reach endpoints in posterior parietal cortex depend on which hand does the reaching |
| Q48492212 | The transcription factor DeltaFosB is recruited by inflammatory pain |
| Q36849719 | Theory of Connectivity: Nature and Nurture of Cell Assemblies and Cognitive Computation |
| Q91618628 | Timing Determines Tuning: A Rapid Spatial Transformation in Superior Colliculus Neurons during Reactive Gaze Shifts |
| Q36792829 | Transition from Target to Gaze Coding in Primate Frontal Eye Field during Memory Delay and Memory-Motor Transformation |
| Q36966346 | Trial-by-trial motor adaptation: a window into elemental neural computation. |
| Q28235501 | Trial-by-trial transformation of error into sensorimotor adaptation changes with environmental dynamics |
| Q33612616 | Using a compound gain field to compute a reach plan |
| Q48097256 | Visual remapping by vector subtraction: analysis of multiplicative gain field models. |
| Q36098832 | Visual-Motor Transformations Within Frontal Eye Fields During Head-Unrestrained Gaze Shifts in the Monkey. |
| Q36965165 | Visuomotor Map Determines How Visually Guided Reaching Movements are Corrected Within and Across Trials |
| Q51874874 | Visuospatial planning in the travelling salesperson problem: a connectionist account of normal and impaired performance. |
| Q40803057 | Where's Waldo? How perceptual, cognitive, and emotional brain processes cooperate during learning to categorize and find desired objects in a cluttered scene |
| Q42912687 | Which is the best intrinsic motivation signal for learning multiple skills? |
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