| review article | Q7318358 |
| scholarly article | Q13442814 |
| P356 | DOI | 10.1016/0010-0277(90)90018-F |
| P698 | PubMed publication ID | 2269008 |
| P2093 | author name string | Church RM | |
| Broadbent HA | |||
| P433 | issue | 1-2 | |
| P304 | page(s) | 55-81 | |
| P577 | publication date | 1990-11-01 | |
| P1433 | published in | Cognition | Q15749512 |
| P1476 | title | Alternative representations of time, number, and rate | |
| P478 | volume | 37 |
| Q34558826 | 5-Hydroxytryptamine and interval timing behaviour |
| Q58797185 | A Population-Based Model of the Temporal Memory in the Hippocampus |
| Q52080325 | A model for neural representation of temporal duration. |
| Q47786744 | A scale-invariant internal representation of time |
| Q39688837 | A single mechanism account of duration and rate processing via the pacemaker-accumulator and beat frequency models |
| Q60723891 | Acquisition and extinction under periodic reinforcement |
| Q52042765 | Adult timing after preweaning shifts of Zeitgeber in rats: crossed sensitization to time? |
| Q93087907 | An Oscillator Ensemble Model of Sequence Learning |
| Q88015387 | Are separate theories of conditioning and timing necessary? |
| Q48047064 | Assessing the Approximate Number System: no relation between numerical comparison and estimation tasks |
| Q37619981 | Associative and temporal processes: a dual process approach |
| Q50496157 | Blocking by fixed and variable stimuli: Effects of stimulus distribution on blocking. |
| Q36983680 | CS-US temporal relations in blocking |
| Q33995464 | Carving the clock at its component joints: neural bases for interval timing |
| Q60147291 | Chapter 4 Application of a mode-control model of temporal integration to counting and timing behavior |
| Q35086288 | Chronometric studies of numerical cognition in five-month-old infants |
| Q72376955 | Controlled attention sharing influences time estimation |
| Q36963004 | Core systems in human cognition |
| Q30980076 | Data archiving in animal experimentation: merits, challenges, and a case study |
| Q35805035 | Developmental neuroscience of time and number: implications for autism and other neurodevelopmental disabilities |
| Q34482433 | Dissecting the clock: Understanding the mechanisms of timing across tasks and temporal intervals |
| Q34269922 | Duration comparison: relative stimulus differences stimulus age, and stimulus predictiveness |
| Q73918127 | ERPs and PET analysis of time perception: spatial and temporal brain mapping during visual discrimination tasks |
| Q51960475 | Episodic-like memory in rats: is it based on when or how long ago? |
| Q51860241 | From numerical concepts to concepts of number. |
| Q86952054 | How noise contributes to time-scale invariance of interval timing |
| Q34049266 | Individual differences in working memory capacity and temporal discrimination |
| Q37035667 | Intact interval timing in circadian CLOCK mutants. |
| Q37589293 | Interactions of timing and prediction error learning |
| Q34691354 | Intertrial interval as a contextual stimulus: further analysis of a novel asymmetry in temporal discrimination learning |
| Q47992042 | Interval Timing Is Preserved Despite Circadian Desynchrony in Rats: Constant Light and Heavy Water Studies |
| Q52101328 | Interval timing in mice does not rely upon the circadian pacemaker. |
| Q50999239 | Interval timing is intact in arrhythmic Cry1/Cry2-deficient mice. |
| Q51900862 | Is the growth of subjective time in humans a linear or nonlinear function of real time? |
| Q30385548 | Learning about the CS during latent inhibition: Preexposure enhances temporal control |
| Q37761833 | Learning to Time: a perspective |
| Q90289782 | Modeling Interval Timing by Recurrent Neural Nets |
| Q35228534 | Modeling pharmacological clock and memory patterns of interval timing in a striatal beat-frequency model with realistic, noisy neurons |
| Q26865864 | Motivation and timing: clues for modeling the reward system |
| Q39055173 | Multiple channels of visual time perception |
| Q73965773 | Nonlinear time perception |
| Q57723262 | Novel Inversions in Auditory Sequences Provide Evidence for Spontaneous Subtraction of Time and Number |
| Q48254033 | Number knows no bounds |
| Q45289711 | Numerosity discrimination in infants: evidence for two systems of representations |
| Q27350335 | Numerosity estimation in visual stimuli in the absence of luminance-based cues |
| Q35583207 | On the nature of CS and US representations in Pavlovian learning |
| Q28660860 | One, two, three, four, nothing more: an investigation of the conceptual sources of the verbal counting principles |
| Q24546194 | Operant conditioning |
| Q50635712 | Overshadowing by fixed- and variable-duration stimuli. |
| Q41789143 | Perceiving control over aversive and fearful events can alter how we experience those events: an investigation of time perception in spider-fearful individuals |
| Q44636401 | Phase resetting and its implications for interval timing with intruders |
| Q34330565 | Preferred rates of repetitive tapping and categorical time production |
| Q83371410 | Processing numerosity, length and duration in a three-dimensional Stroop-like task: towards a gradient of processing automaticity? |
| Q52230180 | Production of time intervals from segmented and nonsegmented inputs |
| Q51908571 | Ratio abstraction by 6-month-old infants. |
| Q36599128 | Scalar properties in animal timing: conformity and violations |
| Q47355483 | Spontaneous representations of small numbers of objects by rhesus macaques: examinations of content and format |
| Q50464904 | Superior ambiguous occasion setting with visual than temporal feature stimuli. |
| Q88015381 | Switching or gating? The attentional challenge in cognitive models of psychological time |
| Q52098694 | Temporal integration and temporal backward associations in human and nonhuman subjects |
| Q48097177 | The Timing of Reward-Seeking Action Tracks Visually Cued Theta Oscillations in Primary Visual Cortex. |
| Q51951637 | The construction of large number representations in adults. |
| Q35636771 | The impact of attention on judgments of frequency and duration |
| Q88015378 | The influence of the scalar timing model on human timing research |
| Q50485106 | The perception of empty and filled time intervals by pigeons. |
| Q41318622 | The representation of temporal information in perception and motor control |
| Q48618960 | The representations underlying infants' choice of more: object files versus analog magnitudes |
| Q56636499 | The role of numerical competence in a specialized predatory strategy of an araneophagic spider |
| Q52039342 | The start-stop procedure: estimation of temporal intervals by human subjects. |
| Q26999735 | Time-scale invariance as an emergent property in a perceptron with realistic, noisy neurons |
| Q88015391 | Timing behaviour of black-capped chickadees (Parus atricapillus) |
| Q41773804 | Timing in a variable interval procedure: evidence for a memory singularity |
| Q52098693 | Timing in retroactive interference |
| Q37775122 | Timing using temporal context |
| Q38113320 | Timing: an attribute of associative learning |
| Q41463755 | Toward a neurobiology of temporal cognition: advances and challenges. |
| Q47906398 | Towards a neural model of timing |
| Q48882394 | Tracking of the expected time to reinforcement in temporal conditioning procedures. |
| Q38838704 | True Numerical Cognition in the Wild |
| Q35585079 | Two systems of non-symbolic numerical cognition |
| Q35379888 | Unwinding the molecular basis of interval and circadian timing. |
| Q33781110 | Visual tracking combined with hand-tracking improves time perception of moving stimuli |
| Q43066553 | Watching the clock |
| Q37494488 | What is all the noise about in interval timing? |
| Q28272313 | What makes us tick? Functional and neural mechanisms of interval timing |
| Q34909047 | Why noise is useful in functional and neural mechanisms of interval timing? |
| Q28661236 | Why the verbal counting principles are constructed out of representations of small sets of individuals: a reply to Gallistel |
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