Functional and Neural Mechanisms of Interval TimingWarren H. Meck Understanding temporal integration by the brain is expected to be among the premier topics to unite systems, cellular, computational, and cognitive neuroscience over the next decade. The phenomenon has been studied in humans and animals, yet until now, there has been no publication to successfully bring together the latest information gathered from |
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... Macar, Ph.D. Center for Cognitive Neuroscience CNRS — 31 Chemin Joseph-Aiguier Marseille, France Kevin C.H. Pang, Ph.D. Department of Psychology Bowling Green State University Bowling Green, Ohio Christopher J. MacDonald, B.S. ...
... Macar, Ph.D. Center for Cognitive Neuroscience CNRS — 31 Chemin Joseph-Aiguier Marseille, France Kevin C.H. Pang, Ph.D. Department of Psychology Bowling Green State University Bowling Green, Ohio Christopher J. MacDonald, B.S. ...
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... R. Chris Miall Afterword Timing in the New Millenium: Where Are We Now?..........................................533 Françoise Macar Index..................................................................................................
... R. Chris Miall Afterword Timing in the New Millenium: Where Are We Now?..........................................533 Françoise Macar Index..................................................................................................
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... Macar et al., 1992; McAuley and Jones, 2002; Pressing, 1999; Rousseau and Rousseau, 1996). A classic example of interval timing comes from the fixed-interval (FI) procedure in which a subject is reinforced for the first response it ...
... Macar et al., 1992; McAuley and Jones, 2002; Pressing, 1999; Rousseau and Rousseau, 1996). A classic example of interval timing comes from the fixed-interval (FI) procedure in which a subject is reinforced for the first response it ...
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... (e.g., Casini and Macar, 1996a, 1996b, 1999; Pouthas, this volume). Identifying the ways in which attentional processes come under temporal control (and vice versa) xxii Functional and Neural Mechanisms of Interval Timing.
... (e.g., Casini and Macar, 1996a, 1996b, 1999; Pouthas, this volume). Identifying the ways in which attentional processes come under temporal control (and vice versa) xxii Functional and Neural Mechanisms of Interval Timing.
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... Macar et al., 1990; Monfort et al., 2000; Pouthas, this volume; Vidal et al., 1992). On the basis of their analysis of patients with cerebellar lesions of various etiology, Ivry and Keele (1989) and Keele and Ivry (1990) proposed that ...
... Macar et al., 1990; Monfort et al., 2000; Pouthas, this volume; Vidal et al., 1992). On the basis of their analysis of patients with cerebellar lesions of various etiology, Ivry and Keele (1989) and Keele and Ivry (1990) proposed that ...
Contents
3 | |
Timing without a Clock | 23 |
Implications for OscillatorBased Representations of Interval and Circadian Clocks | 61 |
4 Toward a Unified Theory of Animal Event Timing | 77 |
5 Interval Timing and Optimal Foraging | 113 |
6 Nonverbal Representations of Time and Number in Animals and Human Infants | 143 |
7 Temporal Experience and Timing in Children | 183 |
Attention Clock Speed and Memory | 209 |
13 Electrophysiological Correlates of Interval Timing | 339 |
14 Importance of Frontal Motor Cortex in Divided Attention and Simultaneous Temporal Processing | 351 |
Anatomically Separate Systems or Distributed Processing? | 371 |
CorticoStriatal Mechanisms of Interval Timing and Birdsong | 393 |
17 Neuroimaging Approaches to the Study of Interval Timing | 419 |
18 Electrophysiological Evidence for Specific Processing of Temporal Information in Humans | 439 |
19 Cerebellar and Basal Ganglia Contributions to Interval Timing | 457 |
From Empirical Data to Timing Theory | 485 |
9 Attentional TimeSharing in Interval Timing | 235 |
Attention and Interval Timing in Older Adults | 261 |
11 Neurogenetics of Interval Timing | 297 |
12 Dopaminergic Mechanisms of Interval Timing and Attention | 317 |
An Image of Human Neural Timing | 515 |
Afterword | 533 |
Index | 541 |
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