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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Page xix
... suggest an equivalence of the ITI feedback effects and the types of pharmacological stimulation provided to ADD patients by drugs such as nicotine (see Levin et al., 1996, 1998). These findings also support the proposal that attentional ...
... suggest an equivalence of the ITI feedback effects and the types of pharmacological stimulation provided to ADD patients by drugs such as nicotine (see Levin et al., 1996, 1998). These findings also support the proposal that attentional ...
Page xxiii
... suggesting that the timing system is rapidly reset upon command (e.g., Pashler, 2001). It is also interesting to note that some researchers have argued that a primary function ... suggest different Introduction: The Persistence of Time xxiii.
... suggesting that the timing system is rapidly reset upon command (e.g., Pashler, 2001). It is also interesting to note that some researchers have argued that a primary function ... suggest different Introduction: The Persistence of Time xxiii.
Page xxiv
Warren H. Meck. between the ages of 3 and 51⁄2 and suggest different conceptualizations of time as a function of experience and maturation. Analog representations of stimulus magnitudes have also been explored using mode-control models ...
Warren H. Meck. between the ages of 3 and 51⁄2 and suggest different conceptualizations of time as a function of experience and maturation. Analog representations of stimulus magnitudes have also been explored using mode-control models ...
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... suggest that theta rhythm frequency in the frontal cortex serves as an indicator of the direction of the discrepancy in the content of temporal memory and that SDHACU amplitude in the frontal cortex serves as an indicator of the ...
... suggest that theta rhythm frequency in the frontal cortex serves as an indicator of the direction of the discrepancy in the content of temporal memory and that SDHACU amplitude in the frontal cortex serves as an indicator of the ...
Page xxx
... suggested by Lewis and Miall (this volume). Additional studies of central nervous system electrophysiology have ... suggest the involvement of these and other brain structures (e.g., frontal cortex, hippocampus, and cerebellum) in ...
... suggested by Lewis and Miall (this volume). Additional studies of central nervous system electrophysiology have ... suggest the involvement of these and other brain structures (e.g., frontal cortex, hippocampus, and cerebellum) in ...
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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