Neuroscience, Perception, Auditory cortex, Planum temporale and Functional magnetic resonance imaging are his primary areas of study. Human brain, Sensory system, Stimulus, Brain mapping and Functional imaging are among the areas of Neuroscience where the researcher is concentrating his efforts. His Perception research includes elements of Cognitive psychology, Auditory system and Cognitive science.
His Auditory cortex study incorporates themes from Speech recognition, Melody and Auditory perception. His Planum temporale course of study focuses on Acoustic space and Binaural recording, Monaural, Noise and Pattern recognition. As part of the same scientific family, Timothy D. Griffiths usually focuses on Functional magnetic resonance imaging, concentrating on Brainstem and intersecting with Thalamus.
Timothy D. Griffiths focuses on Neuroscience, Auditory cortex, Perception, Speech recognition and Audiology. His Auditory cortex research is multidisciplinary, incorporating elements of Auditory perception, Stimulus, Planum temporale, Magnetoencephalography and Brain mapping. His Planum temporale study combines topics in areas such as Gyrus and Superior temporal gyrus.
His Perception research integrates issues from Cognitive psychology, Auditory system and Sequence learning. His work deals with themes such as Communication, Musical instrument, Intraparietal sulcus, Auditory scene analysis and Psychophysics, which intersect with Speech recognition. His Audiology research incorporates elements of Amusia and Cognition.
Timothy D. Griffiths mostly deals with Neuroscience, Auditory cortex, Audiology, Perception and Hippocampus. His research integrates issues of Gyrus, Functional imaging, Neural substrate and Posterior parietal cortex in his study of Auditory cortex. His biological study spans a wide range of topics, including Lesion, Cognition, Aphasia and Psychoacoustics.
His studies deal with areas such as Rhythm and Auditory perception as well as Cognition. The various areas that Timothy D. Griffiths examines in his Perception study include Cognitive psychology, Sensory system, Background noise, Speech recognition and Functional magnetic resonance imaging. His work in Hippocampus addresses issues such as Semantic memory, which are connected to fields such as Neuropsychology.
His primary areas of study are Auditory cortex, Audiology, Neuroscience, Perception and Primate. The Auditory cortex study combines topics in areas such as Figure–ground, Cognitive psychology and Speech perception. His study in Audiology is interdisciplinary in nature, drawing from both Mismatch negativity, Cognition, Sensory system, Chronic pain and Temporal lobe.
As part of his studies on Neuroscience, he often connects relevant subjects like Broadband. His Perception study integrates concerns from other disciplines, such as Functional magnetic resonance imaging, Tinnitus, Neural substrate and Electroencephalography. His Local field potential research incorporates themes from Superior temporal gyrus, Electrophysiology, Stimulus, Planum temporale and Electrocorticography.
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The Processing of Temporal Pitch and Melody Information in Auditory Cortex
Roy D Patterson;Stefan Uppenkamp;Ingrid S Johnsrude;Timothy D Griffiths;Timothy D Griffiths.
The planum temporale as a computational hub
Timothy D Griffiths;Jason D Warren.
Trends in Neurosciences (2002)
What is an auditory object
Timothy D. Griffiths;Jason D. Warren.
Nature Reviews Neuroscience (2004)
Sensitivity to dynamic auditory and visual stimuli predicts nonword reading ability in both dyslexic and normal readers
C. Witton;J.B. Talcott;P.C. Hansen;A.J. Richardson.
Current Biology (1998)
Calcium overload in selectively vulnerable neurons of the hippocampus during and after ischemia: an electron microscopy study in the rat.
R. P. Simon;T. Griffiths;M. C. Evans;J. H. Swan.
Journal of Cerebral Blood Flow and Metabolism (1984)
Music and the brain: disorders of musical listening
Lauren Stewart;Katharina von Kriegstein;Jason D. Warren;Timothy D. Griffiths.
Analysis of temporal structure in sound by the human brain.
Timothy D. Griffiths;Timothy D. Griffiths;Christian Büchel;Richard S.J. Frackowiak;Roy D. Patterson.
Nature Neuroscience (1998)
Distinct neural substrates of duration-based and beat-based auditory timing.
Sundeep Teki;Manon Grube;Sukhbinder Kumar;Timothy D. Griffiths.
The Journal of Neuroscience (2011)
Properties of the Internal Clock: First- and Second-Order Principles of Subjective Time
Melissa J. Allman;Sundeep Teki;Timothy D. Griffiths;Warren H. Meck.
Annual Review of Psychology (2014)
Right parietal cortex is involved in the perception of sound movement in humans.
Timothy D. Griffiths;Geraint Rees;Adrian Rees;Gary G. R. Green.
Nature Neuroscience (1998)
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