University Relations
http://www.umn.edu/urelate
612-624-6868

Audrey Royer
Research Interests
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Education
- M.S. Biomedical Engineering, University of Michigan, 2002
- B.S.E. Electrical Engineering, University of Michigan, 2001
Honors and Awards
- NIH Integrative Neuroimaging Graduate Training Fellowship, 2008-2009
- NIH Neuro-physical-computational Sciences (NPCS) Graduate Training Fellowship, 2006-2008
- Morris Smithberg Award, 2006
- Graduate Fellow, 2005 - 2006
- Guidant Foundation Scholarship, 2001-2002
- Senior Scholar of the Electrical Engineering Department, 2001
- James B. Angell Scholar, 2001
- Schlumberger Collegiate Award Scholarship, 2000-2001
- Junior Scholar of the Electrical Engineering Department, 2000
- William M. Seeley Award, 2000
Selected Publications
- Royer AS and He B. Goal selection versus process control in a brain–computer interface based on sensorimotor rhythms. J. Neural Eng. 2009 6(1):016005.
- Royer AS, Miller RF. Dendritic impulse collisions and shifting sites of action potential initiation contract and extend the receptive field of an amacrine cell. Vis Neurosci. 2007 24(4):619-34.
- Royer AS, Doud AJ, Rose ML, and He B. EEG Control of a Virtual Helicopter in 3-Dimensional Space Using Intelligent Control Strategies. IEEE Trans Neural Syst Rehabil Eng. 2010 18(6):581-9.
- Royer AS, Rose ML, and He B. Goal Selection vs. Process Control while Learning to Use a Brain-Computer Interface. J Neural Eng. 2011 8(3):036012.
- Royer AS, Doud AJ, Rose ML, He B. EEG Control of a Virtual Helicopter in 3-Dimensional Space Using Intelligent Control Strategies. IEEE Trans Neural Syst Rehabil Eng. 2010 Sep 27. [Epub ahead of print]
- Royer AS, McCullough A, He B.A sensorimotor rhythm based goal selection brain-computer interface. Conf Proc IEEE Eng Med Biol Soc. 2009;2009:575-7
- Royer AS, He B. Goal selection versus process control in a brain-computer interface based on sensorimotor rhythms. J Neural Eng. 2009 Feb;6(1):016005
- Royer AS, Miller RF. Dendritic impulse collisions and shifting sites of action potential initiation contract and extend the receptive field of an amacrine cell. Vis Neurosci. 2007 Jul-Aug;24(4):619-34