Interference between velocity-dependent and position-dependent force-fields indicates that tasks depending on different kinematic parameters compete for motor working memory
Bays P.M., Flanagan J.R., Wolpert D.M. Interference between velocity-dependent and position-dependent force-fields indicates that tasks depending on different kinematic parameters compete for motor working memory. Experimental Brain Research 2005, 163:400-405.
Human adaptation to rotated vision: Interplay of a continuous and a discrete process
Bock O., Abeele S., Eversheim U. Human adaptation to rotated vision: Interplay of a continuous and a discrete process. Experimental Brain Research 2003, 152:528-532.
Independent learning of internal models for kinematic and dynamic control of reaching
Krakauer J.W., Ghilardi M.F., Ghez C. Independent learning of internal models for kinematic and dynamic control of reaching. Nature Neuroscience 1999, 2:1026-1031.
Adaptation to rotated visual feedback: A re-examination of motor interference
Miall R.C., Jenkinson N., Kulkarni K. Adaptation to rotated visual feedback: A re-examination of motor interference. Experimental Brain Research 2004, 154:201-210.
Kinematics and dynamics are not represented independently in motor working memory: Evidence from an interference study
Tong C., Wolpert D.M., Flanagan J.R. Kinematics and dynamics are not represented independently in motor working memory: Evidence from an interference study. Journal of Neuroscience 2002, 22:1108-1113.
Visuomotor rotations of varying size and direction compete for a single internal model in motor working memory
Wigmore V., Tong C., Flanagan J.R. Visuomotor rotations of varying size and direction compete for a single internal model in motor working memory. Journal of Experimental Psychology: Human Perception and Performance 2002, 28:447-457.