Learning of Visuomotor Transformations for Vectorial Planning of Reaching Trajectories

Gain learning. The last 8 movements of the baseline block are shown followed by 56 consecutive movements at gain 1.5. Each plot shows group data. A, Learning curve for gain training to a single target. B, Learning curve for gain training to eight targets. C, The relationship between mean movement extent and target distance at a gain of 1 (open circles) and a gain of 1.5 (filled circles). The dashed lines represent accurate performance at the two gains. The movement extents closely matched the target distances except for the smallest movements, which were somewhat hypermetric. D, The relationship between mean peak velocity and target distance. The outward trajectories had stereotypical single-peaked velocity profiles that scaled with target distance (inset). It may be noted that thelines fitting the peak velocities at the four target distances do not intercept the y-axis at zero. This was not investigated specifically but may represent either a range effect or an intrinsic nonlinearity in programming of small but rapidly rising force impulses (Gordon and Ghez, 1987).

Rotation learning. Learning was measured by the progressive reduction in the directional error at the peak velocity. The last 8 movements of the baseline block are shown followed by 56 consecutive movements with the 30° CCW rotation. Each plot shows group data. A, Learning curve for rotation learning to a single target. B, Learning curve for rotation learning to eight targets. C, Learning curves for rotation learning with single, four, and eight targets, plotted for the first 18 moves of the training block. D, Learning curves for rotation learning plotted for consecutive moves to a single target for single-, four-, and eight-target training.

Gain generalization across multiple target distances. A, Bottom, The plot is of mean (±SEM) group data showing the percent adaptation to untrained target distances relative to adaptation to the training targets. The data are collapsed for the four different training targets.Top, The four different training targets (circles) are shown in gray, and the testing targets are in white. On any given training day only one of the gray targets was trained to, and the remaining seven targets were used for testing. B, Mean peak velocity for the untrained targets is plotted against target distance in the two testing directions. C, Mean movement time for the untrained targets is plotted against target distance in the two testing directions.

Gain generalization across multiple directions after training in a single direction. Bottom, The plot is of mean (±SEM) group data showing the percent adaptation to untrained directions relative to the training target.Top, The gray targets show the four different target directions for 4 different training days. The testing targets are in white.

Rotation generalization. A, Generalization across multiple directions after training in a single direction. The directional data are relative to the training target.Bottom, The plot is of mean (±SEM) group data showing the percent adaptation to untrained directions relative to the training target. Top, The four different training directions (45, 135, 225, and 315°) for 4 different days are shown by the gray symbols. The positioning of the testing targets (in white) is shown. B, Generalization across multiple directions after training in one, two, four, and eight directions. Bottom, The plot is of mean (±SEM) group data showing the relative percent adaptation in the untrained directions relative to the trained directions. When there was more than one training target, the mean performance to all the training targets was used to calculate the relative adaptation in untrained directions. Data were collapsed for clockwise and counterclockwise directions.Top, Training targets are shown in gray, and testing targets are in white.

Rotation generalization across multiple target distances after training to a single distance of 7.2 cm. The plot shows mean (±SEM) group data of the percent adaptation to untrained distances 2.4, 4.8, and 9.6 cm relative to the training distance.Inset, The target array is shown with the training target in gray.

Schematic of experimental paradigm.A, Training configuration: shoulder at 45° and elbow at 90°. The arrows indicate the hand directions before and after adaptation with a 60° CCW rotation. B, Testing configuration: shoulder at 90° and elbow at 90°. Thelarge arrows in the test configuration indicate the predicted hand directions if adaptation were absent (top), if learning were in joint space (bottom), or if learning were in extrinsic space (middle). The smaller filled arrows show the actual mean movement direction for each subject. C, Cumulative histogram of the direction of all movements to the 45° target for all subjects in the training configuration. D, Cumulative histogram of the direction of all movements to the 45° target direction for all subjects in the testing configuration.