The law relating the kinematic and figural aspects of drawing movements

doi:10.1016/0001-6918(83)90027-6

Acta Psychologica

Volume 54, Issues 1–3, October 1983, Pages 115-130

https://doi.org/10.1016/0001-6918(83)90027-6 Get rights and content

Abstract

Considerable evidence exists that the velocity of execution of handwriting and drawing movements depends on some global metric properties of the movement (size, linear extent etc.). Recent experiments have demonstrated that the instantaneous velocity also depends on the local curvature of the trajectory, that is, on the differential geometrical properties of the movement. In this paper we investigate further the role of the differential factors. Experiments are described in which drawing movements of simple geometrical forms and scribbles are performed either freely and extemporaneously, or in the presence of external constraints. It is shown that, at any time during the movement, the velocity component related to differential factors only depends on the value of the curvature of the trajectory at the same time (no dynamics). The relation can be described quantitatively as a specific Power Law and applies to all movements considered here, including those which are performed by following the edge of a template. The fact that the velocity of execution increases with the radius of curvature implies a built-in tendency of the motor control system to keep angular velocity relatively constant and qualifies the Isogony Principle proposed previously. The specific exponent of the Power Law suggests a possible interpretation of this empirical relation.

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^☆: The experiments reported in this paper were conducted by the authors at the three Institutions listed. We express our gratitude to P. Panchyshyn and M. Ehrette for skillfully preparing the templates and to U. De Giovanni and M.G. Orlando for artwork and typing. The work was supported by CNRS A 650–5169 and USPHS NS-15018 Research Grants, and by the CNR.

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The law relating the kinematic and figural aspects of drawing movements☆

Abstract

Neuroscience

The co-ordination and regulation of movements

The guiding of human writing movements

Kybernetik

The information capacity of the human motor system in controlling the amplitude of the movement

Journal of Experimental Psychology

Problems of organization of motor systems

Progresses in Theoretical Biology