Circle-Drawing Movements at Different Speeds: Role of Inertial Anisotropy

doi:10.1152/jn.00946.2001

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Circle-Drawing Movements at Different Speeds: Role of Inertial Anisotropy

Kerstin D. Pfann,¹ Daniel M. Corcos,¹^,²^,³^,⁴ Charity G. Moore,⁵ and Ziaul Hasan¹^,³

¹School of Kinesiology (MC 194) and ²Department of Psychology, University of Illinois at Chicago, 60608; ³Department of Physical Therapy (MC 898), University of Illinois at Chicago, 60612; ⁴Department of Neurological Sciences, Rush Presbyterian-St. Luke's Medical Center, Chicago, Illinois 60612; and ⁵Department of Epidemiology and Biostatistics, Norman J. Arnold School of Public Health, University of South Carolina, Columbia, South Carolina 29208

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Pfann, Kerstin D., Daniel M. Corcos, Charity G. Moore, and Ziaul Hasan. Circle-Drawing Movements at Different Speeds: Role of Inertial Anisotropy. J. Neurophysiol. 88: 2399-2407, 2002. This study investigated the role of inertial anisotropy at the hand in causing distortions in movement. Subjects drew circlesin the horizontal plane at four locations in the workspace atthree instructed paces using elbow and shoulder movements. Specifically,we tested two hypotheses, which we would expect if the anisotropyof inertia were not completely accounted for by the CNS when generatingcircle-drawing movements: 1) speed will affect the circularityof figures, with faster movements associated with greater elongationinto an oval shape, irrespective of workspace location for configurationswith a similar angle between the forearm and upper arm. 2) Theelongation of the circle at fast speeds will be in the directionof least inertia. The results showed that despite individual differencesin the speed dependence of the relative motions at the elbow andthe shoulder, the circularity decreased (distortion increased)with increased speed, and workspace location had no effect oncircularity. We also found that the elongation of the circlesat fast speeds was in a direction close to but significantly differentfrom the direction of least inertia for three workspace locationsand was in the direction of least inertia for the fourth location.We suggest that the elongation results from lack of full accountingby the CNS of the anisotropy of viscosity andinertia.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

It is generally recognized that the mechanical properties of a limb play a significant role in transforming the motor outputof the CNS into a limb movement. The mechanical properties ofa multi-jointed limb can be quite complex. For example, if theupper arm and forearm are free to move, the stiffness, viscosity,and inertia at the hand each vary systematically with the directionof imposed motion, i.e., they are anisotropic (Hogan 1985; Mussa-Ivaldiet al. 1985; Tsuji et al. 1995). Considerable attention has beengiven to the importance of the anisotropy of stiffness $---$ usuallyrepresented by a stiffness ellipse $---$ in the context of the equilibrium-pointhypothesis (e.g., Gomi and Kawato 1997; Shadmehr et al. 1993).Viscous and inertial anisotropies have been investigated to alesser extent (Lacquaniti et al. 1993; Tsuji et al. 1995), althoughthe importance of inertial anisotropy in the control of target-reachingmovements has been shown by Gordon et al. (1994).

Whereas elastic and viscous anisotropies have their origin largely in the mechanical properties and arrangement of the muscles,inertial anisotropy reflects the relative involvement of the armsegments for hand movements in different directions. For example,when the elbow angle is near 90° and hand movement is in a directionperpendicular to the forearm, there is little movement of theupper arm segment, and therefore only the inertia of the forearmand hand matters, whereas a greater inertia comes into play whenmoving the hand in a direction for which there is considerablemotion of the upper arm as well. That the inertia is of greatersignificance at higher speeds can be seen by comparing the requirementsfor producing the same movement at two different speeds: for example,for a system in which stiffness, viscosity, and inertia are constant,if the movement is to be performed at five times the speed, andthus in 1/5 of the time, the time course of each of the torquecomponents would be speeded up by a factor of 5, and the magnitudesof the joint torques required to counter the stiffness, viscosity,and inertia would increase by factors of 1, 5, and 25, respectively.[As for the different inertial terms in the equations of motionrelated to the angular accelerations and to squares and productsof angular velocities, they would each increase by a factor of25 (Hollerbach and Flash 1982)]. Thus inertial anisotropy wouldplay an increasingly important role compared with viscous andelastic anisotropies as the speed of movementincreases.

Our general aim is to investigate the possible role of inertial anisotropy in causing errors or distortions in movement; thiswould provide insight into the extent to which motor planningdoes or does not take account of this mechanical property of thelimb. Gordon et al. (1994) have demonstrated a lack of accountingfor inertial anisotropy in the initiation of quick voluntary,target-reaching movements of the hand. The movements were performedin the absence of on-line visual feedback, and the targets wereat the same distance but in different directions in the horizontalplane. The peak acceleration and velocity were found to vary systematicallywith direction, being largest for the direction of least inertiaand smallest for the direction of greatest inertia. This suggeststhat the motor plan for launching the movement does not compensatefor inertial anisotropy. Similar results have been obtained inmonkeys who were allowed full vision: at least part of the directionalvariation in speed could be explained by inertial anisotropy (Turneret al. 1995).

Although the directional tuning of primary motor cortex cells is modified by the application of external forces (Kalaska etal.1989; Li et al. 2001), it is not known whether the motor planat the cortical level takes account of the internal forces associatedwith inertial anisotropy. It has been shown that there is a nonuniformdistribution of preferred directions of primary motor cortex cellsthat is correlated with joint power (Scott et al. 2001), a variablethat reflects the effects of both the inertial anisotropy of thelimb and the force-velocity relationship of contracting muscles.However, no study has shown a modulation of cell discharge thatreflects inertialanisotropy.

If inertial anisotropy was ignored by the CNS in generating the motor output, one would expect that the movement directionwould tend to veer toward the direction of least inertia. Although,as shown by Gordon et al. (1994), the resulting inaccuracy isquickly corrected in discrete, point-to-point movements, it isnot known whether the same is true when a subject attempts tofollow a curved path, for which the desired direction of movementvaries continuously. In the case of a curved path, the directionof the acceleration must change continuously, thereby engaginga changing effective inertia. In particular, the attempt to drawa circle without accounting for inertial anisotropy would be expectedto result in a figure elongated along the direction of least inertia.When subjects succeed in drawing circles that do not exhibit suchelongation, they must either compensate for inertial anisotropythrough prior planning and/or feedback corrections (Verschuerenet al. 1999) or slow down sufficiently so that inertial effectsbecome relatively unimportant. By asking subjects to draw circlesat progressively faster speeds, one expects to see increasingdistortion in the form of elongation along the direction of leastinertia if inertial anisotropy is not fully compensated. In thepresent report, we focus on such movements, which have the additionaladvantage of being reasonably familiar to thesubjects.

Several studies of circle-drawing movements have reported distortions in the presence of full vision, but they have not attributedthe distortions to inertial effects. Using three-dimensional forearmand upper arm motions, Soechting et al. (1986) observed systematicdistortions in shape for large circles (ca. 30 cm diam) drawnfreehand at relatively slow, self-determined frequencies (0.7-1.2Hz). The distortions were attributed to inaccuracies in the mappingbetween the desired extrinsic, trajectory parameters and intrinsic,joint angle parameters (Soechting and Terzuolo 1986). If the distortionsarise due to a linearization of the extrinsic-to-intrinsic mapping,as these authors argue, then the distortion should be considerablyless for smaller circles. Moreover, distortions due to such amapping inaccuracy, because they arise prior to any decisionsconcerning movement dynamics, should be independent of speed.In contrast, distortions due to inertial effects should be morepronounced at higher speeds. Indeed, Dounskaia et al. (2000) reportincreased elongation of circles into ovals as the drawing frequencywas increased in steps over the range of approximately 1-5.3 Hz.Their subjects drew small (ca. 2.5 cm) circles in the horizontalplane with an inkless pen using wrist and finger movements whilethe forearm was immobilized. Because of the many kinematic degreesof freedom in the situation in which a pen is grasped in the fingersand the palm, it is not possible to determine whether the directionof elongation coincided with the direction of leastinertia.

We studied circle-drawing movements at different speeds with full vision and with forearm and upper arm motions as the twoavailable degrees of freedom in the horizontal plane. Becauseof the possibility that distortions in shape could arise fromdifferences in the control of movements in different regions ofthe workspace, as has been shown for arm positioning and pointingtasks (e.g., Imanaka et al. 1995), circles drawn at differentworkspace locations were investigated. The purpose of the studywas to test the idea that the distortions observed in circlesdrawn by neurologically normal subjects are consistent with thoseexpected if the anisotropic nature of the inertia is not completelyaccounted for when generating themovement.

The following specific hypotheses were tested. Hypothesis 1: speed will affect the circularity of figures drawn by elbow andshoulder movements (as has previously been shown for wrist andfinger movements) with faster movements associated with greaterelongation into an oval shape; however, for comparable anglesbetween the forearm and the upper arm, the position in the workspacewill not affect the circularity of the figures. Hypothesis 2:the orientation of elongation of circles drawn at high speed willcorrespond to the direction of least inertia. The latter can bepredicted on the basis of the inertial characteristics, i.e.,mass and moment of inertia, of the arm segments. The expectationis that the orientation of the elliptical figures drawn at highspeed will vary with workspace location, so that the long axiscoincides with the direction of least inertia. In addition totesting these two hypotheses, which pertain to extrinsic spacecoordinates, we also investigated the amplitude and phase relationsamong the two joint angles (elbow and shoulder). Some of the findingshave appeared previously in abstract form (Pfann et al. 2001).

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Six subjects were recruited for this study (4 male, 2 female; ages 22-41), who gave their informed consent in accordance withlocal Institutional Review Board guidelines. All subjects werefree from known neurological or musculoskeletal abnormalitiesand were right handed. The basic task that subjects performedwas to draw circles repetitively in the horizontal plane withthe right hand near specified locations and at different speeds,using rotations at the shoulder and elbowjoints.

Apparatus

A splint was fitted to the seated subject's right forearm and hand to immobilize the wrist with the index finger extended.The arm was supported in the horizontal plane by two plastic pylons,one under the forearm, and the other under the upper arm, whichwere free to slide on a table with a smooth surface. To minimizefriction, the supporting pylons were floated just above the tablesurface by a continuous flow of compressed air (Karst and Hasan1991). The forearm was maintained in a neutral position. A transparentpointer was attached to the base of the forearm support, slightlyabove the plane of the table, whose direction was aligned withthe forearm and index finger. A black dot on the pointer was placedvertically below the tip of the index finger, whose movementstherefore reflected the fingertip movements. This dot was usedby the subject as the marker for circle drawing; it did not producea trace of the movementpath.

A Selspot active marker system with two cameras was used to record kinematic data. Pairs of infrared light-emitting diodes(LEDs) were placed along the long axes of the upper arm and forearm.Another pair, placed on the upper trunk, consisted of one LEDon the right shoulder (acromion), and one along the axis betweenthe right and left shoulders. The duration of the trial and samplingfrequency was varied with the pace instruction so as to allowmore than one cycle of circle-drawing movements to be recorded.The slow-pace trials were recorded for 6 s at a sampling frequencyof 100 Hz, and the moderate- and fast-pace trials were recordedfor 4 s at a sampling frequency of 200Hz.

The subject's height, weight, age, gender, and limb segment lengths were recorded. Based on the anthropometric parameters,the limb segment masses, center of mass locations, and momentsof inertia were estimated (Plagenhoef et al.1983). The positionsof the LEDs on each limb segment were recorded with respect tothe proximal and distaljoints.

Protocol

Subjects drew circles repetitively with eyes open with three instructions concerning the pace and at four locations in theworkspace. Prior to every trial, a circle of 5 cm diam was shownto the subject to indicate the size of the desired circles. Wedid not provide a template of a circle to the subject during thedrawing task because tracing the template could have obscuredthe distortions we wished to study; moreover, Zelaznik and Lantero(1996) have shown that visual feedback does not serve as a sourceof form in circle drawing. For each trial, the subject was askedto start drawing circles continuously at the prescribed pace ina counterclockwise direction about the desired center point, whichwas marked by a dot on the table. Data acquisition was startedafter a few cycles, when the subject indicated his/her readinessverbally. Subjects were asked to continue drawing circles untilthe experimenter asked them to stop, 4 or 6 s later, at the endof thetrial.

Three different instructions were given concerning the pace: as slow as necessary to draw perfect circles, at a moderate speed,and very fast. Subjects were free to interpret these instructionsin terms of actual speed as knowledge of results was not provided.The frequency of cyclical circle-drawing movements ranged acrosssubjects between 0.22 and 1.1 Hz (mean: 0.7 Hz) for the slow instruction,between 0.83 and 5.3 Hz (mean: 1.8 Hz) for the moderate speedinstruction, and between 1.7 and 6.5 Hz (mean: 4.3 Hz) for thevery fast instruction. Circles were drawn at all three paces ina fixed order (fast, moderate, slow) before changing locations.Twelve trials were recorded at each location $---$ one with no movement,three fast paced, four moderate paced, and four slowpaced.

Four different locations of the desired center of the circle were chosen to cover a significant range of the workspace inthe horizontal plane. For three of the four locations, the elbowangle was in midrange (ca. 90°), with the center placed in theright (R), middle (M) or left (L) portion of the workspace. Thesedesired locations, for which the fingertip was at approximatelythe same distance from the right shoulder, were defined with theshoulder horizontally abducted for R, adducted by 45° for M, and90° for L, but the actual mean shoulder angles deviated from thesevalues. These locations were chosen to span a range of the workspacewhile maintaining a similar extent of inertial anisotropy (asmeasured by the ratio of the effective inertias in the directionsof greatest and least inertia), and therefore an expected similareffect of speed on circularity. The fourth location (E) was definedby a more extended elbow (bent 45° from full extension), withthe shoulder adducted by 90°. The desired center for locationE was therefore at a greater distance from the shoulder than forthe other locations. This location was chosen not only to encompassa wider range of the workspace, but also because it was expectedthat the inertial anisotropy, as measured by the ratio of theeffective inertias in the directions of greatest and least inertia,would be different with a more extended elbow compared with itsvalue for the other three locations. The order in which the locationswere presented was the same for all subjects (R, M, L,E).

Data analysis

The horizontal-plane orientations of the forearm, upper arm, and trunk were determined from the positions of the respectivepairs of LED markers. From these orientations, the shoulder andelbow angles were determined as functions of time. The subjects,despite being strapped to the chair, often did not keep the trunkat the desired orientation in space, therefore the mean shoulderangle did not correspond to the location-specific desired value.This resulted in a smaller range of shoulder angles across thedifferent workspace locations than was anticipated. To obtaina true indication of location in an egocentric frame of reference,the forearm and upper arm orientations (such as those shown inFig. 1) were referenced to the trunk orientation, the latter beingdetermined from the pair of LEDs placed on the upper trunk. Weadopted the convention that the lateral (x axis) direction, definedby the trunk LEDs, corresponds to zero degree, and counterclockwiserotations (i.e., flexions) in the horizontal plane to positivevalues. Zero degree for the shoulder corresponds to the upperarm being oriented laterally, and for the elbow, to full extension.

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Fig. 1. Representative trials of circles drawn by a subject (S4) at different locations in the workspace at a slow pace (A) and at a fast pace (B). For each of the 4 workspace locations [right (R), middle (M), left (L), and extended (E)], the circles drawn are shown along with the mean forearm and upper arm orientations, which are depicted by the stick figures. The x and y axes correspond respectively to the lateral and anterior directions referenced to the upper trunk, with (0, 0) corresponding to the acromion. In B, the direction of least inertia is also shown (thin lines) for each location, for comparison with the orientation of the elliptical figures actually drawn at the fast pace.

The sampled positions of the two forearm LEDs, and the distances between them and the fingertip, were used to calculate fingertipposition in Cartesian coordinates as a function of time as wellas shoulder and elbow angle position in joint angle coordinates.Time-domain smoothing with a least-squares filter $---$ Savitzky-Golay,2nd degree, with 10 neighboring points on each side (Press etal. 1992) $---$ was employed; this also yielded the fingertip velocitycomponents. These time-series data were partitioned into individualcycles based on zero crossings of the velocity component in anarbitrarily chosen direction; incomplete cycles at the beginningor end of a trial were discarded. To avoid contamination by theeffects of the drift in center position that often occurred duringthe cyclical movements, each cycle was analyzed separately. Theparameters p₁-p₅ were estimated for the equation of the ellipse

<IT>x</IT>2<IT>+</IT><IT>p</IT>1<IT>xy</IT><IT>+</IT><IT>p</IT>2<IT>y</IT>2<IT>+</IT><IT>p</IT>3<IT>x</IT><IT>+</IT><IT>p</IT>4<IT>y</IT><IT>+</IT><IT>p</IT>5<IT>=0</IT> (1)

by minimizing the sum of squares of the left hand side of Eq. 1 over all data points (x_i, y_i) in the cycle. The "fmins" algorithmin Matlab 5.2 yielded the best values of p₁-p₅. In addition, theaverage movement speed over the cycle was calculated. In threecycles of a total of 1,551, the path was qualitatively nonelliptical(e.g., a figure 8); these werediscarded.

DIRECTION OF LEAST INERTIA. This was computed following the method of Lacquaniti et al. (1993) and Sabes and Jordan (1997). The procedure can be summarizedas follows. The 2 × 2 inertia matrix, which relates the torquesat the two joints to the angular accelerations of the two segments,was determined using the segment inertial parameters for the subjectand the mean elbow angle for the given trial. The 2 × 2 Jacobianmatrix, which relates increments in the Cartesian coordinatesof the hand to increments in the segment angles, was also calculated,using the mean joint angles for the trial. The inertia matrixwas then transformed, using the Jacobian, into a matrix that relatesthe force components to the acceleration components at the handin Cartesian coordinates (Lacquaniti et al. 1993). The inverseof this matrix represents the "endpoint mobility tensor" (seeAPPENDIX IV in Hogan 1985). Its eigenvalues represent the reciprocalsof the smallest and largest effective inertia at the hand. Thecorresponding eigenvectors represent the two mutually orthogonaldirections of least and mostinertia.

The direction of least inertia so calculated was quite close to the direction of the perpendicular to the forearm. With respectto the perpendicular, the least inertia direction varied between $-$ 3.1 and 2.5° (mean = $-$ 0.1°) across the subjects for locationswith comparable elbow angles (R, M, and L). Positive values denotea more counterclockwise orientation as seen from above. The correspondingeffective inertia at the hand varied between 0.30 and 0.45 kg(mean = 0.42 kg). To assess the anisotropy of inertia, this maybe compared with values ranging from 1.9 to 2.8 kg (mean = 2.5kg) for the direction of greatest inertia. The ratio of the greatestinertia to the least inertia varied between 5.6 and 7.2 (mean= 6.1). For location E, the least inertia direction with respectto the forearm perpendicular varied between $-$ 3.6 and 4.1° (mean= 2.6°), the least inertia between 0.30 and 0.44 kg (mean = 0.39kg), and the greatest inertia between 1.9 and 3.5 kg (mean = 2.9kg). The ratio of the greatest inertia to the least inertia variedbetween 6.3 and 8.1 (mean = 7.3) for thislocation.

We also determined, for each cycle, the ratio of the peak-to-peak excursions of the elbow and shoulder angles, as well asthe phase difference between the waveforms of the two angles.The phase was calculated as follows. The best-fit ellipse wasdetermined for the observed relationship between the shoulderand elbow angles using the same analytical method as describedearlier for fitting the ellipse to the fingertip path, but afterreplacing x by the shoulder angle and y by the elbow angle. Comparingthe parameters (p₁-p₅) of the equation of this ellipse with thatof an ellipse generated by sinusoidal changes in the two angles,the phase of the elbow with respect to the shoulder was determinedfrom

phase=cos<SUP>−1</SUP> {−<IT>p</IT><SUB><IT>1</IT></SUB><IT>&cjs0823; </IT>[<IT>2sqrt</IT>(<IT>p</IT><SUB><IT>2</IT></SUB>)]<IT>}</IT>

The sign ambiguity of the phase angle as determined from the inverse cosine function was resolved by an automated procedurethat compared the observed elbow angle during a cycle with theelbow sinusoids calculated using both possible signs of the phase.The phase was found to be negative in all but 2 of the 1,548 cyclesanalyzed.

VARIABLES ANALYZED. Pertaining to extrinsic space coordinates. Location: a categorical variable with four values (R, M, L, and E). Speed: mean fingertip speed (cm/s) over a movement cycle.Circularity: the ratio of the length of the minor axis to thelength of the major axis of the best-fitting ellipse for fingertipmotion over a cycle. The possible range of this ratio is between0.0 (a straight line) and 1.0 (a perfect circle). Orientation:the orientation of the major axis of the best-fitting ellipsefor a cycle with respect to a fixed direction in the workspace.The fixed direction was the rightward lateral direction definedby the pair of LEDs placed on the trunk. The orientation measurewas meaningful only when the circularity was not close to 1.0,and, in light of the circularity data, it was analyzed only forthe fast pace trials. Relative orientation: this was defined forthe fast-pace trials as the orientation of the major axis of thebest-fitting ellipse for a cycle, relative to the direction ofleastinertia.

Pertaining to intrinsic joint coordinates. Elbow/shoulder ratio: the ratio of the peak-to-peak excursions of the elbow and shoulder angles over a cycle. Phase: the phasedifference between the motion of the elbow and the motion of theshoulder. A negative value represents a phase lag of the elbowmotion with respect to the shouldermotion.

STATISTICAL ANALYSES. Mixed models (Brown and Prescott 1999) were used to investigate the following: the effects of location and instructed paceon speed, the effects of speed and location on circularity, elbow/shoulderratio, and phase, and the effects of location on orientation andon relative orientation. For the relative orientation, we alsotested the deviation of its values from zero. These models accountedfor correlations among observations within the same subject andsubject variability from the fixed effects in the models. Allmodels controlled for trial and cycle regardless ofsignificance.

Data transformations were applied to two of the dependent variables to approximate a more normal distribution and to stabilizevariances for modeling purposes. The circularity measure (C) wastransformed using the logit transformation Y = ln [C/(1 $-$ C)].This transformation insured that model based predicted valuesof C were within [0, 1] range (Ratnaparkhi and Mosimann 1990

).Descriptive statistics (means and variances) of C showed increasingvariability as the pace increased but no trend across location.After taking the logit transformation, the new measure Y showedapproximately equal variances across instructed pace and acrosslocation. The natural logarithm transformation was applied tothe elbow/shoulder excursion ratio originally having a right-skeweddistribution. The transformed ratio was approximately symmetricbased on a normal probabilityplot.

All tests were two-sided using a type I error rate of 0.05. Bonferroni procedures were used for pairwise comparisons to protectthe overall error rate. All statistical analyses were performedin SAS version 6.12 (SAS Institute, Cary,NC).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Speed

The three instructions concerning the pace (slow, moderate, and fast) resulted in significantly different actual speeds ofmovement [13.0 ± 4.0, 35.1 ± 9.9, and 72.5 ± 15.0 (SD) cm/s, respectively;F(2,10) = 88.97, P < 0.0001]. There was no significant effectof workspace location on speed [F(3,15) = 0.30, P = 0.83].

Circularity

Figure 1A shows the circles drawn by a subject with the instruction to move slowly. Four trials are shown at the differentlocations in the workspace. Stick figures of the arm depict themean orientations of the forearm and upper arm segments for eachtrial. The circles drawn were not perfect, but comparing themwith the attempted circles drawn by the same subject under thefast instruction, shown in Fig. 1B, it is clear that the drawingsmade more rapidly departed much more from circularity. Moreover,at each location in the workspace, the distortion of the rapidlydrawn circles took the form of a relative elongation in one directionand a relative shortening along the orthogonal direction. Theorientation of the direction of elongation varied with the locationin the workspace. For comparison with the direction of elongation,Fig. 1B also shows the computed direction of least inertia foreach of the depicted trials. As workspace location varies, theorientation of the axis of elongation appears to vary similarlyto the orientation of the direction of leastinertia.

The impression given by Fig. 1, that the circularity decreases (distortion increases) with faster speeds, is confirmed bystatistical analysis. A mixed model was used for the logit transformedcircularity measure (see METHODS), in which the effects of meancycle speed (continuous variable) and workspace location (categoricalvariable) were examined. The analysis showed that mean cycle speedhad a statistically significant effect on circularity [F(1,5)= 127.61, P < 0.0001]. There was no statistically significanteffect of workspace location [F(3,15) = 0.19, P = 0.90].

Figure 2 shows, for all the cycles in our data set, the circularity measure plotted against the mean speed. The trend of therelationship is brought out more clearly by the plot of the predictedcircularity based on the statistical model, controlling for configuration,trial, and cycle number, shown by diamonds. Clearly, irrespectiveof workspace location, nearly circular forms are drawn at slowspeeds (1 represents a perfect circle), and as speed increasesthe circle elongates (0 represents a straight line), as was hypothesized.

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Fig. 2. The dependence of circularity on speed. Individual cycle data are shown (

), for all the subjects, pace instructions, and locations in workspace. Instead of a regression line, which would be inappropriate for the curvilinear relationship exhibited by the data, the estimates of circularity based on the statistical model described in METHODS are shown (diamonds). The values correspond to the inverse logit transform of the predicted values stemming from significant components of the model.

Orientation of the major axis in fast trials

In Fig. 1B, the orientation of the long axis of the elongated circles appears to become more counterclockwise as the workspaceis traversed from right to left. Figure 3A shows, for the differentlocations, the mean values (and model based standard errors) ofthe orientation of the major axis of the fitted ellipse with respectto the rightward lateral axis; positive values denote counterclockwiseorientations with respect to this axis. The effect of workspacelocation was statistically significant [F(3,15) = 26.03, P < 0.0001].Pairwise comparisons among the locations were all statisticallysignificant except the difference between the orientations atlocations M and E.

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Fig. 3. Dependence of the orientation of the major axis of the best-fitting ellipse on location in workspace. The mean parameter estimates and SE bars are shown based on 1-way ANOVAs for the fast movements. A: absolute orientation with respect to a fixed (rightward lateral) axis. B: relative orientation with respect to the direction of least inertia.

Relative orientation of the major axis in fast trials

Figure 3B shows the mean values and standard errors of the orientation of the long axis relative to the direction of leastinertia. The estimated means range over less than 15° for thedifferent workspace locations, suggesting that the long axis isfairly closely fixed relative to the direction of least inertia.The effect of workspace location on the orientation relative tothe direction of least inertia, however, was statistically significant[F(3,15) = 25.55, P < 0.0001]. Pairwise comparisons revealed thatthe relative orientations at locations R, M, and L were each significantlydifferent (P < 0.0001) only from the relative orientation at locationE. (Subject S5 exhibited relative orientation values quite discrepantfrom the group means. Discarding the data for S5, however, didnot alter the conclusion: The effect of location on the relativeorientation remained significant, with location E being differentfrom all others.)

In addition, the relative orientation was significantly different from zero at workspace locations R (P = 0.0033), M (P =0.0108), and L (P = 0.0067) but not at location E (P = 0.9635).Figure 3B shows that the major axis of the best-fitting ellipseis oriented approximately 12° clockwise with respect to the directionof least inertia for three of the locations. The orientation ofthe major axis for location E, however, is not significantly differentfrom the direction of leastinertia.

Elbow/shoulder excursion ratio and phase difference

The mean values of the ratio of elbow and shoulder excursions for the locations R, M, L, and E were, respectively, 1.36, 1.38,1.37, and 1.82. The corresponding phase differences (elbow relativeto shoulder) were, respectively, $-$ 130.6, $-$ 128.9, $-$ 124.9, and $-$ 141.0°,the negative values indicating a phase lag. The effect of locationwas significant on the elbow/shoulder ratio [F(3,15) = 33.74,P < 0.0001] as well as on the phase [F(3,15) = 9.48, P = 0.0009].Pairwise comparisons revealed that the elbow/shoulder ratio aswell as the phase were different for location E compared withthe other locations [P < (0.05/6) = 0.0083], but there were nosignificant differences when comparing the other pairs of locations.The effect of speed was not significant on the excursion ratio[F(1,5) = 3.42, P = 0.12]. Examining the data for individual subjects,however, we found that four of the six subjects exhibited increasingelbow/shoulder ratio with increasing speed, with significant positivecorrelations (r = 0.50 to 0.69, P < 0.0001). Of the remainingtwo subjects, subject S3 did not show a significant correlationof excursion ratio with speed and subject S5 showed a significantnegative correlation (r = $-$ 0.37, P < 0.05). If the data for subjectS5 were discarded, the effect of speed on the elbow/shoulder ratioreached significance at the criterion level [F(1,4) = 11.48, P= 0.03]. The effect of speed on the phase was significant [F(1,5)= 18.05, P = 0.0081], albeit with a modest slope of 0.204°/(cm/s),the positive sign indicating a decrease in the phase lag of theelbow angle with increasing speed. All six subjects exhibitedsignificant correlations (r = 0.18 to 0.54, P < 0.05) of the samesign, and discarding the data for subject S5 did not the changethe significant effect of speed on the phase [F(1,4) = 11.89,P = 0.03]. It appears, therefore that as the speed increases,individual subjects differ in how the shoulder and elbow motionsare apportioned with the elbow/shoulder ratio increasing for themajority of subjects, but all subjects exhibit some decrease inthe lag of the elbow with respect to the shoulder. With respectto the different locations in workspace, all subjects exhibita greater elbow/shoulder excursion ratio and a greater phase lagfor the more extended elbow position compared with the other threepositions.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Tests of the specific hypotheses

Two hypotheses were advanced in the INTRODUCTION to test the idea that speed causes systematic distortions in drawing circlesand that inertial anisotropy may be responsible. Hypothesis 1was that speed will affect the circularity of figures drawn byelbow and shoulder movements (as has previously been shown forwrist and finger movements by Dounskaia et al. 2000), with fastermovements associated with greater elongation into an oval shape,but the position in the workspace for comparable angle betweenthe forearm and upper arm, will not affect the circularity ofthe figures. Our observations fully support this hypothesis. Positionin workspace had no statistically significant effect on circularitynot only for the three positions with similar inertial anisotropy(L, M, R) but also for the position with a different anisotropy(E).

Hypothesis 2 was that the orientation of the elliptical figures drawn at high speed will vary with workspace location suchthat the long axis coincides with the direction of least inertia.We found that indeed the orientation did not remain fixed in theworkspace. The observations, however, revealed a small but consistentdiscrepancy of approximately 12° between the direction of elongationand the direction of least inertia for three of the four workspacelocations tested (R, M, and L). At the fourth location (E), wherethe elbow was in a more extended position, the discrepancy wasnot significantly different from zero, which supports the hypothesis.This issue will be discussed in greater detail lateron.

Before addressing our findings in the context of inertial anisotropy, it is important to consider other possible mechanisms,not based on the biomechanics of the arm, that can give rise todistortions in hand-drawncircles.

Possible nonmechanical explanations for distortion of circles

Location in workspace is known to influence the errors in arm positioning tasks; in particular, the left and right hemispacesdiffer in this regard when reaching with the same hand (Imanakaet al. 1995). This phenomenon, related presumably to corticalhemispheric effects, could also influence the errors in othertasks such as circle drawing. We found, on the contrary, thatamong the right, middle, and left positions located at comparabledistances in the workspace, there was no significant change inthe circularity, the relative orientation of the long axis ofthe distorted circle, the elbow/shoulder excursion ratio, or thephase. These observations weigh against an explanation of thedistortion in terms of attentional or visual differences betweenlocations in different directions. Moreover, Carey and Grace Otto-deHaart (2001) have argued that even the differences in arm positioningerrors in different locations may be attributable to inertialanisotropy.

Errors due to inaccuracy in the transformation from the desired movement of the fingertip (in extrinsic coordinates) to thenecessary motions of the segments (in intrinsic coordinates) havebeen reported, for pointing movements (Flanders et al. 1992) aswell as for circle and ellipse drawing movements (Soechting etal. 1986). While distortion arising from this mechanism appearsto be important for comparatively large circles, with diameterca. 30 cm, it would have less effect when drawing smaller circles,ca. 5 cm, such as the ones we studied. More importantly, thismechanism cannot account for the observed effect of speed on thedistortion. Therefore while inaccuracies in the transformationbetween extrinsic and intrinsic kinematic variables may well contributeto the distortion to some extent, the systematic speed-relatedincrease in elongation cannot arise from thismechanism.

Some investigators consider the inter-segmental phase during periodic motion to be an expression of the phase preferred bythe underlying dynamical system, and if there are discrete transitionsin the preferred phase when the frequency of periodic motion isincreased, these transitions are regarded as describing essentialproperties of the dynamical system (Kelso 1984; Kelso et al. 1991).From this point of view, the dynamical system could be so organizedthat it prefers in-phase or out-of-phase segmental motions, anda transition in the phase difference as the frequency is increasedresults in a circle changing into an ellipse. Neither Dounskaiaet al. (2000) nor we, however, observed a sudden transition incircularity or in the phase as the speed was increased; moreover,the phase between the elbow and wrist angles (Dounskaia et al.2000) or between the shoulder and elbow angles (our study) nevercame close to 0 or 180°. Therefore the dynamical systems approachin which a discrete transition occurs at a critical frequencydoes not provide an explanation for theobservations.

Explanations based on mechanical properties

A circle can be distorted into an oval shape by a change in the relative excursions of the segments, in the inter-segmentalphase, and in the precise waveforms of the segmental motions orby a combination of these three factors. We have investigatedtwo of these factors. Our results indicate that all subjects decreasethe phase lag of elbow motion with respect to shoulder motionwhen moving at higher speed, and a majority of them also increasethe elbow/shoulder excursion ratio. Despite these individual differences,the change in circularity with speed is similar acrosssubjects.

The fact that at lower speeds the circularity is high for all locations indicates that the anisotropy of stiffness is eitherof negligible importance or it is well accounted for by all subjectsin generating the motor output. For faster speeds, none of thestrategies adopted by different subjects succeeds in preventingthe distortion of circles. This suggests that some speed-dependentmechanical property, related to inertia or viscosity, is not fullyaccounted for in generating the motor output, resulting in distortionat the higher speeds. Velocity-dependent forces, such as Coriolisforces, could lead to distortions. However, Lackner and colleagueshave shown that, in reaching movements, subjects compensate automaticallyfor self-generated Coriolis forces (e.g., reaching while turningthe trunk) (Pigeon et al. 1999); moreover, subjects adapt over8-15 trials, without visual or direct tactile feedback about reachingaccuracy, to Coriolis forces that are experimentally imposed byrotating the room without the subject's knowledge (Lackner andDiZio 1994). Therefore we do not believe the distortions are dueto Corioliseffects.

That the viscous properties of muscle affect the kinematics has been shown for single-joint movements (Jaric et al. 1998).The possibility of viscous anisotropy's contribution was not consideredin the Introduction because it was assumed that at the highestspeeds of movement the effect of inertial anisotropy will dominatethe effects not only of stiffness anisotropy but also of viscousanisotropy. The observation that the direction of elongation ofthe ellipse is somewhat different from the direction of leastinertia leads us to consider the possibility that anisotropy ofviscosity may also be playing a role. This modification of theoriginal postulate, we would argue, can help explain the consistentdiscrepancy we observed between the direction of elongation andthe direction of least inertia for three of the four locationsstudied and can also explain the lack of discrepancy for the fourthlocation. The argument is presented in the followingtext.

Figure 4A depicts diagrammatically the stick figure of the arm in a middle location (M), along with the mean direction ofelongation of the ellipse observed for this location. Also shownis the direction of least inertia (using the anthropometric parametersfor a typical subject and the elbow angle depicted). The directionof elongation differs from the direction of least inertia by 11°clockwise, which is the mean value observed for location M. Wewould like to also compare the direction of elongation with thedirection of least viscosity, but the latter is not known andtherefore can only be approximated based on reports in the literature.Tsuji et al. (1995) found the direction of least viscosity tobe close to the direction of least stiffness and Mussa-Ivaldiet al. (1985, their Fig. 7) show that for locations comparableto that of Fig. 4A, the maximum stiffness is approximately alongthe line joining the endpoint to the shoulder, and therefore theminimum stiffness direction is perpendicular to this line. Thisdirection, which we assume is nearly unaltered between posturalmaintenance and voluntary movement (Gomi and Kawato 1997), isshown as a dotted line in Fig. 4A, which corresponds to a roughapproximation of the direction of minimum stiffness and viscosity.It is noteworthy that the observed direction of elongation ofthe ellipse lies part way between the directions of least inertiaand least viscosity. We interpret this to mean that the elongationarises not entirely because of lack of compensation for inertialproperties but also partly from lack of compensation for viscousproperties. The same interpretation is equally applicable to locationsL and R (not depicted) because all the directions depicted inFig. 4A will simply rotate with changes in arm orientation aslong as the elbow angle remains the same. Indeed, we found thediscrepancy between the direction of elongation and the directionof least inertia to be statistically indistinguishable among thethree locations with comparable elbow angles.

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Fig. 4. Diagrammatic depiction of the arm (S: shoulder, E: elbow) for 2 different elbow angles (A for workspace location M, and B for location E). The average orientation of the elongation of circles drawn at fast speeds is shown by the thick short line at the endpoint. For comparison are shown the direction of least inertia (thin solid line), and the surmised direction of least viscosity and stiffness (dotted line).

For a more extended elbow, corresponding to location E, there is no significant discrepancy between the directions of elongationand of least inertia, as depicted in Fig. 4B. For this locationcompared with the other locations, the inertial anisotropy ismore pronounced insofar as the ratio of the greatest and smallestinertias is larger. The larger inertial anisotropy can dominateany effects of viscous anisotropy, which would be consistent withthe direction of elongation almost coinciding with the directionof leastinertia.

There is evidence to indicate that subjects are aware of inertial anisotropy (Flanagan and Lolley 2001) and, indeed, seemto make use of the anisotropy in prescribing the hand-movementtrajectory when avoiding an obstacle (Sabes and Jordan 1997; Sabeset al. 1998). It is surprising, then, that subjects do not accountfor it when launching a pointing movement (Gordon et al.1994)nor when drawing circles at high speeds. Comparing the responseto inertial anisotropy with the response to externally added inertialloads, the initial motor output in the latter case too has beenfound to be independent of inertia (Gottlieb et al. 1989; Honget al. 1994; Karst and Hasan 1991). When, for example, the inertialload is known to be greater, the CNS does not compensate by simplyscaling up the entire motor output, although some compensationvia motion-related feedback occurs during the movement (Gottlieb1996; Sainburg et al. 1999). Rather, the movement time is prolonged,which is also the case without external loads when the hand movesin directions of greater inertia (Gordon et al. 1994). The limitationto compensation for inertia, both external and internal, may bea reflection of the delays in feedback correction that increasein significance at higher speeds. Whether the movement plan itselffails to account for mechanical anisotropies or whether thereis not enough time for feedback corrections to compensate forthe anisotropies, it is the mechanical properties that appearto cause distortions increasing consistently with speed ofmovement.

Conclusion

A good portion of the current literature on the control of multijoint movements focuses on inertial properties of the movingsegments and the inter-segmental interactions that arise fromthem. If inertial properties were the only mechanical propertiesof significance, then the control of fast movements will be asimple matter of scaling the motor output that is appropriatefor slow movements (Hollerbach and Flash 1982), resulting in identicalmovement paths at all speeds. Clearly this is not the case forthe circle-drawing movements studied in this report or the onesstudied by Dounskaia et al. (2000), nor is it the case for a varietyof other cyclical movements including locomotion (Bianchi et al.1998), mastication (Throckmorton et al. 2001), and arm swinging(Abe and Yamada 2001). Speed effects have also been describedfor noncyclical movements such as reaching (Fischer et al. 1997),drawing (Schillings et al. 1996), and handwriting (Wright 1993).Moreover, the CNS does not seem to take full account of the inertialproperties even for such common movements as those involved inpointing to a fixed target. We tested whether the same is truefor movements that necessarily entail a nonstraight path. Ourresults support this hypothesized lack of accounting for inertialproperties to the extent that circles drawn at slow speeds turninto more elliptical shapes at higher speeds, with the long axisremaining close to $---$ but not identical with $---$ the direction of leastinertia. The discrepancy, however, is consistent enough to demandexplanation, and we have provided a possible explanation in termsof the concomitant influence of viscoelasticanisotropy.

An overall scheme that is consistent with our results is that the motor plan for repetitive movements is designed $---$ either inadvance or through sculpting by motion-dependent feedback $---$ so asto be adequate for slow movements for which inertial effects arenot dominant. When higher speed is required, the plan is altered,in a subject-dependent manner, but never to the extent neededto compensate fully for the now important inertial and viscousproperties of the limb and therefore does not result in the samepath as before. More rigorous tests of this scheme will involvemeasurements of the mechanical anisotropies along with the kinematicsand kinetics of voluntary movements for the same subjects andlimb configurations (cf. Lacquaniti et al. 1993) and the studyof the influence of unusual loads that could possibly annul theinherentanisotropies.

	ACKNOWLEDGMENTS

This study was supported in part by the National Institutes of Health Grants R01-NS-28127, R01-NS-40902, R01-NS-19407, andR01-AR-33189.

	FOOTNOTES

Address for reprint requests: D. Corcos, School of Kinesiology, University of Illinois at Chicago (MC 194) 901 W. RooseveltRd., Chicago, IL 60608-1516 (E-mail: dcorcos{at}uic.edu).

REFERENCES

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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Circle-Drawing Movements at Different Speeds: Role of Inertial Anisotropy

0022-3077/02 $5.00 Copyright © 2002 The American Physiological Society