Apparent Position of Visual Targets during Real and Simulated Saccadic Eye Movements

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Volume 17, Number 20, Issue of October 15, 1997 pp. 7941-7953
Copyright ©1997 Society for Neuroscience

Apparent Position of Visual Targets during Real and Simulated Saccadic Eye Movements

M. Concetta Morrone¹, John Ross², and David C. Burr¹^,²^,³
¹ Istituto di Neurofisiologia del Consiglio Nazionale delle Ricerche, 56127 Pisa, Italy, ² Department of Psychology, University of Western Australia 6907 Nedlands, Australia, and ³ Department of Psychology, Università di Roma "la Sapienza," 00185 Rome, Italy

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

It is now well established that briefly flashed single targets are mislocalized in space, not only during saccades but alsobefore them. We show here by several techniques (including a vernierjudgment that did not require absolute location in space) thaterrors appear up to 100 msec before saccades are made and aremaximal just before they start. The size and even the sign oferrors depend strongly on position in the visual field, the completepattern of errors suggesting a compression of visual space aroundthe initial fixation point and the target of the impending saccade.The compression was confirmed by displaying multiple rather thansingle targets and was found to be powerful enough to reduce oreven to remove vernier offset for pairs of bars shown simultaneouslyand to create offsets for colinear bars separated in time by 75msec. It also reduced the apparent number of parallel bars. Whensaccades were simulated by moving the display at saccadic speed,there were sometimes errors of location, but only for tasks requiringabsolute judgment of position. The pattern of errors differedgreatly from that during saccades and, in particular, showed nosigns of compression. We can model our saccade results by assuminga shift in the point in space associated with eye position compressionof eccentricity along the axis of saccades.
Key words: saccades; eye movements; extraretinal position signal; magnocellular; attention; visual capture

INTRODUCTION

Saccades are rapid eye movements, frequently made, that shift the point of gaze and therefore reposition images of the externalworld on the retinas. They pose two obvious problems: (1) Whyis image motion not usually noticed; and (2) how is visual stabilitymaintained in the face of shifts in the retinal position of images?Recent evidence suggests that motion signals are suppressed duringsaccades, possibly by selective attenuation of the magnocellularpathway (Burr et al., 1982; Shiori and Cavanagh, 1989; Burr etal., 1994; for review see Ross et al., 1996a). However, the questionof visual stability remains elusive.

Theories of stability across saccades have been dominated by the idea of a uniform vectorial correction that cancels out thetranslation of images on the retina. This idea has often beenattributed to von Helmholtz (1866), who used the term Willenanstreungung(usually translated as effort of the will) for the primary sourceof the information used to make the correction. But Grüsser (1994)has traced the idea itself beyond Franciscus Aguilonius in theearly 17th century and has shown that it has surfaced repeatedlyin ancient and modern times. The idea is now most closely associatedwith two models, the "efference copy" (and "reafference") of vonHolst and Mittelstaedt (1950) and the "corollary discharge" ofSperry (1950). von Helmholtz (1866) suggested that sensationsof motion, although not registered consciously, might also makea contribution, and Sherrington (1918) identified afferent signalsfrom extraocular muscle spindles as a possible source of informationabout eye position during movement. There has emerged the conceptof an extraretinal position signal (ERPS) with possibly both "outflow"and "inflow" components (Whitteridge, 1960).

The correction to retinal position codes had been assumed to coincide with the eye movement and to grow continuously withit, therefore ensuring stability of perceived position at alltimes, until the work of Matin and Pearce (1965). They showedthat targets flashed during saccades were mislocated, and furthermore,that errors of location were different for targets flashed atdifferent positions. This undermined the assumption of a correctioncoinciding with the saccade and cast doubt on the more fundamentalassumption that the correction was uniform for all directionsin space. Matin and Pearce (1965, page 1487) themselves suggestedthat "compensation" might occur "at different rates at differentregions of the visual field."

Subsequent findings of Matin and his associates led them to conclude that the ERPS does not coincide with its saccade butis more sluggish (Matin et al., 1969, 1970). Similar conclusionshave been drawn by Schlag and associates (Dassonville et al.,1992; Schlag and Schlag-Rey, 1995; Cai et al., 1997) and by Honda(1989, 1991, 1993), who found substantial errors of location fortargets flashed before the eye had moved, suggesting that theERPS anticipated its saccade. Less attention has been given tothe issue of the uniformity of errors of location across the visualfield, but Honda (1995) recently reported that the size of errorschanges with target position. The pattern Honda finds is consistentwith what Matin and Pearce (1965, page 1487) termed a "contractionof visual space in the direction of ocular motion."

For many years attempts to find any neurophysiological substrate for the widely assumed ERPS met with little success. However,it has recently been shown by Duhamel et al. (1992) that a substantialproportion of neurons in the parietal cortical lateral intraparietalarea (LIP) shift their receptive fields in a manner consistentwith an ERPS. They anticipate saccades by responding to what willfall on their classical receptive fields after an intended saccadehas been completed. Similar behavior has also been demonstratedin neurons in the deep layer of the superior colliculus (Walkeret al., 1995). But even more recent evidence suggests that someLIP neurons behave in stranger ways; their receptive fields deform,increasing or decreasing in size, and are displaced in directionsother than that of the saccade (Ben Hamed et al., 1996). The functionof this behavior is much less clear.

Our purpose here is to examine more closely the pattern of perisaccadic errors of location in humans, particularly how theychange with target position, and also to deduce the structureof perceptual space during saccades.

Some of this work has been published in abstract form (Morrone et al., 1996; Ross et al., 1996b) and in a brief report (Rosset al., 1997).

MATERIALS AND METHODS
Stimuli. Stimuli were displayed on a Mitsubishi color monitor with display area 36 × 25 cm, subtending 70 × 50° at the usualdistance of 25 cm. The display was surrounded by a white card(1.2 × 1 m), lit to about 10 cd/m² by background lighting. Stimuli were generated at 120 Hz by avisual stimulus generator (Cambridge Research Systems VSG2) housedin a personal computer (PC). All stimuli (except natural scenes)were presented on a red background (Commission Internationalede l'Eclairage (CIE) coordinates: x = 0.595; y = 0.349; luminance,16.3 cd m²) for a single frame (8.3 msec). Except where indicated stimuliwere single or multiple green vertical bars (CIE coordinates:x = 0.298; y = 0.563) displayed at luminance equal to the background(determined separately for each observer by flicker photometry).They were usually 4° wide and stretched either from the top ofthe screen to the bottom (full bars), or from the middle to thetop or the bottom (half bars). The display is illustrated in Figure1.
Fig. 1. Top, Spatial layout of the display. The screen was 36 × 25 cm (70 × 50° at the usual distance of 25 cms), of uniform red,with mean luminance of 14 cd/m². The bar, usually vertical and equiluminant green (but sometimesblack), could be displayed at any position. The ruler, when usedas a reference, appeared 500 msec after completion of saccade.Bottom, Time course of the presentation. The black fixation circle(F₀) stayed on for the duration of the experiment. Aftera warning, a similar black circle appeared at F₁, towhich observers saccaded as quickly as possible. The stimulus(in this case a single vertical bar at position 0°) was brieflydisplayed for one frame (8 msec) at some arbitrary time afterthe saccadic target appeared. In the first series of experiments,observers simply reported the apparent position of the bar relativeto the ruler. In others, they had to report the apparent offsetof two half-bars or the number of bars seen in a multiple display.
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The time of presentation of the stimulus was determined by computer and illustrated to the experimenter, together with theeye movement trace, after each trial, with a visual display (suchas Fig. 1, bottom). The actual timing of the stimulus onset, relativeto eye movements, was calibrated directly by measuring it at themonitor with the eye movement sensor. Because of the monitor raster,there was a 5 msec variation of display time from top to bottom;the times given in this study are those at the center of the screen,at the level of eye gaze.

Eye movements. Eye movements were monitored by an infrared limbus eye tracker (HVS SP150). The horizontal resolution was 0.01degree, and accuracy was 0.1 degree (manufacturer's specifications).Vertical resolution and accuracy was about 0.03 and 0.3 degree,respectively. The infrared sensor was mounted below the righteye on transparent wraparound plastic goggles through which observersviewed the display screen binocularly. The PC sampled eye positionat 1000 Hz and stored the trace in digital form (after suitablelinearization). Before each session, both the gain and the linearizationof the eye tracker were calibrated by asking observers to makesaccades to five fixed points arranged horizontally (or verticallyin the one case in which subjects saccaded vertically).

After each trial, the computer identified the beginning of the saccade (by convolving the trace with a difference-of-gaussianfunction and finding the peak or trough), and calculated the delayof the stimulus presentation (positive or negative) relative tosaccade onset. An experimenter viewed the eye movement trace aftereach trial and adjusted the estimate of saccade onset (when necessary)or aborted the trial if the saccade was not of sufficient amplitude(within 5% of correct amplitude).

Simulated saccades. "Simulated saccades" were produced by viewing the oscilloscope through a light plastic mirror (25 × 15cm) caused to rotate at saccadic speeds by a computer-activatedsolenoid. The mirror was positioned as close as possible to theobserver and gave a clear view of the entire monitor togetherwith ~60° of surround (the white card) in all directions. Displacementdistance was calibrated by projecting a laser from eye positionto the screen. Duration and velocity of the motion were monitoredthroughout the experiment with the infrared sensor of the eyetracker placed on an "artificial eye" attached to the mirror.Typical duration for a 20° displacement was 45 msec, comparedwith 40 msec for the human saccade (Carpenter, 1988). We did notmonitor eye movements during the experiments (because the trackerwas used to identify motion onset and to check mirror function),but in separate control experiments we showed that subjects maintainedperfect fixation under these conditions and did not make saccadesor fast pursuit movements in response to the moving scene (cf.Kawano and Miles, 1986).

Procedure. Observations were made in a dimly lit room. Trials began with a dark fixation spot, which appeared usually 10°to the left of the center of the screen and stayed on thereafter.After a warning a target appeared (and thereafter stayed on) usually10° to the right of the center, and observers made a saccade toit as soon as they could. Latencies varied with observer and levelof training within a range of 140-220 msec. Stimuli were flashedfor one frame (8 msec) some time after the appearance of the targetand could fall before, during, or after the saccade (see Fig.1 for illustration of sequence of events). About 500 msec afterthe saccade, a ruler was drawn across the whole screen, runningthrough the fixation point and target (illustrated in Fig. 1).Observers were required to report the positions of bars with referenceto this ruler. For most experiments the fixation point and targetwere positioned as described above, but for others they variedto give shorter horizontal saccades and vertical saccades. Observersvoiced their responses, which were recorded on computer by anexperimenter, after checking the quality of the saccade and theestimate of saccade onset.

The procedure for simulated saccades was identical to that for saccades, except that the mirror action replaced the saccades.The display was inverted horizontally to compensate for the invertingeffect of the mirror.

Observers. Observers, whose ages ranged from 26-65, included the authors and students from their laboratories in Perth andPisa. Because relevant theory, and even patterns in the data,emerged only late in the course of investigation, all were effectivelynaive for most observations, but care was taken to keep some observersinnocent of theory as it developed and to recruit new observersto guarantee unprejudiced observations.

RESULTS

Effect of saccades on apparent position
Time course of localization In the first experiment observers viewed (from a distance of 25 cm) a fixation point at $-$ 10° (to the left of center) and saccadedto a target at +10° (20° saccades). Single bars subtending 1.8× 50° were flashed for one frame at the center of the screen (0°), $-$ 20° (left of center), or +20° (right of center). The short exposureminimized motion blur during saccades. Time of display rangedfrom well before (< $-$ 150 msec) to well after (>150 msec) the startof saccades. Observers, who were unaware of actual display positions,reported where bars appeared by reference to the ruler that wasdrawn on the screen 500 msec after the saccades has finished.

Figure 2 shows the results of the first experiment, for observer M.C.M. (an author), observing both equiluminant green bars(left) and black bars (right). For both types of stimuli, reportedbar position was close to true position outside the range of $-$ 50to 50 msec, but within this range the apparent position of barswas systematically displaced. The pattern of the displacementdepended critically on the actual position of the displayed bar.Those displayed to $-$ 20, $-$ 7, or 0° were systematically mislocatedin the direction of the saccade. The displacement began beforesaccade commencement, reaching a maximum near the time t = 0,where it was ~10°, half the size of the saccade. The magnitudeof the mislocalization decreased gradually throughout the saccade,returning to near veridical shortly after the completion of thesaccade.
Fig. 2. Apparent position of a bar flashed briefly (8 msec) at various positions and at various (randomized) times relative to saccadiconset, as observers saccaded from the fixation point at $-$ 10° tothe target at 10° (indicated by the arrow on the left). For thecurves on the left, the bars were green, equiluminant with thered background, and for those on the right they were black. Allof the data are from observer M.C.M., an author. The continuouscurves are the predictions of the model, described in MathematicalModel of the Results. The physical position of the bar was $-$ 20°(upright triangles), $-$ 7° (open squares), 0° (filled circles),20° (inverted triangles), or 28° (filled squares). The patternof results for the dark bars was very similar to that with theequiluminant bars. Bars displayed to the left of the saccadictarget were mislocalized in the direction of the saccade, withmaximum error just before saccadic onset; bars displayed pastthe target were mislocalized in the other direction, toward thetarget.
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The results for bars displayed at +20 and +27° were quite different from the others. Mislocalization was again maximal atapproximately t = 0 but in the opposite direction from the otherconditions. In these conditions apparent displacement occurredagainst the direction of the saccade, back toward the saccadictarget. Again, the displacement relaxed in amplitude throughoutthe saccade, returning near (but not quite to) veridical aftercompletion of the saccade.

The continuous curves passing through the data of this and later figures are fits of a model, which assumes a shift in theorigin of visual space before each saccade, together with a compression.Details of the model are given in Mathematical Model of the Results.

The results for luminance-modulated stimuli were very similar to those for equiluminant stimuli, except for a slight differencein time course, with the equiluminance data anticipating luminancedata by about 10 msec. This difference (incorporated in the modelpredictions) most probably results from differences in processinglatencies for luminance and chromatic stimuli (Bowen, 1981; Burrand Morrone, 1993). Because the major pattern of results did notvary much between stimuli, most of the subsequent measurementswere made with equiluminant stimuli, known not to be less visibleduring saccades (Burr et al., 1994).

Figure 3 shows similar sets of data collected with equiluminant stimuli from three additional observers, two of whom wereinnocent of the goals of the experiment. Saccades were again 20°,left to right. The effects were qualitatively similar for allobservers, although there were differences in magnitude, particularlyfor M.R.D., for whom the displacements in both directions wasgreater than for the others. The continuous lines refer to modelpredictions, with parameters chosen separately for each observerbut maintained for all data collected by each observer (see Table1 for values).
Fig. 3. Same as Figure 1 for three different observers, two of whom were unaware of the goals of the experiment. In this case, thebars were always equiluminant green. The bars were physicallydisplayed at $-$ 20° (upright triangles), $-$ 7° (filled squares forJ.R.), $-$ 3° (circles for M.D. and J.F.), 0° (circles for R.J.),or +20° (inverted triangles).
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Table 1. Values of model constants used to fit the data of the various observers

Observer Gain a₀ Origin shift
Compression

$tau$ ₀ $sigma$ ₀ $tau$ ₁ $sigma$ ₁

M.C.M. 0.93 $-$ 5 40 $-$ 7 15

J.F. 1.09 $-$ 10 40 $-$ 3 17.5

J.R. 1.09 $-$ 10 40 $-$ 3 17.5

J.A.M. 0.79 0 40 $-$ 7 15

H.D. 0.79 $-$ 10 40 7 40

M.D. 0.66 10 40 7 30

Figure 4 shows data for smaller (10°) saccades, between $-$ 5 and +5°, achieved by viewing the same display as before from 50instead of 25 cm. This scaled the whole image, so the bars subtended0.9 × 25°. Both observers were naive about the experimental goals.The pattern of results is similar to those of the larger saccades,with mislocalization in the direction of the saccade for bar positionsat $-$ 10 and 0° and against it for bars at +10°.
Fig. 4. Same as Figure 2, except the saccades were smaller, from $-$ 5 to 5°. The display was otherwise the same as before but was viewedfrom twice the previous viewing distance (50 cm). The bars werephysically at $-$ 10° (upright triangles), 0° (filled circles) or10° (open squares).
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Effect of spatial position To study the effect of spatial location on mislocalization over a wider range, we measured the apparent position of bars displayedrandomly from positions $-$ 20 to 20° in the critical presaccadicperiod. Bar latency (relative to the signal to saccade) was setso that stimuli tended to fall over a wide range at random, butonly those that fell between $-$ 25 < t < 0 msec were included inlater analysis. Figure 5 shows the results for observer M.C.M.for 20° saccades. Figure 5, A and B, refers to standard left-to-rightsaccades for equiluminant green bars and for black bars, respectively.The results show that both the amount and the direction of displacementclearly depend on the physical position of the bars, with a tendencyfor data to concentrate around the two fixation points. The smalldots show control measurements, made with the eyes still undersimilar conditions. Position judgments were very accurate. Thelinear regression of these data had a slope of 1 (r > 0.995).Figure 5C shows results for right-to-left saccades (from +10 to $-$ 10°) for dark and equiluminant stimuli, producing similar butmirror-reversed results.
Fig. 5. Apparent position of bars presented at various positions in the interval just before saccadic onset ( $-$ 25< t <0 msec). A, B,Results for equiluminant green and black bars, respectively, for20° left-to-right horizontal saccades. C, The direction of thesaccades was reversed, from 10 to $-$ 10°. D, Possibility of visualfeatures acting as passive attractors, investigated by "priming"the bar position with a flashing dot (open circles) or by adding50 stationary random dots (2° diameter) to the display and usingan ever-present saccadic target that was dimmed slightly as asignal to saccade (open triangles). Neither manipulation significantlyaffected the results. E, F, The bar was horizontal, and observersjudged its vertical position, either during vertical saccades(E) or horizontal saccades (F). The horizontal saccade had verylittle effect on the vertical position, but the vertical saccadecaused the same pattern of compression observed previously. Asbefore, the continuous lines show the model predictions.
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For Figure 5E the observer made vertical saccades and reported the vertical position of a horizontal bar. Again, the patternof results was similar to that of the standard horizontal saccade,with a tendency for data to cluster around the two fixation points.For Figure 5F, the observer again reported the vertical positionof a horizontal bar, but this time while making horizontal saccades.Under these conditions localization was virtually veridical, implyingthat saccades have very little effect in the orthogonal direction.This is pursued further in Figure 7.
Fig. 7. Apparent position in two dimensions of large green dots (6° diameter) briefly presented in the interval just before onsetof 20° horizontal saccades ( $-$ 25 < t < 0 msec). The horizontallocalization followed the same pattern as observed with bars,but the vertical localization showed no systematic bias or tendencyfor compression. The dashed lines show the prediction for veridicalperception.
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Figure 6 shows more measurements of the effect of bar position for different observers and for saccades of varying size. Theexact pattern of results varies from observer to observer, andwith saccade size, but the general tendency for compression wasalways present. The compression was most extreme with observerM.R.D. (consistent with the results shown in Fig. 4). With 20°saccades he always tended to see bars near 0°, irrespective ofwhere they were displayed. Even with 2.5° saccades, the compressionwas considerable. Observer J.A.M. also showed compression forthe shorter saccade, but it was less extreme. All data could bewell simulated with a single model, with the same parameters asused in the previous figures (see Table 1 for values).
Fig. 6. Results similar to those of Figure 4, for different observers and variable length saccades (indicated by the arrows near theabscissas). Saccade amplitude was 20° for A, B, E, 10° for C (viewingdistance, 50 cm), 5° for D (viewing distance, 100 cm) and 2.5°for F (viewing distance, 200 cm). The bar was briefly presentedin the interval just before the onset of saccades (for 20 and10°, $-$ 25 < t < 0 msec; for the smaller saccade, between $-$ 10 <t < 0).
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   Importance of visual cues In the previous experiments, the only features on the screen were the initial fixation point and the saccadic target (theruler appeared 500 msec later). One possibility is that thesefeatures act as "passive attractors," which in some way bias apparentposition in their direction. To examine this idea, we attemptedtwo variants, shown in Figure 5D. For one experiment we primedthe position of the stimulus with a large, high-contrast dot flashedbefore the saccade (data shown in Fig. 5D, open circles); in anotherwe added at 50 random locations additional stationary "seed" dots,of identical size and color to the saccadic target (Fig. 5D, triangles).In this condition the saccadic target was always present, decreasingin contrast to signal the observer to make a saccade.

It may be argued that the first intervention should decrease the uncertainty of the stimulus position, decreasing the compression.The second may decrease the attractiveness of the saccadic targetby diluting it with competing attractors. In fact neither interventionchanged the pattern of results. This would suggest that if thefixation points are serving as attractors in some way, they donot do so passively.
Localization orthogonal to saccade direction Figure 5E suggested that saccades had little effect on the vertical position of horizontal bars during horizontal saccades.We pursued this further by asking observers to locate in two dimensionsthe center of disks (6° diameter) displayed at random anywherewithin the whole display area in the critical interval 0-40 msecbefore saccade onset. Because localization in two dimensions wasmore difficult than in one dimension, we collected data only fromthe experienced observers M.C.M. and J.R. The results are shownin Figure 7, for horizontal localization (Fig. 7A,C) and for verticallocalization (Fig. 7B,D). Horizontal localization was not dissimilarto previously reported results, except for an increase in variability,probably attributable to the increase in eccentricity of the stimuliand the greater demands of the two-dimensional task. Verticallocalization, however, was quite veridical. There was a certainlevel of noise, but there was no systematic dependency on verticalposition. Nor was there a dependency on horizontal position (datanot shown).
Multiple targets As a more severe test of the dependence of saccadic displacement on spatial position, and of compression, we used a stimuluscomprising two half-bars (1.8 × 25°), one displayed from the midlineto the top, the other from the midline to the bottom of the screen.In the first experiment they were first displayed simultaneously,but at different positions, either at $-$ 20 and 0° or at 0 and 20°(with the top or bottom assigned to one of the two possible positionsat random). Observers made 20° saccades (from $-$ 10 to +10°) andwere required to report separately the positions of both bars.Figure 8 shows the results for equiluminant stimuli for two observers,M.C.M. and J.R. The top curves plot the positions of the half-bars,with different symbols for the two sets of spatial positions.The pattern of results is similar to that observed with full bars(Fig. 2). Furthermore, the apparent position of one half-bar doesnot depend on the true position of the other; the data for position0° for the $-$ 20/0° condition (Fig. 8, triangles) and the 0/20°condition (Fig. 8, circles) were very similar.
Fig. 8. Judgment of the apparent position of two half-bars displayed simultaneously at different positions, either at $-$ 20 and 0° (filledand open triangles, respectively) or at 0 and 20° (open and filledcircles, respectively), while observers made 20° horizontal saccades.The results for half-bars shown in pairs are similar to thosefor single isolated bars. The bottom curves show the apparentseparation of the bars for the two conditions. Whereas the $-$ 20/0°(triangles) pair maintains a veridical separation of $-$ 20° at alldelays, the separation of the 0/20° pair (circles) shrinks justbefore saccadic onset, when they appear to be colinear.
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The effects of compression are brought out more clearly in the bottom curves of Figure 8, which show the apparent separationsfor the two conditions. Although the $-$ 20/0° pairs were alwaysseen to be separated by $-$ 20° (correctly), the separation betweenthe 0/20° pair narrowed to around 0° near saccade onset. Thisis again consistent with compression and does not rely on absolutejudgments relative to an external ruler but on the differencesof such judgments: any systematic biases should be eliminatedin the subtraction.

We next measured the apparent separation of two half-bars (again equiluminant and 1.8 × 25°) that were colinear but separatedin time by 75 msec (order of top and bottom randomized). Hereobservers were required to report the sign and amplitude of theseparation, rather than the positions of each half-bar. With thistechnique there was no requirement for observers to make positionjudgments relative to an external scale. The results are shownin Figure 9 for four different spatial positions of the bars: $-$ 7, 0, 10, and 20°. The ordinate shows the difference betweenthe second and the first presented bars, so a positive numbermeans a relative displacement of the second bar in the directionof the saccade.
Fig. 9. Apparent separation of colinear half-bars presented at various positions with a 75 msec asynchrony, at various (randomized)delays of the first bar relative to the onset of a 20° horizontalsaccade. Although physically colinear, the bars appeared to beoffset over much of the range of delays. The direction of theoffset depended on spatial position. At 0 and $-$ 7°, the displacementwas initially positive (meaning that the second bar was displacedin the direction of the saccade), becoming negative as time progressed.At 20°, the pattern of results was reversed (although somewhatnoisier). At 10°, the saccadic target, there was very little displacementin either direction. Note that for t < $-$ 75 msec, both bars werepresented to the same physical position on stationary retinas.
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The pattern of results is clearly different for the three conditions. The most interesting interval is between $-$ 100 and $-$ 75msec, when both bars are presented at the same position to stationaryeyes and the second, but not the first, falls near the saccadeonset. When presented at 0°, there was a positive displacementduring this period, implying that the second bar was displacedin the direction of the saccade. When the bar was displayed at20°, however, the displacement occurred in the opposite direction,consistent with previous results of this report. After the eyesbegan to move, the pattern of the results changed as the eye movementdisplaced the retinal position of the bars. It is notable thatbars displayed near 10° (the saccadic target, the main focus ofcompression) were never seen as being offset, at any delay, evenwhen eye movements caused them to be painted at different positions.The results for bars at 0 and 20° show very clear signs of bothdisplacement and compression before saccades, without relyingon absolute judgment relative to an external ruler.

Effect of simulated saccades on apparent position
Time course of localization To disentangle the effects of image motion and displacement from more central effects accompanying saccades, we repeated someof these experiments with simulated saccadic movements. Observersviewed the display through a large mirror that displaced the wholescene, including the display screen and its surround, through20° at saccadic speed. As with the first experiments, observerswere required to report the apparent position of equiluminantbars displayed at various times relative to the onset of the mirrormotion.

Figure 10, open circles, shows the results for bars displayed at position 0. For comparison data collected with real saccadesunder otherwise identical conditions have been replotted fromFigures 2 and 3 (small squares), together with the model fit.At first glance the results seem similar, with an early mislocalizationin the direction of motion, but there are some interesting differences.The first is that the mislocation in the simulated saccades istypically of greater magnitude than during real saccades, oftenup to 20° (the size of the displacement), whereas the mislocalizationduring real saccades never exceeded 10°. Another clear differenceis that during the simulated saccades, the mislocalization commencedfar earlier, even 200 msec before movement onset, whereas thesaccadic results were all ~0° for times less than 50-60 msec.There was also considerably more scatter in the data for simulatedsaccades over the period preceding the motion than observed withreal saccades.
Fig. 10. Apparent position of bars before, during and after simulated saccades, produced by displacing the image 20° rightward at saccadicspeeds. The results are shown by the large open circles. The smallsquares show the results during saccades (replotted from Figs.2, 3) for comparison. The dotted line shows the physical displacementof the bar caused by the mirror.
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Figure 10, dotted line, shows the physical effect of the mirror motion, assuming a "photographic" retina. The comparison rulercame on 500 msec after the mirror motion, so judgments with themirror in its final position should be veridical. Before thattime, the point of retinal stimulation will be systematicallyshifted by the mirror, as indicated by the dotted line. The datafollow this prediction reasonably well for 0 < t < 150 msec butbegin to fail for times before t = 0. There is also considerablescatter over this region, and the observers complained that thetask was very difficult.
Effect of spatial position To examine whether the effects of the simulated saccades varied with space, observers were asked to report the apparent positionof bars displayed at various spatial positions, just before themirror started to move (t $approx$ $-$ 20 msec). Figure 11 shows the resultsfor the two observers. The bars were always seen displaced inthe direction of the motion, with no tendency for the displacementto reverse for positions beyond the saccadic target (compare withFigs. 5, 6 for the saccadic results). Furthermore, the amountof displacement was quite constant with spatial position. Thelines through the data are linear regressions, having slopes of1.2 and 1.1 for M.C.M. and J.R., respectively. This is certainlynot consistent with compression, which would produce slopes ofless than unity.
Fig. 11. Apparent position of bars presented at random positions just before 20° saccadic-like motion (t = 64-20 msec). Bars were systematicallymislocalized against the direction of motion by a similar amountat all positions. The regression lines have slope greater thanunity (1.1 for M.C.M., 1.2 for J.R.), showing that there is nocompression (if anything, a slight expansion) of space with simulatedsaccades.
[View Larger Version of this Image (13K GIF file)]

Vernier alignment One of the most powerful pieces of evidence of mislocalization (in both directions) before saccades was given by the estimatesof apparent vernier offset of two colinear half-bars presentedat different times (results shown in Fig. 9), which did not relyon judgments relative to some external ruler. We repeated thisfor the simulated saccade for bars presented at position 0. Theresults, shown in Figure 12, are quite different from those obtainedin real saccades. In the critical period $-$ 100 < t < $-$ 75 msec (whenboth were displayed before the movement), the bars were seen tobe aligned, compared with the large and systematic apparent offsetobserved with real saccades. The dashed lines show the predictionsbased on retinal displacements caused by the mirror movement.The data follow this physical prediction quite well, althoughthe data of M.C.M. tend to underestimate the magnitude of theoffset by about 30%.
Fig. 12. Apparent separation of colinear half-bars presented with a 75 msec asynchrony at various delays relative to the onset of a20° saccadic-like movement (analogous to the experiment of Fig.9). The dotted lines show the physical separation caused by themotion of the mirror during stimulus presentation. The data followthis prediction quite well (except for a tendency of M.C.M. tounderestimate the displacement). There was no mislocalizationbefore $-$ 75 msec (indicated by the left vertical dashed line),when both bars were displayed to stationary retinas (compare withFig. 9).
[View Larger Version of this Image (22K GIF file)]

Thus it can safely be concluded that effects of saccades on apparent direction are not entirely attributable to the displacementcaused by the saccade or to the sense of motion created by itor by masking attributable to image motion.

Spatial distortions during real and simulated saccades
The results to date suggest that saccades can produce strong visual compression, especially toward the saccadic target. Imagemotion of comparable speed and duration does not produce similareffects. We explored the generality and strength of the compressionby examining the appearance of complex natural scenes and multiplestimuli around saccadic onset.

We first looked informally at the effects of saccades on natural scenes by briefly presenting a variety of natural scenesand portraits to observers and asking them to report on theirappearance. When the images appeared just before saccadic onset,the scenes seemed to be compressed along the direction of thesaccade, around the saccadic target (for example, see Ross etal., 1997). All observers, both trained and naive, agreed aboutthe compression, although there were subtle differences in exactlyhow they perceived the scenes. During simulated saccades withthe moving mirror, no such compression occurred.

To quantify these effects, we displayed multiple bars (between 0 and 4) around the saccadic target at different times andasked observers to report how many they saw. The bars could occupysome or all of four possible positions around the saccadic target(at 10°): 1, 7, 13, and 19°. The number of bars, the positionsto which they were displayed, and their delay were varied at random.The results for two trained observers making 20° left-to-rightsaccades are shown in Figure 13. Observers never reported seeinga bar when none had been displayed (Fig. 13, circles) and alwaysreported one bar when only one was displayed, no matter whereit fell (Fig. 13, squares). With multiple bars, however, both observerstended to underestimate bar number during the critical periodpreceding saccade onset. Four bars were typically seen as oneduring this period. Note that it would be difficult for observersto bias these results, because they did not know when the barswere displayed or how many there were in a given trial.
Fig. 13. Observers were asked to report how many bars they saw displayed. Multiple bars (between 0 and 4) were displayed simultaneouslyaround the saccadic target, at some or all of four possible positions:1, 7, 13, and 19°. The number of bars, the positions to whichthey were displayed, and the display time were randomized (exceptthat 4 bars was more frequent than the other possibilities). Theresults show that there were no false-positives (zero bars werealways reported as such), and single bars were always seen, irrespectiveof their position. However, multiple bars tended to be grosslyunderestimated when displayed during the interval near the startof each saccade; they tended to collapse to a single bar.
[View Larger Version of this Image (23K GIF file)]

Results similar to those reported here have been obtained with naive observers (see Ross et al., 1997). Furthermore, literallydozens of visitors to our laboratories have verified the maineffect, that four bars presented just before a saccade are seenas one.

Figure 14 shows the results with the simulated 20° saccades under similar conditions. Observers occasionally underestimatedbar number around the time of image motion but never erred bymore than one bar.
Fig. 14. Observers were asked to report how many bars they saw in a display (similar to Fig. 14) but with simulated rather than realsaccades. Observers sometimes reported four bars as three or threeas two (possibly because of the eccentricity of the bars) butdid not show the large and systematic underestimation seen withreal saccades.
[View Larger Version of this Image (22K GIF file)]

Mathematical model of the results
All of the curves passing through the data in the previous graphs were derived with a two-component model, described in thissection. The first component, O(t), represents the origin of theinternal coordinate system, which shifts from the fixation (F₀)to the saccadic target position (F₁), mimicking closely the intention-to-movesignal of the von Holst and Mittelstaedt (1950) model. The shiftcommences before the initiation of the saccade and proceeds graduallyover time following a cumulative gaussian function:

(1)

where t is time relative to saccadic, and $tau$ ₀ and $sigma$ are free parameters that describe the peak time and spread of the gaussianfunction. An example of the function O(t), used to fit the dataof subject M.C.M., is illustrated in Figure 15A.
Fig. 15. Illustration of the functions that change the origin of the internal coordinate system [O(t); Eq. 1] and the compression ofthe spatial metric [ $phi$ (t); Eq. 2]. The dotted line illustratesthe time course of the saccades, from $-$ 10 to 10°. See MathematicalModel of the Results for full details of the model.
[View Larger Version of this Image (20K GIF file)]

The second component of the model modulates the metric of the internal space (expressed in units of retinal eccentricity).During fixation this is equal to identity but nearly vanishesin proximity of the saccade:

(2)

where a₀, t₁, and $sigma$ ₁ are free parameters describing the strength and time course of the compression (see Fig. 15B).

Having defined the origin shift and the metric compression functions, it is now possible to express the apparent position,P(x,t), as a function of the retinal eccentricity:

(3)

where E(x,t) is the retinal eccentricity of the stimulus defined as the difference between the stimulus position (in space;x) and the position of the eye. Sign is the sign function, andS = (F₁ $-$ F₀)/2 is half of the amplitude of the saccade. The eyemotion was modeled by assuming constant velocity (v) for the durationof the saccade (t_f), flanked by zero velocity fixations(a reasonably close approximation under these conditions; Carpenter,1988):

(4)

The model uses five free parameters that were determined separately for each subject to obtain the best overall fit for allof the data collected for that subject. The values of all of theparameters are reported in Table 1. The gaussian function determiningthe origin shift is very similar for all subjects (with the exceptionof M.D.), having the same spread of about 40 msec and peak positionvarying by <5 msec. The spread of the collapse function variesmore between subjects, but the minimum of the function variesvery little in position and amplitude. Given this small variability,there are probably less than five useful free parameters.

The change-of-origin signal O(t) has a time constant similar to that of the saccade. However, it precedes the saccade andreaches 50% of its final value at the onset of the saccade and90% of it by the end of the saccade. The compression signal isalso gradual, with a smaller time constant, but it reaches itsminimum at about saccadic onset.

The above model provided a satisfactory fit for all observers except M.R.D. This subject showed an extremely strong compressionfor large saccades, whereas his results for smaller saccades weresimilar to those of the other subjects. To simulate this differentialeffect, it was necessary to consider that the planned displacement(F₁ $-$ F₀) induced by the saccade was smaller than the effectiveone for the large saccadic condition. We assumed that the plannedsaccade was always 3° for all of the saccadic amplitudes tested(20, 10, and 2.5°).

To model both equiluminance and luminance apparent position data, it was necessary to take into account the faster transmission(or integration time) of the luminance response. This was achievedby introducing a delay of 10 msec for the origin shift and thecompression signals. Interestingly, the delay needed to simulatethe data corresponds quite closely to that evaluated psychophysicallyin a separate study under similar light and adaptation conditions(Burr and Morrone, 1993).

DISCUSSION

Comparison with previous studies
Several previous psychophysical studies have demonstrated anticipatory, presaccadic displacement of flashed stimuli in thedirection of saccades, up to 100 msec before they start, bothin total darkness (e.g., Matin, 1972; Honda, 1991; Schlag andSchlag-Rey, 1995) and with visual referents present (Honda, 1993,1995). The displacement we find is maximal in the 25 msec beforesaccades and depends on stimulus position; it is in the oppositedirection for stimuli beyond the end point of a saccade. Therehave been previous reports showing a dependency of perisaccadicmislocalization on spatial position (Matin and Pearce, 1965; Bischofand Kramer, 1968; O'Regan, 1984; Honda, 1995), but none of thesefound a reversal in direction as we do or pursued their findingsto demonstrate compression with multiple targets or other techniques.O'Regan (1984) attempted to explain position dependency as anartifact arising from differences in visual persistence at differenteccentricities, but this explanation would have difficulty explaininghow four bars, each perfectly visible individually, could mergeinto one, and how even natural scenes are altered in appearanceby saccades in ways consistent with errors in the location ofsingle targets. Perhaps the most convincing evidence for simultaneousmislocalizations in two different directions comes from estimatesof vernier offset, particularly when both half-bars are presentedbefore the eyes move. These results (Fig. 9) are not confoundedby movements of the eyes or by strategies used to locate barsin space.

Several recent studies, conducted under conditions different from ours, show target mislocalizations in the direction of thesaccade, even for stimuli past the saccadic target (e.g., Miller,1996; Cai et al., 1997). We can only speculate on the reasonsfor the discrepancy between their results and ours. Perhaps themajor difference is that our studies were performed at photopicluminances, whereas those not finding the inversion were performedin the dark. It is possible that the reversal in direction dependson visual cues, although these by themselves are not sufficientto cause the effects (as shown by the simulated saccades). Alternatively,visual function could be qualitatively different at low luminancelevels. Other details in the techniques were also different, suchas exposure duration and the task required of the observer. Furtherresearch would be need to determine the main reason for the discrepancy.

Real versus simulated saccades
It has been suggested that errors of location before and during saccades may not result from reorganization of linkages betweenretina and space but from image motion (MacKay, 1970; O'Regan,1984; Sperling, 1990). Our control studies show that this is notthe case under the conditions of these experiments. Simulatedsaccades affect target localization, but the effects were quitedifferent in magnitude, time course, and even sign from thoseduring eye movements, and there was no evidence of compressionwith multiple targets. When four bars were shown simultaneouslyin the simulated saccade condition, subjects almost always reportedfour and never fewer than three. This contrasts with the realsaccade condition, in which often only one bar was reported whenfour were displayed in the 50 msec before a saccade.

Figure 10, dotted line, shows the physical displacement caused by the mirror, predicting performance based on a cumulativephotographic record of retinal images, both of the bar and thelater ruler. The results follow this prediction quite well whilethe mirror is in motion and for a short time before. For earlierpresentations, however, there is a very large scatter, over thefull 20° range. This could suggest the action of two processes:an absolute judgment based on the retinotopic record indicatinga bar located at 20° and a relative judgment based on the positionwithin the screen, indicating a bar at ~0°. Only at presentationslong before motion onset did observers reliably report seeingthe bar at position 0, presumably because the retinotopic trace,or memory, had completely faded. Not only was there considerablescatter in the data, but observers reported considerable difficultyand conflict. Interestingly, this conflict seems not to arisefor real saccades, for which the range of errors was less, andobservers were more comfortable with the task. Nevertheless, oneshould be cautious about using this type of task for measuringsaccadic mislocalization, given the ambiguity it causes in normalviewing. For this reason, we place greatest confidence in thevernier task, in the interval t < $-$ 75, when both bars are displayedto stationary retinae. There was a strong position-dependent mislocalizationduring saccades but no effect for the simulated saccades (compareFigs. 9, 12).

Model and its biological basis
We can model our results for real saccades with two assumptions: (1) that there is a shift in the assumed external referencepoint for the center of the fovea; and (2) that retinal eccentricitiesare subjected to horizontal compression. In the present implementationthe model is simple and computationally economical. Two very coarsesignals are sufficient to model all of the data reported here,including the counterintuitive retinotopic dependence of the localizationerror. The shift signal is a linear additive process, whereasthe metric modulation is nonlinear. In a previous simulation ofthe data (Ross et al., 1997), the model used a compression signal,constructed by fading out an old origin signal and fading in anew one, that simply multiplied the metric. However, to improvethe fit, the compression signal needs to depend on eccentricity,increasing the complexity of the model. In the present simulationthe collapse is achieved by means of a reduction in the valueof an exponent and can be thought of as a momentary disconnectionor gating of the eccentricity-dependent remapping of visual input.

At this stage it is difficult to speculate about the neurophysiological substrate mediating the operations defined by theequations of our model. However, it is interesting to note thatmany visual centers of the brain possess the necessary hardware.The shift in external reference point assumed in our model isconsistent with anticipatory shifts in receptive field locationof neurons in the LIP and in the superior colliculus (Goldberget al., 1990; Duhamel et al., 1992; Colby et al. 1995; Walkeret al. 1995). Many cells in these areas respond to stimuli thatwill be brought into their receptive field by the saccade. Theseanticipatory responses are found to occur ~50 msec before saccadesbegin, near the time when we find the largest position shifts.In most of the work reported to date, receptive fields shift inthe direction of the saccade, consistent with our results whenstimuli do not fall beyond the saccadic target. Recently, however,Ben Hamed et al. (1996) have reported more complex behaviors inLIP neurons before saccades. The receptive fields can change ina variety of bizarre ways, including translation in directionsother than that of the saccade or expansion or contraction ofreceptive field size. These results, if confirmed, may providea biological substrate for the compression component of our model.

Another interesting property of parietal neurons in areas 7A and LIP (and in V3 and V6) is that many vary their response gainwith gaze position (Andersen et al. 1985, 1990; Galletti and Battaglini,1989; Battaglini et al. 1996). Zipser and Andersen (1988) havesuggested that the change in gain could be instrumental in transforming,via a distributed network, the internal retinocentric coordinatesto oculocentric coordinates and ultimately to an allocentric system.In the model of Zipser and Andersen (1988), the gain modulationis multiplicative in nature, as is the compression in our model.It is therefore feasible that the gaze-dependent modulation ofthese neurons could also cause compression of the metric, if theirgain were drastically reduced at the moment of transition. Interestingly,a nonvisual signal with appropriate time course does exist insome LIP neurons (Andersen et 1990, their Fig. 4); these neuronsare insensitive to visual or attentive processes and have a highresting discharge that is inhibited just before saccadic onset(like the fixation neurons in the superior colliculus; Wurtz,1996).

LIP is strategically positioned to integrate visual input, from both the magnocellular and parvocellular pathways (Fellermanand Van Essen, 1991; Merigan and Maunsell, 1993). Recent evidence,partly from our laboratories, suggests that the magnocellularpathway is inhibited during saccades, but the parvocellular pathwayis not (Burr et al., 1994; Uchikawa and Sato, 1995; for review,see Ross et al., 1996a). It is possible that the parvocellularsystem can analyze the transient stimuli used in this study forform, orientation, and color but is unable to make an overallspatial analysis of the whole visual scene (purported to be therole of then magnocellular-dominated dorsal stream; e.g., Mishkinet al., 1983). This reduced capacity to map visual space may restrictthe space within which transient stimuli can be located. Thisis unlikely to be a problem under normal viewing conditions, inwhich saccadic velocities of continuous images are beyond theresolution of the parvocellular system (Merigan, 1990), and anyerroneous perception during saccades will be masked by the clearimages during periods of fixation (MacKay, 1970; Matin, 1972;Campbell and Wurtz, 1978).

FOOTNOTES

Received May 8, 1997; revised July 3, 1997; accepted July 25, 1997.

This work was supported by the Australian Research Council, the Italian Consiglio Nazionale delle Ricerche, and a Framework4 Biomed Grant (BMH4-CT96-1461).

Correspondence should be addressed to Dr. David Burr, Istituto di Neurofisiologia del Consiglio Nazionale delle Ricerche,Via S. Zeno 51, 56127 Pisa, Italy.

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