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The Journal of Neuroscience, October 15, 1999, 19(20):9098-9106
The Spectral Main Sequence of Human Saccades
Mark R. Harwood, Laura E. Mezey, and Christopher M. Harris Department of Ophthalmology and Visual Sciences Unit, Great Ormond Street Hospital for Children NHS Trust and Institute of Child Health, University College London, London WC1N 3JH, United Kingdom
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Despite the many models of saccadic eye movements, little attention has been paid to the shape of saccade trajectories. Some investigators have argued that saccades are driven by a rectangular "bang-bang" neural control signal, whereas others have emphasized the similarity to fast arm movement trajectories, such as the "minimum jerk" profile. However, models have not been tested rigorously against empirical trajectories. We examined the Fourier transforms of saccades and compared them with theoretical models. Horizontal saccades were recorded from 10 healthy subjects. The Fourier transform of each saccade was accurately computed using a padded fast Fourier transform (FFT), and the frequencies of the first three minima (M1, M2, M3) in each energy spectrum were measured to a precision of 0.12 Hz. Each subject showed near-linear trends in the relationships among M1, M2, and M3 and the reciprocal of duration (1/T), which we call the "spectral main sequence." Extrapolation of plots did not pass through the origin, indicating a subtle departure from self-similarity. Bivariate confidence regions were established to allow for slope-intercept variability. The nonharmonic relationships seen cannot arise from a rectangular saccadic pulse driving a linear ocular plant. The relationships are also incompatible with minimum acceleration, minimum jerk, or higher-order minimum square derivative trajectories. The best fits were made by trajectories that minimize postmovement variance with signal-dependent noise (Harris and Wolpert, 1998
). It is concluded that the spectral main sequence is exquisitely sensitive to the saccade trajectory and should be used to test objectively all present and future models of saccades.
Key words: saccadic eye movements; human; Fourier transform; saccade trajectories; bang-bang control; minimum variance model
INTRODUCTION
Saccades are the fastest type of eye movement, reaching hundreds of degrees per second and are usually completed in tens of milliseconds. Despite their speed, saccade trajectories tend to be remarkably stereotyped both within and across individuals. The duration, T, and peak velocity, PV, of saccades increase monotonically with amplitude, A, of the movement in a more-or-less consistent way, which has been called the "main sequence" (Bahill et al., 1975b
Despite the numerous models of the saccadic system, there has been surprisingly little attention paid to the precise shape of velocity profiles. Descriptively, Yarbus (1967)
In terms of explanatory models, probably the most common view is that trajectories are time-optimal by bringing the eye to its final position in the shortest possible time (Clark and Stark, 1975
An alternative, kinematic approach to explain trajectories, which consequently is independent of the choice of plant, can be adopted. The similarity between the trajectories of saccades and fast arm movements has been emphasized previously (Abrams et al., 1989
Although temporal MSD profiles appear to fit saccades well, why movements should be selected for smoothness is unclear. Recently Harris and Wolpert (1998)
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Figure 1. Similarities of MSD and MV model trajectories (see Materials and Methods). Shown are velocity profiles of minimum acceleration, jerk and snap (MA, MJ, MS), minimum variance second and third order (MV2, MV3 with third time constant = 10 msec); the descriptive Yarbus model (Y) is also shown for its similarity to MA. The time-origin is centered at peak velocity, which has been normalized to unity. Trajectories have been scaled in time so that velocity is 0.25 at ±0.5 time units, except in MV3 where a slight asymmetry precluded the alignment at +0.5 time units. For clarity, the order with which the profiles reach zero velocity has been mirrored in the legend. The MV profiles are based on an amplitude of 5° and duration 38 msec.
It is difficult to discriminate between these models by conventional means because of the smoothness of movements, recording noise and limited bandwidth, and the uncertain plant. Defining trajectories with higher derivatives, such as acceleration, jerk, or snap, becomes virtually impossible because of noise and the distortion caused by the low-pass filtering of any eye movement recording equipment.
In this study we compared actual saccade trajectories with model trajectories using Fourier transforms. The Fourier energy spectra of a primate saccade has a characteristic and distinctive sequence of sharp local minima at frequencies that depend on the duration and overall shape of the trajectory (Harris et al., 1990
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Figure 2. Fourier energy spectra of velocity profiles plotted on log10-linear axis. Energy plots are shown for the models in Figure 1 and for the rectangular pulse bang-bang model (BB). For clarity the sharpness of the minima has been reduced, and the ordinates have been offset. The minima frequencies and their ratios are summarized in Table 3.
MATERIALS AND METHODS
Horizontal eye movements were recorded using an infrared limbus eye-tracker (IRIS, Skalar Medical, Delft, The Netherlands). This apparatus has a horizontal linear range of ±25° with an accuracy of 3 minarc. The frequency response has a 3 dB attenuation at 100 Hz and can readily detect the first three minima for saccades over 4°.
The experimental protocol was approved by the Institute of Child Health Ethics Committee, and informed consent was obtained from all volunteers. Saccades were recorded from 10 healthy adults (6 males, 4 females) with normal vision aged 25-35 years (mean = 29.3 years). Subjects sat facing a white flat screen in dimmed room lighting (2 cd/m2); their heads were supported in a chin rest and stabilized by a pair of ear muffs. Only recordings from the left eye were analyzed.
The stimulus was a red (670 nm) laser circular spot with a diameter of 1 mm projected onto the screen via a galvanometer mirror, which was under computer control. The screen was 89 cm from the subject, and the spot subtended an angle of 4 minarc at the retina.
Each trial started with the target spot in the center, which after a random time delay (1.1-2.5 sec) stepped to a peripheral position, where it remained for 1.5 sec before returning to the center for the start of the next trial. Each subject was presented with 100 trials, with 10 trials for each of 10 different peripheral target positions: 2.5, 5, 10, 15, and 20° to the left and right of the central fixation target. Trials were presented in a fixed pseudorandom order. Only saccades to centrifugal target jumps were recorded.
Before trials were presented, a calibration procedure was performed in which the subject was asked to fixate the spot at 12 different predetermined horizontal locations between +20° and
20°. A linear regression was produced on-line, and if necessary, the apparatus was readjusted and the calibration procedure repeated until a linear relationship between eye position and target position was obtained.
Analysis. All saccades were previewed to exclude trials with anticipatory saccades and blink artifacts. Eye position was sampled at 1 kHz. Eye velocity and acceleration were estimated from the eye position using a zero-phase low-pass digital filter (3 dB point = 64 Hz). The onset of a saccade was defined as the first point at which the velocity was continuously above 10°/sec for at least 10 msec. Similarly, the offset was defined as the last point after the peak velocity to be above 10°/sec. To ensure that the saccade trajectory was always fully captured for Fourier analysis, the extracted data segment went 5 msec beyond the identified start and end points of the saccade.
The Fourier transform of a saccade was computed from the unfiltered position signal using a standard fast Fourier transform (FFT). This involved extending ("padding") the extracted data segment at either end to form a dataset comprising 8192 points, then multiplying by a cosine window, and then applying the FFT. This avoided problems associated with truncation and wrap-around (Harris, 1998a
2,
SMS confidence regions. To study possible relationships among the four variables (M1-M3 and reciprocal duration, 1/T), linear regressions were performed for each subject. Given the presence of unavoidable measurement errors and biological variability in the frequencies and durations, the best unbiased intrasubject estimate of the slopes and intercepts was obtained by bivariate linear regressions of M1, M2, and M3 versus 1/T, M2 and M3 versus M1, and M3 versus M2.
Sample differences in the linear regression will lead to covariance between the individual samples of slope and intercept. The codependence can be seen in the example in Figure 3, where higher regression slopes are associated with lower regression intercepts, and vice versa. To obtain an overall estimate of the population intercept and slope, bivariate confidence regions were constructed according to n(µ
1(µ
(p, n
) and intercept (x = µx
) components, we have for two dimensions a region bounded by the ellipse of the form ay2 + bxy + cx2 = d, centered on (
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Figure 3. Illustration of bivariate confidence regions. Ellipses show 95% (inner) and 99% (outer) confidence regions for the estimate of the population slope and intercept of the individual M1 versus 1/T regressions ( ). The center, (
Models. Eight models were considered: the descriptive Yarbus model (Y); MSD profiles that minimize the square of acceleration (MA; a parabola), the square of jerk (MJ), and the square of snap (MS); the bang-bang rectangular pulse; and minimum variance profiles with second-order and two with third-order ocular plants. The gamma function model was not considered because it has no local minima in its energy spectrum.
The Fourier energy spectra of the Yarbus and MSD models can be found analytically and are shown in Table 1. Each of these models inherently assumes that velocity profiles of saccades for different amplitudes have the same basic shape but differ only in velocity- and time-scales. Such profiles are self-similar because it is possible to find individual scale factors in velocity and time so that the set of functions would superimpose (for a given model) (Fig. 4A). The Fourier transform preserves self-similarity. Therefore, the ratios of the minima to each other and to reciprocal duration (1/T) are invariant to changes in amplitude, peak velocity, and duration of the trajectory. Linear plots of the minima against each other or against 1/T must yield straight lines passing through the origin. This can be seen in Figure 4B, where scaling amplitude scales the overall energy for a given duration but does not affect the frequencies at which the minima occur; scaling duration has an inverse relationship on the minima frequencies, but the ratios between the minima are constant, as demonstrated for M1 and M2 in the inset. In this study only the ratios among M1, M2, and M3 and the relationship with M1-M3 and 1/T were investigated.
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Table 1. Model velocity formulae and their analytical Fourier energy spectra
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Figure 4. Illustration of self-similarity using a parabola as an example. A, The basic temporal shape (curve a) remains the same with arbitrary scaling in time (curve b) or in velocity (curve c) or both (curve d). B, The Fourier transform of the curves in A. Scaling in velocity amplitude scales the overall energy without affecting the frequency at which the minima occur, whereas scaling in time has an inverse relationship on the minima frequencies. The ratios between the minima are unaffected by the time or amplitude scaling for a given shape, as shown in the inset for the first two minima (see Materials and Methods).
Bang-bang control theory is the optimal strategy to reach the target in the minimum time with the inherent assumption that the ocular plant is linear. Bang-bang control has been proposed previously (Enderle and Wolfe, 1987
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Figure 5. Illustration of bang-bang control with a second-order ocular plant. A, Simplest control is a rectangular pulse in which maximum agonist signal is maintained. Different amplitudes are achieved by changing the duration of the rectangle (dotted line); hence pulses are self-similar (see Materials and Methods). B, Velocity trajectories resulting from A are not self-similar.
Minimum variance trajectories have velocity profiles that minimize the position variance over a postmovement period, where the SD of the noise on the control signal increases with the magnitude of the mean control signal (signal-dependent noise). The optimal profiles were found numerically, assuming that the SD of the noise was proportional to the mean of the control signal, and using the same parameter values used by Harris and Wolpert (1998)
RESULTS
All subjects produced saccades with the typical temporal main sequence (TMS) (Fig. 6) as described by many previous investigators. In particular, duration was always a linearly increasing function of amplitude for saccades over ~4°, and linear regression over the linear portion (4-20°) gave a slope (T-A slope) range of 2.22-3.37 msec/° and an intercept (T-A incpt) range of 20.3-30.4 ms (Table 2). The ratio of peak velocity to mean velocity, which we call Q, tended to be roughly constant for different amplitudes, with a value ranging from 1.54 to 1.80. These temporal measures are similar to other reports (Becker, 1989
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Figure 6. Time-domain analysis of saccades showing typical temporal main sequence relationships. A, Peak velocity versus amplitude. B, Duration versus amplitude. C, Peak velocity × duration versus amplitude. Regression line constrained through origin gives the ratio of peak velocity to mean velocity, Q.
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Table 2. Summary of individual temporal and spectral main sequence parameters
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Figure 7. Typical velocity trajectories of saccades with superimposed MV trajectory. Shown is near symmetry for low amplitudes, becoming more skewed for large amplitudes. Plots were aligned approximately with peak velocity, and amplitudes were 5.4° ( ), 10.3° (
), and 20.0° (
). The lines show the MV (with third time constant of 4 msec) profiles for matched amplitudes and durations.
Fourier analysis showed energy spectra with usually clearly defined minima occurring at nonharmonic frequencies, as shown by the typical example in Figure 8. These energy spectra were similar to those published previously (Harris et al., 1990
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Figure 8. Typical energy spectrum of the velocity profile of a saccade (inset) with amplitude 9.5°, duration T = 47 msec (1/T ~ 21 Hz). Log energy is plotted against linear frequency. Only the first three minima are shown.
Plots between M1-M3 and the reciprocal of duration (1/T), as well as between M2-M3 and M1, and M3 and M2, revealed approximately linear relationships, as seen in Figure 9A,B for a typical subject. To compare these results with model predictions, the slope and intercept were estimated by bivariate linear regressions (see Materials and Methods) and are summarized in Table 2. Subjects showed broadly similar results for each regression, but to take account of intersubject variability in estimating the population slope and intercept, bivariate confidence regions were plotted (Fig. 10) (see Materials and Methods).
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Figure 9. Typical SMS for an individual subject. A, Plots of minima frequencies M1, M2, and M3 versus reciprocal duration of saccade (1/T) for the same subject as in Figure 6. B, Plots of M2 and M3 versus M1, and M3 versus M2. Note near-linear relationships in all plots. Dotted lines show bivariate linear regressions. Solid lines indicate predicted harmonic relationships for the rectangular bang-bang control pulse.
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Figure 10. Comparison of SMS confidence regions with models. Ellipses show 95% (inner) and 99% (outer) confidence regions for the group SMS (see Materials and Methods). Predicted rectangular BB model (square), MSD models (circles, size in increasing order of derivative: acceleration, jerk, snap), Yarbus model (cross-hair), and MV models (triangles, size in increasing order of third time constant: t3 = 0, 4, 10 msec) are plotted. The equations for the 95% (d = 1.004) and 99% (d = 1.946) ellipses are also shown. All model slopes and intercepts are summarized in Table 3.
Comparison with bang-bang control
The simplest bang-bang control signal is the rectangular pulse, which has energy minima at harmonics of the reciprocal of the pulse duration (Fig. 9, solid lines; Fig. 10, squares). It was clear from individual SMSs that there is no harmonic relationship among the minima. The predicted rectangular pulse slopes and intercepts consistently fell far outside the 99% confidence regions and were rejected at the p < 0.001 level.
Comparison with MSD profiles
Inspection of MJ slopes alone suggests a close fit to the observed means (Tables 2, 3). However, with the exception of MJ in Figure 10C (p = 0.065), and MJ and MA in Figure 10F (pMJ = 0.037, pMA = 0.34), all MSDs fell outside of the 99% confidence regions. Moreover, the M3 versus M2 ratio seen in Figure 10F is the least discriminating of the SMS relationships studied because all the models predict very similar values (note scale in Fig. 10F). Although MA provides a poor fit, it can be seen to fall closer than MJ to the confidence regions in all but B and C in Figure 10, which in turn was much closer to the confidence regions than MS. The MS model was consistently rejected at the p < 0.001 level, and higher-order MSD models diverge farther from the confidence regions. It can be seen that the descriptive Yarbus model is very close to MA. This is not surprising because the cosine function in Table 1 can be quite well approximated by a parabola (Fig. 1). Five out of six of the predicted slopes and intercepts for MA, MJ, and Y models were rejected at the p < 0.05 level.
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Table 3. Comparison of model regressions Comparison with MV profiles
MV profiles depend on the type of signal-dependent noise in the motoneuron signal and the specific dynamic response of the ocular plant. We tested examples as described by Harris and Wolpert (1998)
The sensitivity of the theoretical SMS can be seen particularly clearly in Figure 10. A change in the plant model from second to third order with a time constant of just 4 msec had a substantial effect on predicted slope and intercept. Increasing the third time constant to 10 ms had a further significant effect on how well the observed SMS was fitted. The second-order model fell within the 95% confidence bounds for all the interminima ratios but was rejected at p < 0.01 for all the minima against 1/T. The intermediate plant provided a good fit of all the observed SMSs, being within the 95% confidence regions and close to the sample mean. The third model showed varying agreement with the empirical data. It was just outside the 99% confidence regions for half of the relationships, but was never far from the mean slope and intercept.
DISCUSSION
All subjects showed systematic relationships among the frequencies of the energy minima and the reciprocal of the duration of the saccade (1/T). We have called these empirical relationships the SMS, which is quite distinct from the traditional TMS that relates peak velocity and duration to amplitude (Bahill et al., 1975b
Explanatory models of the neural pulse
The saccadic pulse has often been assumed to be rectangular in shape, reflecting the belief that it is the optimal bang-bang control signal (Enderle and Wolfe, 1987
In the theory of optimal control of saturated linear systems, bang-bang control may require more elaborate driving signals, where one or more switches occur between maximum agonist activity and maximum antagonist activity during the movement (Bryson and Ho, 1975
Explanatory kinematic models
Kinematic models assume that a movement trajectory optimizes some trajectory parameter rather than being constrained by the driving signal or muscle dynamics. On the basis of the smoothness and symmetry of fast arm movement trajectories, Hogan (1984)
Wiegner and Wierzbicka (1992)
Explanatory MV models
Apart from the poor fit to the SMS, a serious conceptual problem with the above MSD models (whether for arm or saccadic movements) is their assumption that "smoothness" is the fundamental kinematic goal of the movement. Although both fast arm and eye movements do indeed appear to be smooth, it is not obvious why smoothness should be so important, and it can hardly be considered to be an "explanation." Instead, we have argued that smoothness would arise if the goal of the movement were to minimize position variance at the end of the movement of a given duration in the presence of signal-dependent noise (Harris, 1998b
Although the MV profiles appear similar to MSD profiles (Fig. 1), they become increasingly asymmetric with duration (Harris and Wolpert, 1998
We emphasize that the good fit of this MV trajectory does not prove that saccades follow this MV trajectory; rather, we have failed to reject this model on the basis of the SMS. Other models may fit the data as well. We also emphasize that the SMS characterizes the shape of trajectories and not how they are generated. One could doubtless conceive of an internal feedback controller to realize MV trajectories, but this remains to be explored.
In addition, there are two important caveats to be aware of. First, by constructing a confidence region we are in effect "averaging" across individuals and hence generating a composite SMS. Individual differences in saccade trajectories could reflect optimal trajectories with different constraints (e.g., slightly different plants), but they could also reflect failure to find the precise optimum. Indeed, we have argued that some variability around the optimum would be essential to allow the optimum to be reached on average (Harris, 1998b
Second, our ultimate goal is to understand and model not only saccade trajectories but also their neural commands. In principle, if we have a potentially good model of trajectories we can ask what neural command would give rise to such a trajectory. Thus, Figure 11 shows the aggregate neural command for a second- and third-order MV model. Unfortunately, even for these relatively simple lumped linear models, there are serious difficulties. First, we do not know the time course of the aggregate neural command during a saccade, because it depends on all active excitatory and inhibitory burst units and how they are delivered by the agonist and antagonist motoneurons to their respective extra-ocular muscles. A single motoneuron burst signal may give the impression of a bang-bang control signal, but averaging across burst units has revealed the presence of a small braking pulse (Van Gisbergen et al., 1981
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Figure 11. Neural control signals for MV models. Predicted combined agonist and antagonist motoneuronal firing rate for the second-order MV (solid lines) and third-order MV (dotted lines, t3 = 4 msec) models.
Summary
In summary, we have shown that the Fourier energy spectra of human horizontal saccades in the range of 4-20° in amplitude have minima at frequencies that depend nearly linearly on the reciprocal of saccade duration, which we call the SMS. Unlike the traditional temporal main sequence (Bahill et al., 1975b
FOOTNOTES Received Feb. 16, 1999; revised Aug. 2, 1999; accepted Aug. 2, 1999.
This work was supported by the Medical Research Council Grant G9316292N, the Ormsby Foundation, the Child Health Research Appeal Trust, the Iris Fund, and Help a Child to See.
Correspondence should be addressed to Mark Harwood at the above address.
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Copyright © 1999 Society for Neuroscience 0270-6474/99/19209098-09$05.00/0
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