Preneural limitations on letter identification in central and peripheral vision.

We created a sequential ideal-observer model that could address the question, How much of letter identification performance and its change with eccentricity can be accounted for by preneural factors? The ideal-observer model takes into account preneural factors including the stimulus rendering properties of a CRT display, the optical imaging quality of the eye, and photon capture and sampling characteristics of the cones. We validated the formulation of the model by comparing its performance on simple psychophysical tasks with that of previous sequential ideal-observer models. The model was used to study properties of the image rendering of letters. For example, the model's identification of high-resolution letters (i.e., many pixels per letter), but not low-resolution letters, is largely immune to changes in pixel width. We compared human and ideal-observer letter-identification acuity for the lowercase alphabet at 0 degrees, 5 degrees, and 20 retinal eccentricity. Acuity of the ideal observer for high-contrast letters is approximately seven times better than that of the human observers at 0 degrees. Acuity decreased with eccentricity more rapidly for human observers than for the ideal observer such that the thresholds differed by a factor of 50 at 20 degrees. A decrease in stimulus duration from 100 to 33 ms resulted in no decrease in relative threshold size between the human and ideal observers at all eccentricities, indicating that humans effectively integrate stimulus information over this range. Decreasing contrast from 75% to 25%, however, reduced the difference in acuities twofold at all eccentricities between humans and the ideal-observer model, consistent with the presence a compressive nonlinearity only in the human observers. The gap between human and ideal acuity in central vision means that there are substantial limitations in human letter recognition beyond the stage of photoreceptor sampling. The increasing performance gap between human and ideal-observer performance with eccentricity implicates an increasing role of neural limitations with eccentricity in limiting human letter identification.

[1]  David A. Atchison,et al.  Optics of the Human Eye , 2023 .

[2]  Gordon E Legge,et al.  Psychophysics of reading XX. Linking letter recognition to reading speed in central and peripheral vision , 2001, Vision Research.

[3]  W Seiple,et al.  Duration Thresholds for Target Detection and Identification in the Peripheral Visual Field , 2001, Optometry and vision science : official publication of the American Academy of Optometry.

[4]  C. M. Cicerone,et al.  The spatial arrangement of L and M cones in the peripheral human retina , 2000, Vision Research.

[5]  G. H. Jacobs,et al.  Functional consequences of the relative numbers of L and M cones. , 2000, Journal of the Optical Society of America. A, Optics, image science, and vision.

[6]  L N Thibos,et al.  Relationship between acuity for gratings and for tumbling-E letters in peripheral vision. , 1999, Journal of the Optical Society of America. A, Optics, image science, and vision.

[7]  David Williams,et al.  The arrangement of the three cone classes in the living human eye , 1999, Nature.

[8]  Gordon E. Legge,et al.  Psychophysics of reading. XVIII. The effect of print size on reading speed in normal peripheral vision , 1998, Vision Research.

[9]  C. Cicerone,et al.  Color-opponent sites: Individual variability and changes with retinal eccentricity , 1997 .

[10]  Gordon E. Legge,et al.  Psychophysics of reading—XVI. The visual span in normal and low vision , 1997, Vision Research.

[11]  K. Alexander,et al.  Visual Acuity and Contrast Sensitivity for Individual Sloan Letters , 1997, Vision Research.

[12]  Susana Marcos,et al.  Coherent imaging of the cone mosaic in the living human eye. , 1996, Journal of the Optical Society of America. A, Optics, image science, and vision.

[13]  David R. Williams,et al.  Off-axis optical quality and retinal sampling in the human eye , 1996, Vision Research.

[14]  C. Cicerone,et al.  The spatial arrangement of L and M cones in the living human eye , 1996 .

[15]  N A Brennan,et al.  Distribution of astigmatism in the adult population. , 1996, Journal of the Optical Society of America. A, Optics, image science, and vision.

[16]  P B Kruger,et al.  Accommodation to monochromatic and white-light targets. , 1995, Investigative ophthalmology & visual science.

[17]  Wendy L. Braje,et al.  Human efficiency for recognizing 3-D objects in luminance noise , 1995, Vision Research.

[18]  I Iglesias,et al.  Double-pass measurements of the retinal-image quality with unequal entrance and exit pupil sizes and the reversibility of the eye's optical system. , 1995, Journal of the Optical Society of America. A, Optics, image science, and vision.

[19]  Denis G. Pelli,et al.  The visual filter mediating letter identification , 1994, Nature.

[20]  J. Szlyk,et al.  Temporal properties of letter identification in retinitis pigmentosa. , 1993, Journal of the Optical Society of America. A, Optics and image science.

[21]  David R. Williams,et al.  Serial spatial filters in vision , 1993, Vision Research.

[22]  David Williams,et al.  Modulation transfer of the human eye as a function of retinal eccentricity , 1993 .

[23]  Kristian Donner,et al.  Noise and the absolute thresholds of cone and rod vision , 1992, Vision Research.

[24]  C. M. Cicerone,et al.  The ratio of L cones to M cones in the human parafoveal retina , 1992, Vision Research.

[25]  S J Anderson,et al.  Peripheral spatial vision: limits imposed by optics, photoreceptors, and receptor pooling. , 1991, Journal of the Optical Society of America. A, Optics and image science.

[26]  A. Milam,et al.  Distribution and morphology of human cone photoreceptors stained with anti‐blue opsin , 1991, The Journal of comparative neurology.

[27]  Kenneth R. Sloan,et al.  Packing geometry of human cone photoreceptors: variations with eccentricity and evidence for local anisotropy , 1991, Electronic Imaging.

[28]  B. Boycott,et al.  Retinal ganglion cell density and cortical magnification factor in the primate , 1990, Vision Research.

[29]  A. Bradley,et al.  Theory and measurement of ocular chromatic aberration , 1990, Vision Research.

[30]  C. Curcio,et al.  Topography of ganglion cells in human retina , 1990, The Journal of comparative neurology.

[31]  L. Maloney Confidence intervals for the parameters of psychometric functions , 1990, Perception & psychophysics.

[32]  A. Hendrickson,et al.  Human photoreceptor topography , 1990, The Journal of comparative neurology.

[33]  Kenneth R. Sloan,et al.  Computer methods for sampling, reconstruction, display and analysis of retinal whole mounts , 1989, Vision Research.

[34]  C. M. Cicerone,et al.  The relative numbers of long-wavelength-sensitive to middle-wavelength-sensitive cones in the human fovea centralis , 1989, Vision Research.

[35]  D S Loshin,et al.  Grating Acuity Overestimates Snellen Acuity in Patients with Age‐Related Maculopathy , 1989, Optometry and vision science : official publication of the American Academy of Optometry.

[36]  M W Levine,et al.  Variability in responses of retinal ganglion cells. , 1988, Journal of the Optical Society of America. A, Optics and image science.

[37]  Wilson S. Geisler,et al.  The physical limits of grating visibility , 1987, Vision Research.

[38]  L. Thibos Calculation of the influence of lateral chromatic aberration on image quality across the visual field. , 1987, Journal of the Optical Society of America. A, Optics and image science.

[39]  P Artal,et al.  Determination of the point-spread function of human eyes using a hybrid optical-digital method. , 1987, Journal of the Optical Society of America. A, Optics and image science.

[40]  A. Bradley,et al.  The longitudinal chromatic aberration of the human eye, and its correction , 1986, Vision Research.

[41]  Philip B. Kruger,et al.  Stimuli for accommodation: Blur, chromatic aberration and size , 1986, Vision Research.

[42]  Gordon E. Legge,et al.  Psychophysics of reading—II. Low vision , 1985, Vision Research.

[43]  W. Geisler,et al.  Ideal discriminators in spatial vision: two-point stimuli. , 1985, Journal of the Optical Society of America. A, Optics and image science.

[44]  W S Geisler,et al.  Physical limits of acuity and hyperacuity. , 1984, Journal of the Optical Society of America. A, Optics and image science.

[45]  J. M. Foley,et al.  Contrast masking in human vision. , 1980, Journal of the Optical Society of America.

[46]  K Rayner,et al.  Reading without a fovea. , 1979, Science.

[47]  Chris A. Johnson,et al.  Effect of dioptrics on peripheral visual acuity , 1975, Vision Research.

[48]  N Drasdo,et al.  Non-linear projection of the retinal image in a wide-angle schematic eye. , 1974, The British journal of ophthalmology.

[49]  S M Anstis,et al.  Letter: A chart demonstrating variations in acuity with retinal position. , 1974, Vision research.

[50]  W. Lotmar,et al.  Peripheral astigmatism in the human eye: experimental data and theoretical model predictions. , 1974, Journal of the Optical Society of America.

[51]  A. A. Skavenski,et al.  Miniature eye movement. , 1973, Science.

[52]  H. Bouma Visual recognition of isolated lower-case letters. , 1971, Vision research.

[53]  L L Sloan,et al.  The photopic acuity-luminance function with special reference to parafoveal vision. , 1968, Vision research.

[54]  F. Campbell,et al.  Optical quality of the human eye , 1966, The Journal of physiology.

[55]  Elek Ludvigh,et al.  Extrafoveal Visual Acuity as Measured with Snellen Test-Letters , 1941 .

[56]  E. C. Sanford The relative legibility of the small letters. , 1888 .

[57]  Pablo Artal,et al.  Off-axis monochromatic aberrations estimated from double pass measurements in the human eye , 1999, Vision Research.

[58]  Bosco S. Tjan,et al.  Ideal observer analysis of object recognition , 1997 .

[59]  Walter F. Bischof,et al.  Thresholds From Psychometric Functions: Superiority of Bootstrap to Incremental and Probit Variance Estimators , 1991 .

[60]  D. Pelli The quantum efficiency of vision , 1990 .

[61]  H. Blanchard,et al.  The acquisition of parafoveal word information in reading , 1989, Perception & psychophysics.

[62]  A. Jacobs,et al.  Perception of lowercase letters in peripheral vision: A discrimination matrix based on saccade latencies , 1989, Perception & psychophysics.

[63]  W. Geisler Sequential ideal-observer analysis of visual discriminations. , 1989, Psychological review.

[64]  Kenneth R. Boff,et al.  Sensory processes and perception , 1986 .

[65]  L. Kaufman,et al.  Handbook of perception and human performance , 1986 .

[66]  W S Geisler,et al.  Sampling-theory analysis of spatial vision. , 1986, Journal of the Optical Society of America. A, Optics and image science.

[67]  Jc Joop Jacobs,et al.  The effect of contrast on letter and word recognition , 1981 .

[68]  Julius T. Tou,et al.  Pattern Recognition Principles , 1974 .

[69]  Barbara Elizabeth Roethlein,et al.  The Relative Legibility of Different Faces of Printing Types , 1912 .