Neural theories of simple visual discriminations.

Simple visual discriminations such as detection of presence and recognition of small differences in the spatial and temporal patterns of objects have been explained in some detail in recent years by variants of the physical quantum theory. The present paper summarizes the status of an alternative group of theories, which is classed as neural, primarily to distinguish them from the physical quantum theory, and compares the two groups of theories. The neural theories are models of the visual system as a whole and include assumptions concerning the transformation of stimulus to sensory events, and the decision processes involved in discrimination. They are neural by inference only, and rarely specify the type of neural activity or the neural site at which the events occur. The bulk of the paper is devoted to a description of specific neural theories, attributable to the writer, concerned with (a) the detection process and the form of threshold probability data; and (b) the relation of threshold ΔI/I to I, and to the spatial and temporal characteristics of the stimulus. These theories are compared with selected related theories. The Swets–Tanner decision theory is contrasted with the present detection threshold theory and various lines of evidence are summarized. It is shown that data previously used to support the Swets–Tanner theory are inconclusive. Chief evidence against the Swets–Tanner theory comes from data obtained in a stimulus-comparison experiment, and from the contradiction implied when the relations assumed to exist between stimulus and sensory magnitudes over the threshold range are extended to a wider range. Evidence is presented which is in favor of the present theories and opposed to the neural theories of Graham and his colleagues which relate threshold ΔI/I to the spatial and temporal characteristics of the stimulus. This evidence comes primarily from detection thresholds for stimuli composed of twin spatial points or double temporal pulses, which the Graham theories cannot explain. In addition to spatial and temporal summation, double spatial and temporal stimuli exhibit probability summation whenever the sensory correlates of the stimuli exhibit twin modes. A 5–6 cps scanning mechanism is shown to exist which breaks up prolonged temporal stimuli and provides probability summation among the separate parts.

[1]  M A BOUMAN,et al.  Variation of integrative actions in the retinal system; an adaptational phenomenon. , 1954, Journal of the Optical Society of America.

[2]  C. H. Graham,et al.  The relation of size of stimulus and intensity in the human eye: II. Intensity thresholds for red and violet light , 1939 .

[3]  L A RIGGS,et al.  Motions of the retinal image during fixation. , 1954, Journal of the Optical Society of America.

[4]  H B BARLOW,et al.  Increment thresholds at low intensities considered as signal/noise discriminations , 1957, The Journal of physiology.

[5]  J. Swets,et al.  A decision-making theory of visual detection. , 1954, Psychological review.

[6]  Edwin G. Boring,et al.  A Chart of the Psychometric Function , 1917 .

[7]  H. Blackwell,et al.  Studies of psychophysical methods for measuring visual thresholds. , 1952, Journal of the Optical Society of America.

[8]  H R Blackwell,et al.  Rod and cone receptor mechanisms in typical and atypical congenital achromatopsia , 1961 .

[9]  E. Wolf,et al.  THEORY AND MEASUREMENT OF VISUAL MECHANISMS , 1944, The Journal of general physiology.

[10]  H R BLACKWELL,et al.  Contrast thresholds of the human eye. , 1946, Journal of the Optical Society of America.

[11]  S. Hecht,et al.  Size, shape, and contrast in detection of targets by daylight vision; frequency of seeing and the quantum theory of cone vision. , 1948, Journal of the Optical Society of America.

[12]  S. Hecht,et al.  ENERGY, QUANTA, AND VISION , 1942, The Journal of general physiology.

[13]  C. H. Graham,et al.  AREA AND THE INTENSITY-TIME RELATION IN THE PERIPHERAL RETINA , 1935 .

[14]  Georg v. Békésy Uber das Fechnersche Gesetz und seine Bedeutung für die Theorie der akustischen Beobachtungsfehler und die Theorie des Hörens , 1930 .

[15]  H. K. Hartline,et al.  Intensity and duration in the excitation of single photoreceptor units , 1934 .

[16]  M A BOUMAN,et al.  The two-quanta explanation of the dependence of the threshold values and visual acuity on the visual angle and the time of observation. , 1947, Journal of the Optical Society of America.

[17]  C. H. Graham,et al.  The relation of size of stimulus and intensity in the human eye: I. Intensity thresholds for white light , 1939 .

[18]  A. Kristofferson,et al.  Neural formulation of the effects of target size and shape upon visual detection. , 1960, Journal of the Optical Society of America.

[19]  H R BLACKWELL,et al.  Studies of the form of visual threshold data. , 1953, Journal of the Optical Society of America.

[20]  J SWETS,et al.  Decision processes in perception. , 1961, Psychological review.

[21]  S S Stevens,et al.  To Honor Fechner and Repeal His Law: A power function, not a log function, describes the operating characteristic of a sensory system. , 1961, Science.

[22]  Alfred H. Holway On the Precision of Photometric Observations , 1937 .

[23]  R H BROWN Complete spatial summation in the peripheral retina of the human eye. , 1947, The American journal of psychology.

[24]  W. Crozier,et al.  ON THE VISIBILITY OF RADIATION AT THE HUMAN FOVEA , 1950, The Journal of general physiology.

[25]  H. Vries The quantum character of light and its bearing upon threshold of vision, the differential sensitivity and visual acuity of the eye , 1943 .

[26]  H R BLACKWELL Evaluation of the neural quantum theory in vision. , 1953, The American journal of psychology.

[27]  S HECHT,et al.  Size, shape, and contrast in the daytime detection of targets. , 1946, Journal of the Optical Society of America.

[28]  H. V. Velden Over het aantal lichtquanta dat nodig is voor een lichtprikkel bij het menselijk oog , 1944 .

[29]  W J Crozier,et al.  On the Sensory Discrimination of Intensities. , 1936, Proceedings of the National Academy of Sciences of the United States of America.

[30]  J. Volkmann,et al.  Theory of the Neural Quantum in the Discrimination of Loudness and Pitch , 1941 .

[31]  C. H. Graham,et al.  BRIGHTNESS DISCRIMINATION AS A FUNCTION OF THE DURATION OF THE INCREMENT IN INTENSITY , 1938, The Journal of general physiology.