RU2195174C1 - Method for detecting time for human visual persistence - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method detects human visual persistence due to applying the sequence of two light impulses of preset duration, for example, 50 msec, divided with a pause of 150 msec duration, repeating in a constant time interval of about 1.5 sec, then pause duration between light impulses should be decreased for the patient to determine the moment of subjective fusion of two light impulses into one. The time for human visual persistence is considered to be equal to pause duration at the moment of subjective fusion of two light impulses into one. EFFECT: higher accuracy of detection. 5 dwg, 2 ex

Description

 The invention relates to medicine and is intended to determine the time of inertia of the human visual system.

A known method of determining the time of inertia of vision using a pendulum and contrast filters [1]. Using this method, the threshold contrast ε is measured for a given object during stationary observation, then, at different contrasts K _p created by a given set of filters, the effective contrast K _{e is} brought to the visibility threshold by selecting the exposure time τ, given by the swing amplitude of the pendulum. For the time of inertia, the effective time of preservation of the visual impression is taken, which at the exposure time τ <0.01 s is determined by the formula
θ = K _p τ / ε.
The disadvantage of this method is the use of the mechanical principle of setting the exposure time, which reduces the accuracy of determining the time of inertia.

 A known method of neurophysiological studies of the temporal processing of signals in the striatal cortex of animals. The experiments carried out by this method established the appearance of a registered receptive field in different neurons 20-80 ms after the light stimulus was turned on, the maximum reaction of the receptive field in 60-100 ms, and its disappearance in 100-200 ms [2]. According to this method, animals were anesthetized, immobilized, artificially ventilated and thermally stabilized. Registration of the receptive field was performed using an electroencephalogram.

 The disadvantage of this method is the long preparatory period before conducting studies.

 Known studies of the inertia of the human visual system using electroretinography and visual evoked cortical potentials [3, 4, 5, 6].

 A common disadvantage of the known methods is the difficulty of research, the need to use special equipment, a long preparatory period before research.

 None of the known methods can be adopted as a prototype for the proposed method for determining the time of inertia of the human visual system.

The inertia of the visual system upon presentation of light pulses is usually characterized by the following parameters presented in FIG. 1, where FIG. 1a is a timing diagram of a light pulse, FIG. 1b is a timing diagram of visual sensation per light pulse:
- the time of visual sensation τ ₁ - the time between the moment of exposure of light to the retina and the moment of occurrence of the corresponding visual sensation [7, 8] (fig.1b);
- recovery time τ ₂ - the time between the moment of termination of the effect of light on the retina and the moment of disappearance of the corresponding visual sensation [7, 8] (fig.1b);
- the critical duration of vision T _with - the minimum time of presentation of the light pulse at which light perception is achieved [3].

Figure 2 presents time charts explaining the relationship of the time of visual sensation τ ₁ and the critical duration of vision T _with , where:
- figa - time diagram of a light pulse of duration τ _{and 1} > τ ₁ ;
- fig.2b is a timing diagram of visual sensation per light pulse shown in figa;
- figv - time diagram of a light pulse of duration τ _{and 2} <τ ₁ , in which visual sensation does not occur.

In the case when a light pulse of duration τ _{and 2} <τ ₁ acts on the retina; (figv), photochemical reactions do not cause visual sensation on the light pulse, since the exposure time of the light pulse to the retina is less than the accumulation time in the visual system, necessary for the appearance of visual sensation.

At the same time, according to the definition of the critical duration of vision T _c when a light pulse of duration τ _and <T _{c is} exposed to the retina, visual sensation does not occur. This indicates the equivalence of the concepts of the critical duration of vision T _with and the time of visual sensation τ ₁ .
Figure 3 presents the time diagrams of two light pulses of duration τ _and > τ ₁ , separated by a pause, and the visual sensations caused by them, indicating the time of visual sensation τ ₁ and recovery time τ ₂ , where:
- figa - time diagram of two light pulses separated by a pause t _p causing a visual sensation of separation of pulses;
- figb - time diagram of visual sensation for two light pulses shown in figa;
- figv is a timing diagram of two light pulses separated by a pause t _cr , causing a visual sensation of one light pulse. With a pause duration t _cr between two light pulses, a subjective sensation of merging two light pulses into one is achieved;
- Fig. 3d is a time diagram of visual sensation for two light pulses shown in Fig. 3c.

Upon presentation to the subject of two light pulses separated by a pause t _p > t _cr (figa), he has a feeling of two light pulses (fig.3b). When reducing the duration of the pause t _p between two light pulses to a value of t _p = t _cr , (Fig.3c) there is a subjective sensation of merging two light pulses into one (Fig.3d). The maximum duration of a pause t _p = t _cr between two light pulses, at which a subjective sensation of fusion of two light pulses into one is achieved, is determined by the inertia parameters of the human visual system (figv, d)
t _cr = τ ₂ -τ ₁ .
The following values of the inertia parameters of the human visual system are known:
- recovery time τ ₂ [8] or time to maintain visual impression - about 50 ms [9];
- visual sensation time τ ₁ [8] or critical duration of vision T _s - about 1.5 ms [3].

Since τ ₂ ≫ τ ₁ , then the recovery time τ ₂ can be taken as the inertia of the human visual system
t _cr ≅ τ ₂ .
The proposed method for determining the time of inertia of the human visual system allows:
- simplify the measurement procedure;
- reduce the time of the preparatory period;
- reduce the time to determine the inertia of the visual system;
- conduct research without the use of expensive special medical equipment.

 The proposed method for determining the time of inertia of the human visual system by presenting light pulses to the subject is that the subject is presented with a sequence of two light impulses of a given duration equal to, for example, 50 ms, separated by a pause of, for example, 150 ms, repeated over a constant time interval of the order 1.5 s, the duration of the pause between light pulses is reduced until the subject determines the moment of subjective fusion of two light pulses into one, and on th measurement stage, the duration of the pause between two light pulses with a given constant speed of about 20 ms / s is reduced, until the subject determines the subjectively merging of two light pulses into one, at the second measurement stage, the pause duration between two light pulses with a given constant speed of about 5 ms / s, until the subject determines the moment of subjective sensation of the separation of two light pulses, at the third stage of measurement, the duration of the pause between two light impulses is reduced with ice at a given constant speed of about 2 ms / s, until the subject determines the moment of subjective fusion of two light pulses into one, the inertia time of the human visual system is taken equal to the value of the duration of the pause at the time of subjective fusion of two light pulses into one.

 The proposed method for determining the time of inertia of the human visual system is as follows.

In FIG. 4 is a time chart of the presented light pulses, and FIG. 5 is a time chart of the change in the duration of the pause t _p between two light pulses when determining the time of inertia of the human visual system.

The test subject is presented with a sequence of two light pulses of a given duration, equal, for example, τ _and = 50 ms, separated by a pause t _p , repeated through a constant time interval of the order of T = 1.5 s (Fig. 4). The initial duration of the pause between two light pulses is set equal to t _p1 = 150 ms (figure 5, the time interval T ₀ -T ₁ ). The duration of the pause t _p between the light pulses is reduced to a value of t _cr - the maximum duration of a pause between two light pulses, at which the subjective sensation of merging two light pulses into one is achieved (Fig. 3d). The time of inertia of the human visual system is taken equal to the duration of the pause t _cr at the moment of subjective merging of two light pulses into one:
τ ₂ ≅ t _cr
At the first measurement stage, the pause duration t _p between two light pulses with a given constant speed v _{1 of the} order of 20 ms / s is reduced (Fig. 5, the time interval T ₁ -T ₂ ) until the subject determines the subjectively merging of two light pulses into one (FIG. 5, point in time T ₂ ).

At the second measurement stage, the pause duration t _p between two light pulses with a given constant speed v _{2 of the} order of 5 ms / s is increased (Fig. 5, the time interval T ₃ -T ₄ ) until the subject determines the moment of subjective sensation of the separation of two light pulses ( 5, a point in time T ₄ ).

At the third stage of measurements, the pause duration t _p between two light pulses with a given constant speed v _{3 of the} order of 2 ms / s is reduced (Fig. 5, the time interval T ₅ -T ₆ ), until the subject determines the moment of subjective merging of two light pulses into one (Fig. 5, point in time T ₆ ).

Then determine the duration of the pause t _cr at the moment of subjective fusion of two light pulses into one (figure 5, time point T ₇ ), the value of which is taken as the time of inertia of the human visual system.

 Thus, the claimed method for determining the time of inertia of the human visual system has new properties that determine the receipt of a positive effect.

Example 1. Subject P., 25 years old, using a personal computer compatible with IBM PC that issues light flickers through the LPT port to the indicator of the subject's remote control, showed a sequence of two light pulses of duration τ _and = 50 ms, separated by a pause t _p , repeating through a constant time interval equal to T = 1.5 s (figure 4). The initial duration of the pause between two light pulses was set equal to t _p1 = 150 ms (figure 5, the time interval T ₁ -T ₂ ). In the process of measurement through the LPT port, the signals from the "Decrease fast", "Slow increase", "Slow decrease" and "Measurement" buttons were sent to the personal computer from the subject’s remote control.

If there is a signal from the “Decrease fast” button, the computer reduced the pause duration between two light pulses at a speed of v ₁ ≅20 ms / s, and if there is a signal from the “Increase slow” and “Decrease slow” buttons, it increases accordingly with a speed of v ₂ ≅5 ms / s and decreased with a speed of v ₃ ≅ 2 ms / s the pause duration between two light pulses, by a signal from the Measurement button - fixed the pause duration t _cr between the presented single light pulses at the moment of subjective merging of two light pulses into one and presented the initial sequence of two light pulses.

At the first stage, the test subject, giving a signal from the button "Decrease fast" (Fig. 5, the time interval T ₁ -T ₂ ), determined the estimated subjective fusion of two light pulses into one (Fig. 5, point in time T ₂ ).

At the second stage, the test subject, giving a signal from the "Slow Increase" button (Fig. 5, time interval T ₃ -T ₄ ), determined the moment of subjective sensation of the separation of two light pulses (Fig. 5, time moment T ₄ ).

At the third stage, the subject, giving a signal from the Slow Decrease button (Fig. 5, time interval T ₅ -T ₆ ), determined the moment of subjective merging of two light pulses into one (Fig. 5, time moment T ₆ ), then gave a signal from the button "Measurement" (figure 5, time point T ₇ ). The computer determined the pause duration t _cr = 46 ms and presented the initial sequence of two light pulses.

 In accordance with the recommendations of physiologists, the subject performed a series of 10 measurements. As a result of the measurements, the following values of the time of inertia of the subject's visual system in ms were obtained: 46; 49; 46; fifty; 48; fifty; 49; 49; fifty; 48. The arithmetic average of the measured values of the time of inertia of the visual system is 48.50 ms, the standard deviation is 1.50 ms, the confidence limits of the random component of the error of the measurement result with a confidence probability of 0.95, taking into account the student coefficient, are 3.39 ms.

 Example 2. Subject K., 35 years old, similarly to subject P., performed a series of 10 measurements. As a result of measurements, the following values of the time of inertia of the visual system in ms were obtained: 55; 57; 53; 59; 58; 57; 58; 59; 58; 58. The arithmetic average of the measured values of the inertia time of the visual system is 57.20 ms, the standard deviation is 1.90 ms, the confidence limits of the random component of the error of the measurement result with a confidence probability of 0.95, taking into account the student coefficient, 4.30 ms.

 Thus, the proposed method allows to determine the time of inertia of the human visual system.

Sources of information
1. Luizov A.V. Eye and light. - L .: Energy, 1983. - 140 p.

 2. Shevelev I.A. Temporary signal processing in the visual cortex // Human Physiology. - 1997. - T. 23. - 2. - S. 68-79.

 3. Shamshinova A.M., Volkov V.V. Functional research methods in ophthalmology: - M .: Medicine, 1999. - 416 p.

 4. Tatko V.L. Chronometry of human information processing processes // Itogi Nauki i Tekhniki / Ser. Human and animal physiology. Problems of modern psychophysiology. - M.: VINITI. - 1989.- T. 35.- S. 3-144.

 5. Beteleva T.G. Functional specialization of the hemispheres in the preparation of cash and previous incentives // Human Physiology. - 2000. - T. 26. - 3.- S. 21-30.

 6. Nechaev VB, Klyucharyov VA, Kropotov Yu.D., Ponomarev VA Evoked potentials of the cerebral cortex when comparing visual stimuli // Human Physiology. - 2000. - T. 26. - 2. - S. 17-23.

 7. Kravkov S.V. Eye and his work. Psychophysiology of vision, lighting hygiene. - 4th ed., Revised. and add. - M.-L .: Publishing House of the Academy of Sciences of the USSR, 1950 .-- 531 p.

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Claims (1)

 A method for determining the time of inertia of a person’s visual system by presenting light pulses to a test subject, namely, that the test subject is presented with a sequence of two light pulses of a given duration equal to, for example, 50 ms, separated by a pause of, for example, 150 ms, repeated over a constant time interval of the order 1.5 s, the duration of the pause between light pulses is reduced until the subject determines the moment of subjective merging of two light pulses into one, and in the first stage and of measurements reduces the pause duration between two light pulses with a given constant speed of about 20 ms / s, until the subject determines an estimated subjectively merging of two light pulses into one, at the second measurement stage, increase the pause duration between two light pulses with a given constant speed of about 5 ms / s, until the subject determines the moment of subjective sensation of the separation of the two light pulses, at the third stage of measurement, the pause duration between two light pulses is reduced at a constant speed of the order of 2 ms / s, until the subject determines the moment of subjective fusion of two light pulses at one time, the inertia time of the human visual system is taken to be the value of the duration of the pause between two light pulses at the moment of subjective fusion of two light pulses into one determined at the third stage measurements.

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