RU2209030C1 - Method for determining vision information perception time - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves showing two luminous impulses of given duration equal to 50 ms separated with a pause equal to 150 ms repeating after constant time interval of 1.5 s. Pause duration is reduced at a rate of 20 m/s at the first stage until the testee determines the moment of complete fusion of two luminous impulses into one. Pause duration is increased at a rate of 5 m/s at the second stage until the testee determines the moment of subjective feeling of two separate luminous impulses. Pause duration is reduced at a rate of 2 m/s at the third stage until the testee determines the moment of subjective feeling of two separate luminous impulses fusing into single one. The human vision information perception time is taken to be equal to sum of luminous impulse duration and pause duration between two luminous impulses at the moment of their subjective fusion into a single impulse determined at the third stage. EFFECT: high accuracy of measurements. 4 dwg

Description

 The invention relates to medicine and is intended to determine the time of perception of visual information.

A known method for determining the latent period of visual perception of a person. According to this method, a test object is formed with uniform background illumination and is applied to the pupil of the eye by a flash from a light source during subsequent recording by the subject of changes in the diameter of the pupil of the eye under the influence of a flash of light. The test pupil’s pupil is used as a test object, and the light source is located less than the focal length from the eye, and after a flash of light, an illumination pulse is formed with an amplitude equal to the background given duration T _and , the trailing edge of which coincides with the moment the subject perceives the subject to begin to contract his pupil, and the value T is determined _and latency human visual perception pupillary reaction [1].

 The disadvantage of this method is the need to use special equipment to fix the moment of contraction of the test pupil, the dependence of the diameter of the pupil on the background illumination.

 There are known studies of the temporal parameters of recognition of the stimulus and decision-making on the reactions that make up the "middle term" of the reflex. To measure the time parameters of the sensory phase of the reflex, a reverse masking technique is used to determine the time of perception necessary for transmitting information to the central nervous system and its recognition. The perception time is the period from the start of the exposure of the test short stimulus to the inclusion of a masking stimulus, when the latter can no longer interfere with the recognition of the test stimulus. In the process of research, the subjects are presented with one of 3-4 letters on the electroluminescent screen and after a certain period of time they turn on a masking stimulus - a single flash of 100 μs duration. The masking stimulus is turned on 20 ms after the exposure of the letter. Then the pause between the test and masking stimuli with each break is increased by 10 ms until the subject recognizes the letter. The time of perception of letter stimuli is measured [2].

 The disadvantage of this method is the low accuracy of determining the time of perception of visual stimuli and the dependence of the time of perception of alphabetic information on the parameters of the stimuli, since it is known that when recognizing the signs of stimuli, such as the location of the stimulus contour, its orientation and size, the time characteristics of recognition are different [3]. The low accuracy of determining the time of perception of visual stimuli is due to the discretization of the change in the duration of the pause between the letter stimulus and the masking stimulus, equal to 10 ms.

 Closest to the technical nature of the proposed method is a method for determining the time of inertia of the human visual system by presenting the subject with light pulses, which consists in the fact that the subject is presented with a sequence of two light pulses of a given duration equal to, for example, 50 ms, separated by a pause equal to, for example, 150 ms, repeated after a constant time interval of the order of 1.5 s, the pause duration between light pulses is reduced until the subject determines the moment of sub objective merging of two light pulses into one, and at the first stage of measurement, the pause duration between two light pulses is reduced with a given constant speed of about 20 ms / s, until the subject determines the subjectively merging of two light pulses into one, and at the second measurement stage, the pause duration is increased between two light pulses with a given constant speed of the order of 5 ms / s, until the subject determines the moment of subjective sensation of the separation of two light pulses, in the third stage of of measurements reduces the duration of the pause between two light pulses with a given constant speed of about 2 ms / s, until the subject determines the moment of subjective merging of two light pulses in one, 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 merging of two light pulses in one determined at the third stage of measurement [4].

 The disadvantage of this method is the low functionality, since it is not possible to determine the time of perception of visual information.

 The proposed method allows to expand the functionality of the known method by determining the time of perception of visual information.

 The proposed method for determining the time of perception of visual information by presenting to a test subject 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 through a constant time interval of the order of 1.5 s, the duration of the pause between light pulses they reduce until the subject determines the moment of subjective fusion of two light pulses into one, and at the first stage of measurement, they reduce the length of the pause between two light impulses at a given constant speed of about 20 ms / s, until the subject determines an estimated subjectively fusion 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 is increased until the subject determines the moment subjective sensation of the separation of two light pulses, at the third stage of measurement, reduce the pause duration between two light pulses with a given constant speed of about 2 ms / s, while the subject is not divides the moment of subjective merging of two light pulses into one, characterized in that the time of perception of human visual information is taken equal to the sum of the duration of the light pulse and the duration of the pause between two light pulses at the time of subjective merging of two light pulses into one determined at the third stage of measurement.

Figure 1 presents a timing chart presented for determining the time of visual perception of a sequence of two light pulses of a given duration τ _{imp of the} order of 50 ms, separated by an adjustable pause of the initial duration t _{mon of the} order of 150 ms, repeated over a constant time interval T of about 1.5 s.

In FIG. 2 shows a time chart of the change in the duration of an adjustable pause t _p between two light pulses τ _imp when determining the time of perception of visual information.

 Figure 3 presents the time diagrams of the light pulse and the corresponding reaction of the visual system, characterizing the perception of the visual system of light pulses, where figure 3, a is a temporary diagram of the light pulse; figure 3, b - visual sensation caused by a light pulse.

Figure 4 presents time diagrams of a sequence of two light pulses of a given duration τ _imp , separated by an adjustable pause of duration t _p and the visual sensations caused by them, where figure 4, a is a time diagram of a sequence of two light pulses of a given duration τ _imp , separated by an adjustable pause of duration t _p , in which two light pulses are subjectively perceived by the subjects separately; FIG. 4b - visual sensation on the sequence of two light pulses shown in FIG. 4 a; 4, c is a timing diagram of a sequence of two light pulses of a given duration τ _imp , separated by an adjustable pause of duration t _p = t _cr , where t _cr is the maximum duration of an adjustable pause t _p between two light pulses, at which a subjective sensation of fusion of two light pulses is achieved pulses in one; figure 4, g - visual sensation on a sequence of two light pulses separated by an adjustable pause t _p = t _cr .

The proposed method for determining the time of perception of visual information is as follows. The subject sequence of placing two light pulses of predetermined duration τ _imp order of 50 ms separated by an adjustable initial pause duration t _bp about 150 ms, after repeating a constant time interval T of the order of 1.5 s (1; 2, the time interval T ₀ - T ₁ ).

The duration of the adjustable pause t _p between two light pulses is reduced from the initial duration t _mon to a certain value t _cr until the subject determines the moment of subjective fusion of two light pulses into one (Fig. 4d). The duration of the adjustable pause t _p = t _cr - the maximum duration of the adjustable pause between two light pulses, at which the subjective feeling of merging two light pulses into one is achieved.

At the first measurement stage, the duration of the adjustable pause t _p between two light pulses with a constant speed v _{1 of the} order of 20 ms / s (Fig. 2, the time interval T ₁ -T ₂ ) is reduced from the initial duration t _mon to a certain value t _p1 , while the subject will not determine the estimated subjective fusion of two light pulses into one (figure 2, time T ₂ ).

At the second measurement stage, the duration of the adjustable pause t _p between two light pulses with a constant speed v _{2 of the} order of 5 ms / s (FIG. 2, the time interval T ₃ -T ₄ ) is increased from the value of the pause duration t _p1 to a certain value of t _p2 , while the subject does not determine the moment of distinguishing between two light pulses (figure 2, time point T ₄ ).

At the third measurement stage, the duration of the adjustable pause t _p between two light pulses with a constant speed v _{3 of the} order of 2 ms / s (Fig. 2, the time interval T ₅ -T ₆ ) is reduced from the value of the pause duration t _p2 to a certain value t _cr , until the subject will not determine the actual subjective merger of two light pulses into one (figure 2, time point T ₆ ). The duration of the adjustable pause t _p = t _{cr set} (Fig.2, time T ₇ ).

The time of perception of visual information t _{Vocp is} taken equal to the value of the sum of the duration of the light pulse τ _imp and the duration of the adjustable pause t _p = t _cr between two light pulses at the moment of their subjective merging into one determined at the third measurement stage:
t _voz = τ _imp + t _cr
where τ _imp - the duration of the light pulse;
t _kp - the duration of the adjustable pause at the time of the subjective merger of two light pulses.

 A constant time interval T of repetition of a sequence of two light pulses separated by an adjustable pause of about 1.5 s does not change during the measurement process.

 It is known that the time of perception of visual information — the time necessary for information to be transmitted to the central nervous system and its recognition — is the period from the moment of exposure of the test short stimulus to the inclusion of a masking stimulus, when the latter can no longer interfere with the recognition of the test stimulus [2]. Then, upon presentation of light pulses, the time of perception of visual information is the period from the moment the exposure of the first light pulse begins to the moment the exposure of the second light pulse begins.

It is known that upon presentation of a light pulse, the perception of the human visual system is characterized, in particular, by the following parameters:
- 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 [5, 6] (Fig.3, b);
- recovery time τ ₂ - the time between the moment of termination of the effect of light on the retina and the moment the corresponding visual sensation disappears [5, 6] (Fig. 3, b).

 When a light pulse is presented with a duration shorter than the time of visual sensation, visual sensation does not occur, since the time of exposure of the light pulse to the retina is less than the summation time necessary for the appearance of visual sensation [7].

Upon presentation of a sequence of two light pulses of a given duration τ _imp ≥ τ ₁ , separated by a pause of duration t _p > t _cr (Fig. 4, a), the subject has a subjective feeling of separation of two light pulses (Fig. 4, b). When reducing the duration of the pause t _p between two light pulses to a value of t _p = t _cr (Fig. 4, c), the subject has a feeling of subjective merging of two light pulses into one (Fig. 4, d).

 At the moment of subjective merging of two light pulses into one process of visual perception of the first light pulse in the sequence will not be completed completely and will be interrupted by the process of visual perception of the second light pulse in the sequence.

The sum of the duration of the light pulse τ _imp and the duration of the adjustable pause t _p = t _cr between two light pulses at the moment of subjective merging of two light pulses into one determines the threshold time of visual perception of a light pulse and is taken as the time of perception of visual information
t _voz = τ _imp + t _cr .
Thus, the inventive method for determining the time of perception of visual information 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 _imp = 50 ms, separated by an adjustable pause of initial duration t _mon = 150 ms, repeated over a constant time interval T = 1.5 s (Fig. 1). In the process of measurement through the LPT port, the signals from the buttons “Decrease fast”, “Increase slow”, “Decrease slow” and “Measurement” were sent to the personal computer from the subject’s remote control.

In the presence of a signal from the “Decrease fast” button, the computer reduced the duration of the adjustable pause between two light pulses at a speed of v _{1 of the} order of 20 ms / s; in the presence of a signal from the “Increase slow” and “Decrease slow” buttons, it increased accordingly with a speed of v ₂ ms / s and decreased at a rate of about 2 v ₃ ms / sec adjustable duration pauses between two light pulses, the signal from the button "Measurement" - a fixed duration t _kr adjustable pause between imposes light pulses figured znach of the time of perception of visual information as a sum of the duration of the light pulse τ _imp and duration controlled pause t _n = t _cr between two light pulses when the subjective fusion of two optical pulses in one output the value of time perception of visual information on the screen and recorded the results of measurements in the archive. Then the computer presented the initial sequence of two light pulses separated by an adjustable pause of the initial duration equal to 150 ms, repeated through a constant time interval of 1.5 s.

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

At the second stage, the test subject, giving a signal from the button "Increase slow" (figure 2, the time interval T ₃ -T ₄ ), determined the moment of subjective sensation of the separation of the two light pulses (figure 2, time T ₄ ).

At the third stage, the test subject, giving a signal from the Slow Reduction button (Fig. 2, time interval T ₅ -T ₆ ), determined the moment of subjective merging of two light pulses into one (Fig. 2, time moment T ₆ ), then gave a signal from the button "Measurement" (figure 2, time T ₇ ). The computer determined the duration of the adjustable pause t _cr , calculated the value of the time of perception of visual information as the sum of the duration of the light pulse τ _imp and the duration of the adjustable pause t _p = t _cr between two light pulses at the moment of subjective merging of the two light pulses into one, and deduced the value of the time of perception of visual information t _rep = 80.1 ms on the screen and entered the measurement result in the archive. Next, the computer presented the initial sequence of two light pulses separated by an adjustable pause of initial duration equal to 150 ms, repeated through a constant time interval of 1.5 s.

 In accordance with the recommendations of physiologists, the subject performed a series of 10 measurements. As a result of measurements, the following values of the time of perception of visual information of the test person in ms were obtained: 80.1; 81.2; 82.1; 82.0; 81.1; 80.3; 80.4; 81.6; 81.5; 79.9. The arithmetic average of the measured values of the time of perception of visual information is 81.02 ms, the standard deviation is 0.79 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 1.77 ms.

 The positive effect of the proposed method for determining the time of perception of visual information is confirmed by the results of an experimental study on a group of 10 subjects. The data obtained showed that the time of perception of visual information is in the range of 72.5 ... 86.1 ms.

 Thus, the proposed method allows to determine the time of perception of visual information.

Literature
1. Application of the Russian Federation for the invention 99103477/14, MKI A 61 B 3/06. A method for determining the latent period of human visual perception / Agranovsky A.V., Berg O.Yu., Evreinov G.E. Inventions Utility Models: Official Bulletin of the Russian Agency for Patents and Trademarks. 2001. - 1. - S. 14.

 2. Kostandov E.A., Arzumanov Yu.L., Vazhnova T.N., Reshchikova T.N., Shostakovich G.S. Decision making and the "middle term" of the reflex by IM Sechenov // Human physiology. - 1979. - T. 5. - 3. - S. 415-426.

 3. Kostelyanets N.B., Kamenkovich V.M. Temporal characteristics of the evaluation of simple properties of contour and textured images. // Human physiology. - 1984. - T. 10. - 2. - S. 272-275.

 4. A positive decision on the application 2001-117142 / 14 (017741) A method for determining the time of inertia of the human visual system. Rozhentsov V.V., Petukhov I.V.

 5. 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.

 6. Semenovskaya E.N. Electrophysiological studies in ophthalmology. -M .: Medgiz, 1963 .-- 279 p.

 7. Rozhentsov V.V., Petukhov I.V. Determining the time of sensation of the human visual system. / Computer technology in science, production, social and economic processes: Materials of the II International scientific-practical. conf. , Novocherkassk, November 25, 2001: At 6 p.m. / South.-Ros. state tech. University (NPI). - Novocherkassk: LLC NPO "TEMP", 2001. - Part 4. - P. 12-14.

Claims (1)

 A method for determining the time of perception of visual information by presenting two light pulses of a predetermined duration of 50 ms to a test subject, separated by a pause of 150 ms, repeating through a constant time interval of 1.5 s, in which, at the first measurement stage, the duration of the pause between light pulses is reduced from a given at a constant speed of 20 m / s, until the subject determines the moment of subjective fusion of two light pulses into one, in the second stage, the duration of the pause is increased with a given constant speed 5 m / s, until the subject determines the moment of subjective sensation of the separation of the two light pulses, at the third stage of the measurements, the duration of the pause between two light pulses with a given constant speed of 2 m / s is reduced until the subject determines the moment of subjective fusion of two light pulses into one , while the time of perception of visual information by a person is taken equal to the value of the sum of the duration of the light pulse and the duration of the pause between two light pulses at the moment of subjective merger of the two tovyh pulses in one defined in the third phase measurements.

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