RU2262293C1 - Method for determining human visual system response time - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method involves showing paired light pulses. The reference one of 80 ms duration and duration-controlled one repeat in time interval equal to 1 s. The duration-controlled pulse is delayed or interrupted earlier relative to reference pulse showing time. Delay time or early interruption time of duration-controlled pulse relative to the reference one is discretely incremented with 5 ms long step until the testee determines subjective sensation time represented by the event that the light pulses start or finish at the same time, at the first stage. Duration-controlled pulse delay time or early interruption time is reduced in discrete way with steps of 1 ms until the testee determines subjective sensation time represented by the event that the light pulses start or finish at the same time, at the second stage. Duration-controlled pulse delay time or early interruption time is increased in discrete way with steps of 0.1 ms until the testee determines subjective sensation time represented by the event that the light pulses do not start or finish at the same time, at the third stage. Visual system response time is taken to be equal to duration-controlled pulse delay time or early interruption time relative to the reference one determined at the third measurement stage.

EFFECT: simplified test process.

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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 threshold of visibility by selecting the exposure time τ specified 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 detected receptive field in different neurons 20-80 ms after the light stimulus was turned on, the maximum reaction of the receptive field was found 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.

A known method for determining the time of inertia of the visual system by presenting light pulses to the subject is 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 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 at the first stage and of measurements reduces the duration of the pause between two light pulses with a given constant speed of about 20 ms / s, until the subject determines the subjectively merging of two light pulses into one, at the second stage of measurements, increase the duration of the pause 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 the measurements, the duration of the pause between two light pulses is reduced by given constant speed of the order of 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 pause duration at the time of subjective fusion of two light pulses into one [7].

The disadvantage of this method is the inability to determine the inertia of the visual system while simultaneously presenting two light pulses.

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.

It has been experimentally established that when two light pulses are presented, the reference and adjustable in duration, which is delayed or ends earlier than the presentation of the reference, the human visual system perceives both pulses starting at the same time as the inertia is short, and ending at the same time for a short early termination .

The proposed method allows to determine the time of inertia of the human visual system while simultaneously presenting two light pulses.

The proposed method for determining the time of inertia of the human visual system is that the test subject is presented with a pair of light pulses of a standard duration of 80 ms and adjustable in duration, repeated after a time interval of 1 s, the pulse adjustable in duration is delayed or terminated earlier relative to the time of presentation of the reference, moreover, at the first stage of the measurements, the delay time or early termination of a pulse, adjustable in duration, relative to the reference one, increases the dis at a step of 5 ms, until the subject determines the moment of subjective sensation that the light pulses do not start or end at the same time, at the second measurement stage, the delay time or early termination of the pulse, adjustable in duration, is reduced discretely with a step of 1 ms, until the subject determines the moment of subjective sensation that light pulses start or end at the same time, at the third stage of measurements, the delay time or early end of the pulse, which is adjustable in duration, is increased discretely with a step m 0.1 ms until the subject does not determine the time of subjective sensations, light pulses that originate or terminate at different times. The time of inertia of the visual system is taken equal to the value of the delay time or the time of the early end of the light pulse, regulated by the duration, relative to the reference one, determined at the third measurement stage.

Figure 1 shows the timing diagrams of a sequence of pairs of presented light pulses repeated over a time interval T of 1 s, where Fig. 1a is a timing diagram of a reference light pulse with a duration of τ _imp = 80 ms; figb is a timing diagram of a light pulse adjustable in duration with an initial duration of τ _imp = 80 ms.

Figure 2 presents the timing diagram of the change in the delay time or the early termination time of the time-controlled light pulse relative to the time of presentation of the reference.

Figure 3 presents time diagrams of a sequence of pairs of presented light pulses repeated over a time interval T of 1 s and the visual sensations caused by them, where figa, c are a time diagram of a reference light pulse with a duration of τ _imp = 80 ms; figb is a timing diagram of the adjustable duration of the light pulse, delayed relative to the time of presentation of the reference for a threshold time t _back.pores , causing a feeling that the presented light pulses do not start simultaneously; FIG. 3g is a timing chart of a light pulse that is adjustable in duration and ends with respect to the time of presentation of the reference earlier by the threshold time t _{approx. pores} , causing a feeling that the presented light pulses do not end simultaneously.

The proposed method for determining the time of inertia of the human visual system is as follows. The test subject is presented with a sequence of pairs of light pulses repeating through a time interval T equal to 1 s, a reference duration of τ _imp = 80 ms (Fig. 1a) and adjustable in duration with an initial duration of τ _imp = 80 ms (Fig. 1b).

At the first stage of measurements, the delay time of presentation or the time of early termination of a pulse of duration adjustable with respect to the time of presentation of the reference pulse is increased discretely in 5 ms increments until the subject determines the moment of subjective sensation that the light pulses do not start or end at the same time (Fig. 2, time interval T0-T1).

At the second stage of the measurements, the delay time of presentation or the early end time of a pulse that is adjustable in duration relative to the time of presentation of the reference pulse is reduced discretely in 1 ms steps until the subject determines the moment of subjective sensation that the light pulses begin or end simultaneously (Fig. 2, time interval T1 -T2).

At the third stage of measurements, the delay time of presentation or the time of the early end of a pulse that is adjustable in duration relative to the time of presentation of the reference pulse is increased discretely in 0.1 ms increments until the subject determines the moment of subjective sensation that the light pulses do not start or end at the same time (Fig. 2, time interval T2-T3).

The delay time of presentation or the time of early termination of a pulse that is adjustable in duration relative to the time of presentation of the reference pulse t _then determined at the last stage is fixed (Fig. 2, time point T4) and taken equal to the inertia time of the visual system.

Inertia of vision means the extension of visual sensation after turning off the stimulus [8]. During responses to light stimuli, the receptive field of a small neuron appears first. Then the receptive field expands, after which it weakens, fragmentes and disappears. After the disappearance of the receptive field, the neural structures return to their original state and become ready for the perception of a new stimulus. Since the appearance of the receptive field occurs 20–80 ms after the inclusion of the light stimulus [2], the duration of the reference pulse is taken to be 80 ms.

It is known that the visual perception of a light pulse is hampered under the conditions of reverse masking, which consists in the deterioration of the perception of the first time light pulse due to the presentation of the second pulse in the immediate spatio-temporal proximity to the first. It was shown that there is not only a reverse effect, but also direct masking, in which the first light pulse affects the quality of perception of the second [10]. At an interpulse interval of 500 ms, masking effects are absent or weakly expressed [11]. To eliminate the masking effect, the sequence of pairs of light pulses is repeated at a constant time interval of 1 s.

When the delay in the presentation of a pulse of duration controlled by the duration relative to the time of presentation of the reference pulse for a time t <t _then the subjective subjectively senses that the light pulses start simultaneously, when the delay for a time t≥t _then not simultaneously (figa, b).

At the early end of a pulse that is adjustable in duration relative to the time of presentation of the reference pulse for a time t <t _then the subjective subjectively senses that the light pulses end simultaneously, with a delay of a time t≥t _then not simultaneously (Figs. 3c, d).

Thus, the inventive 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 X., XX years old, using a personal computer compatible with IBM PC, issuing pulses through the LPT port to the indicators on the remote control of the test person, presented a sequence of pairs of light pulses repeating after a time interval of 1 s, a reference duration of Timp = 80 ms (figa) and adjustable in duration with an initial duration of τ _imp = 80 ms (fig.1b). In the process of measurement through the LPT port, the signals from the buttons “Increase delay time by 5 ms”, “Decrease delay time by 1 ms”, “Increase delay time by 0.1 ms” and “Measurement” were sent to the personal computer from the subject’s remote control.

When a signal from the “Increase the delay time by 5 ms” button was received, the computer increased the delay time of the presentation of a pulse that was adjustable in duration relative to the time of presentation of the reference pulse discretely in 5 ms increments; when a signal was received from the “Decrease the delay time by 1 ms” button, it reduced the delay time discretely in increments of 1 ms, upon receipt of a signal from the button “Increase the delay time by 0.1 ms” - increased the delay time discretely in increments of 0.1 ms, by the signal from the button “Measurement” - fixed the delay time Lenia controlled by pulse width relative presentation time reference pulse, the time delay value deduced t _{ass. then} on the monitor screen, recorded the measurement results in the archive and presented the initial sequence of two light pulses.

At the first stage, the subject, giving a signal from the button “Increase the delay time by 5 ms”, determined the moment of subjective sensation that the light pulses do not start simultaneously (Fig. 2, time interval T0-T1).

At the second stage, the subject, giving a signal from the button “Decrease the delay time by 1 ms”, determined the moment of subjective sensation that the light pulses begin simultaneously (figure 2, the time interval T1-T2).

At the third stage, the subject, giving a signal from the button “Increase the delay time by 0.1 ms”, determined the moment of subjective sensation that the light pulses do not start simultaneously (figure 2, the time interval T2-T3), then gave a signal from the button “Measurement "(Fig. 2, time point T4). The computer determined the delay time for the presentation of the adjustable pulse duration relative to the time for the presentation of the reference pulse, the value of the delay time t _{set p} . on the monitor screen, recorded the measurement result in the archive 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 inertia time of the subject’s visual system in ms were obtained: 22, 21, 21, 22, 20, 19, 22, 19, 21, 22. The arithmetic mean of the measured values of the inertia time was 20.9 ms, the standard deviation was 1.2 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 - 2.67 ms.

Example 2. Subject X., XX years old, using a personal computer compatible with IBM PC that outputs pulses through the LPT port to the indicators on the remote control of the test person, showed a sequence of pairs of light pulses repeating after a time interval of 1 s, a reference duration of τ _imp = 80 ms (figa) and adjustable in duration with an initial duration of τ _imp = 80 ms (fig.1b). In the process of measuring through the LPT port, the signals from the buttons “Increase early end time by 5 ms”, “Decrease early end time by 1 ms”, “Increase early end time by 0.1 ms” and “Measure "

When a signal from the button "Increase the early end time by 5 ms" was received, the computer increased the time of the early end of the pulse that was adjustable in duration relative to the time the standard pulse was presented, in increments of 5 ms, when the signal from the button "Reduced early end time by 1 ms" was decreased the early end time is discrete in increments of 1 ms, when the signal from the button “Increase the early end time by 0.1 ms” is received, it increases the early end time discretely in 0.1 ms increments, according to the signal from the “ISM” button renie "- a fixed time of early closure of the controlled pulse duration relative to the time of presentation of the reference pulse, it outputs the value of time t _ok.por early closure at the monitor, recorded the results of measurements in the file and imposes an initial sequence of two pulses of light.

At the first stage, the test subject, giving a signal from the button “Increase the time of early termination by 5 ms”, determined the moment of subjective sensation that the light pulses did not end simultaneously (figure 2, the time interval T0-T1).

At the second stage, the test subject, giving a signal from the button "Decrease the time of early termination by 1 ms", determined the moment of subjective sensation that the light pulses end simultaneously (figure 2, the time interval T1-T2).

At the third stage, the subject, giving a signal from the button “Increase the early end time by 0.1 ms”, determined the moment of subjective sensation that the light pulses did not end simultaneously (figure 2, the time interval T2-T3), then gave the signal from the button " Measurement "(figure 2, time point T4). The computer determined the time of the early end of the pulse, regulated by the duration of the pulse, relative to the time of presentation of the reference pulse, displayed the value of the end time t _{approx. Pore} on the monitor screen, entered the measurement result in the archive 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 inertia time of the subject’s visual system in ms were obtained: 16, 19, 19, 16, 17, 18, 16, 18, 17, 18. The arithmetic mean of the measured values of the inertia time was 17.4 ms, and the standard deviation was 1.17 ms, 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's coefficient, 2.6 ms.

The positive effect of the proposed method for determining the time of inertia of the visual system is confirmed by the results of an experimental study on a group of 10 subjects. The data obtained showed that the time of inertia of the visual system is in the range of 17.2-26.6 ms.

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

Sources of information

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Claims (1)

The method for determining the time of inertia of the human visual system, which consists in the fact that the test subject is presented with a pair of light pulses of a standard duration of 80 ms and adjustable in duration, repeating through a time interval of 1 s, the pulse adjustable in duration is delayed or terminated earlier relative to the time of presentation of the reference, moreover, at the first stage of measurements, the delay time or early termination of a pulse, adjustable in duration, relative to the reference one, is increased discretely from 5 ms until the subject determines the moment of subjective sensation that the light pulses do not start or end at the same time, at the second measurement stage, the delay time or early termination of the pulse, which is adjustable in duration, is reduced discretely with a step of 1 ms until the subject determines the moment of subjective sensation, which light pulses start or end at the same time; in the third stage of measurements, the delay time or early end of a pulse that is adjustable in duration is increased discretely with a step of 0.1 ms, while while the subject does not determine the moment of subjective sensation that the light pulses do not start or end at the same time, the time of inertia of the visual system is taken to be the value of the delay time or the early end time of the light pulse, regulated by the duration, relative to the reference one, determined at the third measurement stage.

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