RU2357647C1 - Method of measurement of visual resolution by frequency of light flitting - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention pertains to medicine. Light flitting emitted by light emitting diodes at the set initial frequency is shown to the subject. Flitting frequency of the first light emitting diode remains unchanged, flitting frequency of the second diode is continuously increased or decreased, until the subject detects differences of the frequencies of light flitting frequencies emitted by light emitting diodes. At this point final frequency of light flitting of the second diode is registered. Visual resolution value is derived as the absolute difference between the final and the initial frequencies of the second light emitting diode.

EFFECT: method enables detecting visual resolution by the frequency of light flitting.

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Description

The invention relates to medicine and is intended to determine the resolution of vision by the frequency of light flicker.

Known estimated minimum visibility of the change in the frequency of light flicker, which is 0.75 Hz [1].

Closest to the technical nature of the present invention is a method for determining the resolution of vision by the frequency of light flickers by presenting the subject with light flickers with a continuously variable frequency, which consists in the fact that the subject is presented with light flickers with a given initial frequency equal to, for example, 15 Hz, then the frequency of light flickers is continuously changed at a speed of the order of 0.5 Hz / s, increasing or decreasing it, until the subject determines the subjective change in frequency with etovyh flicker and fix them at this moment the stop frequency, the value of resolving power of the frequency of light flashes taking the absolute difference between the final and initial frequencies [2].

The disadvantage of this method is the low accuracy of determining the resolution of vision by the frequency of light flicker, due to the need to use memory functions, in particular, access to long-term logical-semantic memory.

The technical result of the proposed method for determining the resolution of vision by the frequency of light flicker is to increase the accuracy of the assessment.

The technical result is achieved by the fact that the subject is presented with light flickers with a given initial frequency, and it is new that the initial frequency is presented simultaneously using two LEDs, the frequency of light flickers of the first LED is not changed, the frequency of light flickers of the second LED is continuously changed, increasing or decreasing it until the subject determines the difference between the frequencies of light flicker emitted by the LEDs and fixes at that moment the final frequency of light flicker torogo LED, for the value of the resolving power of the frequency of light flashes taking the absolute difference between the final and initial frequencies of the second LED.

The proposed method for determining the resolution of vision by the frequency of light flicker is as follows.

Determining the resolution can be made in the mode of increasing the frequency, as shown in figure 1, or in the mode of decreasing the frequency, as shown in figure 2.

The subject is presented with light flickers with a given initial frequency F _n equal to, for example, 15 Hz, simultaneously using two LEDs. The frequency of light flicker of the first LED is not changed, the frequency of light flicker of the second LED is continuously changed at a speed of the order of 0.5 Hz / s, increasing or decreasing it until the subject determines the difference between the frequencies of light flicker emitted by the LEDs. At this moment, the subject fixes the final frequency of light flicker F _{to the} second LED. The value of the resolution of vision by the frequency of light flickering is determined as the absolute difference between the final and initial frequencies of the second LED according to the formula:

ΔF = | F _to -F _n |.

Thus, the inventive method for determining the resolution of vision by the frequency of light flicker has the properties that determine a positive effect.

Example 1. Subject K., 19 years old, using two generators that emit light flicker on two LEDs, showed flicker with an initial frequency of F _n = 15 Hz. The frequency of the first generator did not change, the frequency of the second - continuously changed. The direction of the change in the frequency of light flicker of the second generator (increase or decrease) was set by the toggle switch with the positions “Increase frequency” and “Decrease frequency”. The frequency control of the light flicker of the second generator was carried out by the test buttons “Change frequency” and “Fix frequency”. According to the signal from the Change Frequency button, the second generator, depending on the position of the toggle switch, increased or decreased the initial frequency F _{n of} light flickers at a speed of the order of 0.5 Hz / s, and stopped the frequency change at the signal from the Fixation Frequency button and saved it at the output the value of the final frequency F _to light flicker. The signal with the frequency of the presented light flicker from the second generator was fed through the LPT port to a personal computer, in which the period of the initial F _n and final F _{to the} light flicker frequencies, their frequencies and the absolute difference of the final F _k and initial F _n frequencies were calculated.

Using the toggle switch, the second generator was set to increase frequency. Then, the test subject with a short press of the button “Change frequency” (Fig. 1, time moment T ₁ ) set the second generator to a continuously increasing frequency of light flicker. The subject determined the difference in the frequencies of light flicker emitted by the LEDs, and pressed the button "Fixing the frequency" (figure 1, time point T ₂ ). In this case, the computer calculated and displayed on the monitor screen the final frequency of light flicker of the second generator F _k = 17.9 Hz and the frequency change ΔF = | F _k -F _n | = 2.9 Hz, taken as the value of the resolution of vision in terms of the frequency of light flicker .

In accordance with the recommendations of physiologists, the subject performed a series of 10 measurements, as a result of which the following values were obtained for the resolution of vision by the frequency of light flicker in Hz: 2.9; 2.5; 2.0; 1.8; 1,2; 2.6; 2.9; 3.2; 3.7; 2.5. The arithmetic average of the measured values of the resolution of vision by the frequency of light flicker was 2.5 Hz, the standard deviation was 0.228 Hz, the confidence limits of the random component of the error of the measurement results with a confidence probability of 0.95, taking into account the student coefficient - 0.516 Hz.

As a result of measurements made by test subject K. according to the known method [2], the following values of the resolution of vision were obtained according to the frequency of light flicker in Hz: 3.3; 1.6; 3.2; 3.8; 2.8; 1.7; 2.9; 1.1; 1.0; 2.8. The arithmetic average of the measured values of the resolution of vision by the frequency of light flicker was 2.4 Hz, the standard deviation was 0.312 Hz, the confidence limits of the random component of the error of the measurement results with a confidence probability of 0.95 taking into account the student coefficient is 0.706 Hz.

The decrease in the random component of the measurement error (standard deviation) when performing measurements according to the proposed method compared with measurements performed by the known method [2], was 26.9%.

Example 2. Subject B., 20 years old, performed measurements to determine the resolution of vision by the frequency of light flickers in a mode of decreasing frequency.

Using two generators, issuing light flickering on two LEDs, flickering was presented with an initial frequency of F _n = 15 Hz. The frequency of the first generator did not change, the frequency of the second - continuously changed.

The toggle switch of the second generator was set to the “Decrease frequency” position. Then the test subject with a short press of the button “Change frequency” (figure 2, time T ₁ ) set the second generator in a continuously decreasing frequency of light flicker. The subject determined the difference in the frequencies of light flicker emitted by the LEDs, and pressed the button "Fixing the frequency" (figure 2, time point T ₂ ). In this case, the computer calculated and displayed on the monitor screen the final frequency of light flicker of the second generator F _k = 11.3 Hz and the frequency change ΔF = | F _to -F _n | = 3.7 Hz, taken as the value of the resolution of vision in terms of the frequency of light flicker .

Similarly to test K., test B. performed a series of 10 measurements, as a result of which the following values were obtained for the resolution of vision by the frequency of light flicker in Hz: 3.7; 2.9; 2.1; 3.0; 1.8; 3.6; 1.4; 3.4; 1.6; 2.1. The arithmetic average of the measured values of the resolution of vision by the frequency of light flicker was 2.6 Hz, the standard deviation was 0.272 Hz, the confidence limits of the random component of the error of the measurement results with a confidence probability of 0.95, taking into account the student coefficient, 0.616 Hz.

As a result of measurements made by test B. by a known method [2], the following values were obtained for the resolution of vision by the frequency of light flicker in Hz: 3.9; 2.2; 4,5; 1,2; 3.7; 1.7; 3.9; 1.0; 1,2; 3.2. The arithmetic average of the measured values of the resolution of vision by the frequency of light flicker was 2.7 Hz, the standard deviation was 0.421 Hz, the confidence limits of the random component of the error of the measurement results with a confidence probability of 0.95, taking into account the student coefficient - 0.953 Hz.

The decrease in the random component of the measurement error (standard deviation) when performing measurements according to the proposed method compared with measurements performed by the known method [2], amounted to 35.4%.

To assess the reliability of reducing the random component of the measurement error, we measured the resolution of vision by the frequency of light flickering according to the proposed and known methods in a group of 10 subjects, each of which performed a series of 10 measurements in each method, while 5 subjects measured the resolution of vision in frequency light flickering in the mode of increasing the frequency of the second generator, 5 subjects - in the mode of decreasing the frequency of the second generator. The decrease in the random component of the measurement error when performing measurements according to the proposed method compared with measurements performed by the known method, ranged from 21 to 48%.

Thus, the proposed method allows to increase the accuracy of determining the resolution of vision by the frequency of light flicker.

Information sources

1. A.S. 665895 USSR, MKI A61V 5/16. A method for measuring the critical frequency of flicker fusion / G.N. Yagovkin, A.P. Ovchinnikov (USSR). - 2 p.

2. Patent 2195153 of the Russian Federation, А61В 3/00, 5/16. A method for determining the resolution of vision by the frequency of light flickers / V.V. Rozhentsov, T. A. Lezhnina. - Publ. 12/27/2002, Bull. Number 36.

Claims (1)

A method for determining the resolution of vision by the frequency of light flickers by presenting the subject with light flickers with a given initial frequency, then the frequency of light flickers continuously, increasing or decreasing it until the subject determines the difference in the frequencies of light flickers and fixes at this moment the final frequency of light flickers of the second LED , the absolute difference between the final and initial frequencies is taken as the value of the resolution of vision by the frequency of light flickers schiysya in that the initial frequency placing simultaneously using two LEDs, the frequency of flashing the first light of the LED do not change, and an increased or decreased frequency of light flashes impose on the second LED.

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