RU2343822C1 - Method of vision resolution evaluation based on light blinking frequency - Google Patents

Abstract

FIELD: medical equipment; ophthalmology.

SUBSTANCE: first stage of measurements includes injection of light blinking to the first light-emitting diode of the first pair at frequency increased in comparison with initial frequency by 0.25 Hz. Each first light-emitting diode of following pair submit is supplied with light blinking at frequency increased in comparison with frequency of the first light-emitting diode of previous pair by 0.25 Hz. The second light-emitting diode of the first pair is injected with light blinking at frequency reduced in comparison with initial frequency by 0.25 Hz. Each second light-emitting diode of following pair is injected with light blinking at frequency reduced in comparison with frequency of the second light-emitting diode of previous pair by 0.25 Hz. Patient under test defines pair of light-emitting diodes of the least number, light blinking frequencies of which differ, and presses the button corresponding thereto. At the second stage of measurements, the first light-emitting diode of the first pair receives light blinking at frequency lower by 0.25 Hz than that of the first light-emitting diode of the pair defined at the first stage by patient under test as pair, light blinking frequencies of which differ. Each first light-emitting diode of following pair receives light blinking at frequency increased in comparison with that of the first light-emitting diode of previous pair by 0.05 Hz. The second light-emitting diode of the first pair receives light blinking at frequency lower by 0.25 Hz than that of the second light-emitting diode of the pair defined at the first stage by patient under test, light blinking frequencies of which differ. Each second light-emitting diode of following pair is injected with light blinking at frequency reduced in comparison with that of the second light-emitting diode of previous pair by 0.05 Hz. Patient under test defines pair of light-emitting diodes of the least number, light blinking frequencies of which differ, and presses the button corresponding thereto thus recording value of light blinking frequencies of light-emitting diodes of this pair. Vision resolution by light blinking frequency is calculated as difference between frequency values of the first and second light-emitting diodes recorded at the second stage.

EFFECT: method allows for evaluation of vision resolution by light blinking frequency.

1 dwg, 2 tbl, 1 ex

Description

The invention relates to medicine and medical equipment 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].

There is a method of 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 continuously with a speed of the order of 0 , 5 Hz / s is changed, increasing or decreasing it, until the subject determines the subjective change in the frequency of light flicker and fixes at this moment their final frequency, s value of the 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 closest in technical essence to 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 the initial frequency specified in the visible frequency range, after presenting the light flickers with the initial frequency, the subject is presented alternately with a predetermined frequency in the range 0.5- 1.5 with a constant time of presentation, light flicker with increased compared with the initial - incremental frequency and reduced compared with initial - decrement frequency, and at the first stage of measurements, flash flickers are presented alternately with a continuously increasing increment frequency during presentation at a given constant speed of 0.5 Hz / s and decreasing frequency continuously during presentation with the same speed until the subject does not subjectively determine the difference between the presented frequencies and does not fix the last presented incremental and decrement frequencies, after which the subject is presented with alternately lights flickering with fixed incremental and decrement frequencies before the start of the second measurement stage; at the second stage of measurements, the test subject is presented with alternating light flickers with a decreasing frequency continuously decreasing during presentation at a given constant speed of 0.25 Hz / s and continuously decreasing decreasing frequency during presentation at the same speed until the subject determines subjectively that the flickers presented do not differ and will not record the last shown incremental and decrement frequencies, after which the subject is shown the last recorded increments in turn elementary and decrement frequencies before the beginning of the third stage; at the third stage, the subject is presented with a series of alternating light flickers with a incrementally increasing frequency at the beginning of each series with a given constant step of 0.1 Hz and decrementally decreasingly decreasing at the beginning of each series with the same step until the subject determines the flicker discrimination threshold with incremental and decrement frequencies and will not record the last presented frequencies; the resolution of vision is defined as the difference between the incremental and decrement frequencies recorded in the third stage [3].

The disadvantage of this method is the length of the measurement procedure to determine the resolution of vision by the frequency of light flicker, which limits its use in mass surveys.

The technical result of the proposed method for determining the resolution of vision by the frequency of light flicker is to reduce the measurement time, so it can be used for mass examinations.

The technical result is achieved by the fact that the test subject is presented with light flickers with a predetermined initial frequency in the visible frequency range, and it is new that light flickers are presented simultaneously using 10 pairs of LEDs, each of which corresponds to one of 10 buttons, at the first measurement stage the LED of the first pair serves light flickers with a frequency increased by 0.25 Hz compared to the initial frequency, for each first LED of the next pair serves light flickers with a frequency, personal by comparison with the frequency of the first LED of the previous pair at 0.25 Hz, the second LED of the first pair serves light flickers with a frequency reduced in comparison with the initial frequency by 0.25 Hz, for each second LED of the next pair serves light flickers with a frequency, reduced in comparison with the frequency of the second LED of the previous pair by 0.25 Hz, the subject determines a pair of LEDs with the lowest number, the frequencies of light flickering of which differ, and presses the corresponding button; at the second measurement stage, light flickers are fed to the first LED of the first pair with a frequency lower than 0.25 Hz of the frequency of the first LED of the pair, defined at the first stage as a pair, the frequencies of light flickering of which differ, for each first LED of the next pair light flickers a frequency increased in comparison with the frequency of the first LED of the previous pair by 0.05 Hz, the second LED of the first pair serves light flickers with a frequency lower by 0.25 Hz of the frequency of the second LED of the pair, determined by the first stage, the subjects as a pair, the light flicker frequencies of which differ, for each second LED of the next pair, light flickers are supplied with a frequency reduced by 0.05 Hz compared to the second LED of the previous pair, the test person determines the pair of LEDs with the lowest number, light flicker frequencies which differ, and presses the corresponding button, fixing the value of the frequencies of light flickering of the LEDs of this pair; the bandwidth value of the receptive fields of the neurons of the visual system is calculated as the difference between the frequencies of the first and second LEDs fixed in the second stage.

The drawing shows a diagram containing 10 pairs of LEDs HL1-HL20 and their corresponding 10 buttons SA1-SA10.

The proposed method for determining the bandwidth of receptive fields of neurons of the visual system is as follows.

The test subject is presented with light flickering with a given initial frequency, for example 10 Hz, simultaneously using 10 pairs of HL1-HL20 LEDs, each of which corresponds to one of 10 buttons SA1-SA10.

At the first measurement stage, light flickers are fed to the first LED of the first pair of HL1 with a frequency increased by 0.25 Hz compared to the initial frequency. For each first LED of the next pair, light flickers are supplied with a frequency increased by 0.25 Hz compared to the frequency of the first LED of the previous pair. The second LED of the first pair of HL2 serves light flicker with a frequency reduced by 0.25 Hz compared with the initial frequency. For each second LED of the next pair, light flickers are supplied with a frequency reduced by 0.25 Hz compared to the frequency of the second LED of the previous pair. The test subject determines the pair of LEDs with the lowest number, the frequencies of light flickering of which differ, and presses the corresponding button.

At the second measurement stage, light flickers are fed to the first LED of the first pair of HL1s with a frequency lower than 0.25 Hz of the frequency of the first LED of the pair determined at the first stage to be tested as a pair, the frequencies of light flickering of which are different. Light flickers are fed to each first LED of the next pair with a frequency increased by 0.05 Hz compared to the frequency of the first LED of the previous pair. The second LED of the first pair of HL2 serves light flicker with a frequency lower than 0.25 Hz of the frequency of the second LED of the pair, defined in the first stage by the subject as a pair, the frequency of light flicker which differ. For each second LED of the next pair, light flickers are supplied with a frequency reduced by 0.05 Hz compared to the frequency of the second LED of the previous pair. The subject determines the pair of LEDs with the lowest number, the frequencies of light flickering of which differ, and presses the corresponding button, fixing the value of the frequencies of light flickering of the LEDs of this pair.

The resolution of vision by the frequency of light flickers is calculated as the difference between the frequencies of the first and second LEDs fixed in the second stage.

It has been experimentally established that the resolution of vision by the frequency of light flickers at an initial frequency of 10 Hz for a healthy person is in the range from 1.0 to 2.3 Hz. Based on these values, at the first measurement stage, the step of changing the frequency of the LEDs is taken with a margin of 0.25 Hz. The step of changing the frequency of the LEDs at the second measurement stage is 0.05 Hz, since the accuracy of measuring the resolution of vision is determined by the frequency of light flicker equal to 0.1 Hz.

The inventive method for determining the resolution of vision by the frequency of light flicker allows to reduce the examination time.

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. Subject D., 19 years old, using a personal computer compatible with an IBM PC that outputs pulses through the LPT port simultaneously to the LEDs HL1-HL20 of the remote control unit, showed light flickers with an initial frequency of 10 Hz.

During measurements, the code of the pressed button SA1-SA10 was supplied to the PC at each stage of the measurements via the LPT port from the test subject’s remote control, by which the computer fixed the frequency of light flashing of the LEDs of the pair corresponding to the pressed button and proceeded to the next measurement stage.

At the first stage of measurements, the computer gave pulses to the LEDs of the pairs with the frequencies shown in table 1.

Table 1 Pair number one 2 3 four 5 6 7 8 9 10 Flicker frequency of the first LED, Hz 10.25 10.5 10.75 eleven 11.25 11.5 11.75 12 12.25 12.5 Flicker frequency of the second LED, Hz 9.75 9.5 9.25 8 7.75 7.5 7.25 6 6.75 6.5

The test subject identified pair No. 4, the frequencies of light flickering of which differ, and pressed the corresponding button SA4, which spent 2.5 seconds.

At the second stage of measurements, the computer gave pulses to the LEDs of the pairs with the frequencies shown in table 2.

table 2 Pair number one 2 3 four 5 6 7 8 9 10 Flicker frequency of the first LED, Hz 10.75 10.8 10.85 10.9 10.95 eleven 11.05 11.1 11.15 11,2 Flicker frequency of the second LED, Hz 9.25 9.2 9.15 9.1 9.05 9 8.95 8.9 8.85 8.8

The test subject identified a pair No. 4, the frequencies of light flickering of which differ, and pressed the corresponding button SA4, which spent 3.5 seconds.

As a result, the subject determined the value of the resolution of vision by the frequency of light flickering equal to 1.8 Hz, spending 6 seconds on it.

When determining the resolution of vision by the frequency of light flickering by the known method [3], the subject spent 11 s, that is, 5 s or 83% more time.

To assess the reliability of reducing the measurement time, the resolution of vision was determined by the frequency of light flickers according to the proposed method and the known method [3] in a group of 10 subjects, each of which determined the resolution of vision by the frequency of light flickers in each way. Reducing the measurement time when determining the resolution of vision by the frequency of light flicker according to the proposed method compared with the determination by the known method [3] ranged from 4 to 9 s.

Thus, the proposed method for determining the resolution of vision by the frequency of light flicker allows to reduce the measurement time and can be used in mass surveys.

Information sources

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

2. RF patent 2195153, 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. - 4 p.

3. RF patent 2209029, А61В 5/00. A method for determining the resolution of vision by the frequency of light flickering / V.V. Rozhentsov, T. A. Lezhnina (RF). - Publ. July 27, 2003, Bull. No. 21. - 7 p.

Claims (1)

A method for determining the resolution of vision by the frequency of light flicker by presenting the subject with light flicker with the initial frequency specified in the visible frequency range, characterized in that the light flicker is presented simultaneously using 10 pairs of LEDs, each of which corresponds to one of 10 buttons, in the first measurement stage light flickers are fed to the first LED of the first pair with a frequency increased by 0.25 Hz compared to the initial frequency, for each first LED of the next pair There are light flickers with a frequency increased by 0.25 Hz compared to the frequency of the first LED of the previous pair, light flickers are fed to the second LED of the first pair with a frequency reduced by 0.25 Hz compared to the initial frequency for each second LED of the next pair they give light flickers with a frequency reduced in comparison with the frequency of the second LED of the previous pair by 0.25 Hz, the subject determines a pair of LEDs with the lowest number, the frequencies of light flickering of which differ, and presses the corresponding her button; at the second measurement stage, light flickers are fed to the first LED of the first pair with a frequency lower than 0.25 Hz of the frequency of the first LED of the pair, defined at the first stage as a pair, the frequencies of light flicker of which differ, each flicker of the next pair is light flickered with a frequency increased in comparison with the frequency of the first LED of the previous pair by 0.05 Hz, the second LED of the first pair serves light flickers with a frequency lower by 0.25 Hz of the frequency of the second LED of the pair, determined by the first stage, the test subjects as a pair, the light flicker frequencies of which differ, for each second LED of the next pair, light flickers are supplied with a frequency reduced by 0.05 Hz compared to the frequency of the second LED of the previous pair, the test person determines a pair of LEDs with the lowest number, light flicker frequencies which differ, and presses the corresponding button, fixing the value of the frequencies of light flickering of the LEDs of this pair; the bandwidth value of the receptive fields of the neurons of the visual system is calculated as the difference between the frequencies of the first and second LEDs fixed in the second stage.