RU156335U1 - DEVICE FOR DETERMINING THE BOUNDARIES OF THE PERIPHERAL VISION FIELD - Google Patents

Abstract

A device for determining the boundaries of the peripheral field of view, including a perimeter in the form of an arc of 180 °, and a test object, characterized in that in the middle of the arc to fix the patient’s open eye, a board is mounted with a matte green LED installed on it and connected by a damping resistor, a micro button and two 1.5 V batteries, and the test object being defined is made in the form of 10 parallel-connected two-color R / G LEDs mounted on the central axis from the inside of the arc from the upper edge at 90 ° with a step of 5 ° to the bottom of the arc about 40 °, controlled by a circuit mounted on the outer side of the upper edge of the perimeter arc and containing a 1 kHz rectangular pulse generator connected through a frequency divider with a division coefficient of 8192 and a decimal counter / decoder with two inverter circuits, and made with the possibility of alternating switching on for 4 s and a pause in 4 s of LEDs, by means of two micro-tumblers and three micro-buttons.

Description

The utility model relates to the field of ophthalmology, in particular the diagnosis of perimetry of the eye. All that a person, in a stationary state, sees in front of him, is called the field of view. The field of view of the eye is the amount of space that the human eye sees with a fixed gaze and a fixed position of the head. The field of view is the field of view of both eyes. The visual field is a function of the peripheral parts of the retina, namely the rod apparatus; his condition is largely determined by the ability of a person to freely navigate in space. The physiological boundaries of the visual field depend on the state of the visual apparatus of the eye and visual centers. Changes in the visual field are caused by organic or functional diseases of the visual analyzer: retina, optic nerve, optic pathway, central nervous system. Violations of the field of view are manifested either by a narrowing of its boundaries (expressed in degrees or linear values), or by the loss of its individual sections (hemianopsia), the appearance of scotoma - the area of loss of part of the field of view. When assessing the field of view (in ophthalmology, this is called perimetry), a predisposition to ocular pathologies and diseases can be detected. Disturbances in the peripheral parts of the retina are an invisible danger. It is at the “periphery” that changes develop more often that lead to rupture or detachment of the retina. Therefore, the study of the patient’s field of view is of such great importance. So, if a person’s field of vision is narrowed or curved, then we can talk about the presence of such serious eye diseases as glaucoma or cataracts. By the perimeter of your eye, you can judge the state of your entire visual system. For practical purposes, the most important are: 1. Determination of the external boundaries of the field of view, which under normal conditions depend on the configuration of the surrounding parts of the face (eyelids, nose shape, nose, edges of the orbit), further on the position of the eye in the orbit, on the size of the pupil and pr 2. Determination of partial precipitation or defects in the field of vision, called "scotomas" and developing under the influence of focal diseases of the optic-nervous system. 3. Determination of color perception at the periphery of the retina. The study is carried out using special instruments - perimeters, which are kinetic, having the form of an arc or hemisphere and statistical, using a computer and its special programs. The kinetic and widespread in our country perimeter of the Forster type, adopted as a prototype (Balashevich LI, “Methods for the study of the visual field", Study Guide, St. Petersburg, publishing house SPbMAPO. - 2004 - 55 p. ... - St. Petersburg: Humanism, 2009). This is an 180 ° arc, covered from the inside with black matte paint and having on the outer surface dividing into degrees - from 0 ° in the center to 90 ° on the periphery. The disc with divisions behind the arc allows you to put it in the position of any of the meridians of the field of view. Illuminance 75 lux. During the diagnosis of vision, white test objects are used in the form of paper circles glued to the end of black matte sticks. White objects with a diameter of 3 mm are used to determine the external boundaries of the field of view, and with a diameter of 1 mm - to detect changes within these boundaries; for color perimetry, use colored (red, green and blue) objects with a diameter of 5 mm, mounted at the ends of the gray rods (reflection coefficient 0.2). Diagnostics on color test objects under illumination is useless, since effects such as reflection, absorption, refraction, and scattering of light act. Arc illumination of at least 160 lux. The examinee places his head on the chin and fixes with one eye (the other is covered by a shutter) a white point in the center of the arc. The test object is conducted in an arc from the periphery to the center at a speed of about 2 cm / s. The patient reports the appearance of the test object, and the researcher notices which division of the arc corresponds at that time to the position of the test object. This will be the outer boundary of the field of view for this meridian. The definition of the boundaries of the field of view is carried out by 8 meridians every 45 °. Color perimetry is carried out in a similar manner. For detection by cattle, a test object with a diameter of 1 mm is used and it is slowly moved along an arc in various meridians, especially carefully in the central and paracentral parts of the field of view, where scotomas are most often observed. The results of the study are transferred to a special scheme of visual fields.

The average person has a white field of vision: 55 ° up, 60 ° down, 90 ° outward and 60 ° inward. The average boundaries of the visual fields in daylight on the colors are as follows: outward - to blue 70 °, to red 50 °, to green 30 °; inward - 50 °, 40 ° and 30 °; up - 50 °, 40 ° and 30 °; down - 50 °, 40 ° and 30 ° respectively. When comparing the boundaries of the field of view of the colors from these figures, it is seen that in daylight, red, blue and green colors clearly lose to white due to diffusion, reflection or absorption of light. Therefore, the perimeter of the visual fields on them, as a rule, is not carried out. In recent years, to characterize changes in the field of view in the dynamics of the disease and statistical analysis, use is made of the total designation of the size of the field of view, which is formed from the sum of the visible sections of the field of view examined in eight meridians. Normally, the average boundaries for a white mark 5 mm in size and a perimeter with an arc radius of 33 cm (333 mm) along the eight meridians (through 45 °) are as follows: outward - 90 °, downward outward - 90 °, downward - 60 °, downward inward - 50 °, inwards - 60 °, upwards inwards - 55 °, upwards - 55 ° and upwards outward - 70 °. Then it turns out 90 ° + 90 ° + 60 ° + 50 ° + 60 ° + 50 ° + 55 ° + 70 ° = 530 °. This value is taken as the norm. The boundaries of the normal field of view to a certain extent depend not only on the research methodology. They are affected by the illumination and remoteness of the object from the eye, the brightness of the background, as well as the contrast between the test object and the background, the speed of the object and its color, in addition, the nurse cannot ensure uniform movement of the test object for objective reasons .. Based on the optical eye structure, its perimeter of vision should be close to the circle. However, modern perimeters measure the fields of vision of the eyes, usually with an arc radius of 33 cm. Obviously, the perimetry of the eye at this distance will be less than the perimetry of the eye at a distance of more than 33 cm up, down and out. The modern technique for determining the perimetry of the eye is not limited to the individual structural features of the patient's face. The fact is that for the process of seeing objects, etc. meets the retina, which has a pigment layer consisting of cones and rods. Cones are much smaller in number than rods and they are mostly located in the middle of the retina. Cones are responsible for color perception. The rods are mostly located on the periphery of the retina and are responsible for twilight and night vision. Therefore, in daylight or in a lit room, the retina of the eye does not fully work, namely: cones try to determine the color, and the rods do not receive the light in which they have high sensitivity (S.N.Basinsky, E.A. Egorov: “Clinical Lectures in Ophthalmology”, 2007, published by GEOTAR-Media INSBN, see Retina). Therefore, with the existing technique, not a small part of the retina is diagnosed, the perimetry of the eye loses about 30%, and the perimetry of the patient’s eyes is a graph of visibility diagrams that are elongated and offset from the center. In order to determine the peripheral field of view of the eyes, it is necessary to create the necessary background and ensure the illumination of the determined test object. With the advent of a statistical method such as computer perimetry to determine the threshold of light sensitivity of the retina, diagnosing various diseases has become much easier and faster. When computer eye perimetry is performed, the patient sits down in front of a special device and fixes his gaze on a specially created light mark. At the same time, light spots of various degrees of brightness appear randomly at various points on the monitor. As soon as the patient sees a white spot, he fixes it by pressing a button on the joystick. The speed of the appearance of white spots and the direction of their movement can vary. Based on the results of the diagnosis, the ophthalmologist sees a picture with the parameters of the boundaries of the patient’s field of vision and, when compared with special maps of the field of view, can judge whether there is a narrowing of the field of view or other disorders. However, this technique also has the disadvantages of kinetic perimeters, since the presence of the same illumination and the white color of the test object. Everyone who has ever undergone a similar perimetry of the eyes remembers that during this procedure, he lost more than one white dot, since the glow time of the test object is short. A computer program, of course, “pulls” the chart by the available points, while reducing the reliability of the result, depending on the age of the patient, by 10-20%. Of the foreign computer perimeters, the most famous are the perimeters “Nshrpgeu”, “Octopus”, “Peritest”, “Perimat”, the super-expensive “AR-3000” and the domestic “Perikom”. The above diagnostic methods for determining the perimetry of vision can be implemented differently, more accurately and cheaper.

Retinal rods are one hundred times more sensitive than cones to the energy of light. A single quantum of light is enough for them to produce a visual signal. They provide vision in low light, such as at night, with very high light sensitivity. Thanks to the wands, we can see quite well at dusk and even at night. It is known that retinal rods are responsible for peripheral vision, the number of which on the periphery of the retina is superior (S.N. Basinsky, E.A. Egorov: “Clinical Lectures on Ophthalmology”, 2007, published by GEOTAR-Media INSBN, see section Retina). Also, it was experimentally revealed (confirmed) that in the dark, the photosensitivity of the photoreceptors (rods) of the retina is maximally sensitive, about a hundred times higher than in daylight, and it fixes color radiation well. Moreover, most importantly, against a dark background, the degree of registration of the primary colors R - red, G - green, B - blue or Ye - yellow radiation does not differ significantly from each other, which is actually used in our utility model. As an example, we can recall that a person can see the flame of a lit match in the dark from a distance of several tens of meters, while in daylight it can be overlooked even from 1.0 meter.

The essence of the utility model is to change the usual conditions when determining the boundaries of the peripheral field of view and color sensitivity on the arc-type perimeter and due to the increased sensitivity of the retina photoreceptors against a dark background to color emission, it is proposed to use a device for determining the boundaries of the peripheral field of view, in which as a point for fixing the patient’s examined eye uses a weak glow of a dull green (G) LED connected through a quenching resistor and closed contacts of a micro button with a 3 V battery and soldered on a small board, which is mounted in the middle of the perimeter arc, and the test object being determined is made in the form of a successively moving luminous dot of a LED along a garland consisting of ten two color (R / G) LEDs parallel connected and located on the inner side of the arc through 5 ° from the mark of the upper edge of 90 ° to the middle of the arc to 40 ° (top to bottom), indicating the magnitude of the field of view. The glow time of the LED of the test object at each arc mark and the pause between moving the luminous test object to the next arc mark after 5 ° is set to 4 seconds, and is selected from the condition of confident registration of the test object. Such uniform movement of the luminous detectable test object is carried out by the control board, which is fixed on the outer side of the upper edge of the arc and is made of foil fiberglass. On the control board there is a 1 kHz frequency generator, a binary frequency divider for 8192, a decimal counter / decoder, two NAND digital circuits (inverters), two micro toggle switches and three micro buttons. The electrical circuit of the control board of the luminous test object is powered from two 1.5 V, connected in series, tablet-type batteries or from a +3 V network adapter and for diagnosing vision provides R, G and Ye glow of the LED representing the test object. The main condition for the procedure for determining the boundaries of the peripheral field of view is reduced illumination (curtains are closed on the windows and the lights are off) or darkness.

To obtain such a claimed technical result in the proposed model for determining the peripheral field of view and the sensitivity of the photoreceptors of the retina, the patient's eyes are sequentially diagnosed with a luminous test object from the R, G or Ye LEDs in a dark room on an arc of 180 ° perimeter, which is used everywhere. Thus, in the proposed utility model, the perimetry of the eyes is performed without any illumination, using the superiority of the sensitivity of the retina rods over the cones, which are more responsible for color perception (Shamshinova AM, V.V. Volkov, chapter “Light perception and visual adaptation”, ed. . 1999).

Distinctive features of the proposed utility model are that the procedure for determining the perimetry and color sensitivity of the patient’s retina is performed in low light (curtains are closed on windows and the lights are off) or in the dark on the main colors of the retina (R, G, B or Ye). The proposed utility model uses the effect of a sharp contrast between the dark background and the illumination of the photoreceptors of the retina from the radiation of a colored LED that performs the function of the test object being determined, which is much larger than the illumination of the photoreceptors of the eye in daylight when there are effects that limit the result of perimetry, such as : reflection, absorption, refraction, light scattering, etc. In addition, a fixed (uniform) time of luminescence and pause when moving the test object from top to bottom along the marks on an arc of 5 ° excludes its loss by the patient on the arc, which is often observed on kinetic and statistical perimeters.

To obtain the named technical result, a utility model is proposed in the form of “A device for determining the boundaries of the peripheral field of view” and color sensitivity, in which a weak glow of a dull green LED connected through a quenching resistor and closed micro-button contacts with 3 In the battery, soldered on a small board, which is fixed in the middle of the perimeter arc. And defined by the boundaries of the peripheral field of view, the test object is performed in the form of a moving luminous dot of the LED along a garland consisting of ten two color (R / G) LEDs connected in parallel and sequentially located on the inner side of the arc at 5 ° marks from the top edge mark 90 ° to the middle of the arc to the 40 ° mark (from top to bottom).

A useful model of the device for determining the boundaries of the peripheral field of view is illustrated by six design drawings presented in FIG. 1 - FIG. 6. In FIG. 1, as an example, typical boundaries of the visual fields of the eyes are presented, with embedded diagrams of color test objects R, G, and B. From the diagrams of the visual fields of the eyes, it can be seen that with the existing methodology, almost 30% of the photoreceptors of the retina do not participate in the perimeter of vision. Firstly, due to the small distance to the arc, secondly, due to the physiological structure of the patient’s face, and thirdly, from the conditions for diagnosing in daylight or when there is little light coming from the white test object to the retina of the eye under examination . This thesis is confirmed by small values of the visual fields on the diagram on R, G and B test objects. In FIG. 2 shows a fragment of the procedure for determining the boundaries of the peripheral field of view in a dark room, where, in the middle of the perimeter arc (1), a board 2 from FIG. 5 with a luminous matte green LED V1 to fix the patient’s examined eye, and the nurse uses a new patient-defined test object in the form of a sequentially moving glow of each LED from a garland mounted on the inside of the arc under the control of board 3 of FIG. 6. The garland LEDs of the device are arranged from top to bottom from the top mark of the 90 ° arc to the 40 ° mark on the arc in 5 ° increments. In FIG. 3 shows a power supply circuit of the LED V1 for fixing the diagnosed eye of the patient. Elements of this circuit: a green LED V1, a limiting resistor R1, a micro button Kn1 and two 1.5 V tablet-type batteries are installed and unsoldered on a small board (2). This board is fixed in the middle of the perimeter arc using double-sided tape. As the V1 LED, you can use the GNL-3004GD green matte LED with a diameter of 2.9 mm and a lens length of 3.5 mm. The value of the quenching resistor R1 is selected to create a dim glow of the LED V1. The micro button Kn1 serves to turn on and off the LED for fixing the eyes of the patient V1. In FIG. Figure 4 shows the electrical circuit for controlling the movement of the detected test object in the form of a luminous LED, which at the beginning of vision diagnostics appears for 4 seconds. at the arc mark of 90 °, then after a pause of 4 seconds. the test object appears for 4 seconds. at an arc mark of 85 °, etc. to an arc mark of 40 °, like a traveling wave.

The device for automatically moving the test object contains a garland of ten two-color LEDs V3-V12, which are installed in 3 mm holes drilled on the central axis of the arc from its upper end at 90 ° down to the middle of the arc with a step of 5 ° to 40 ° at the arc and the control circuit of the luminous test object, which contains a 1 kHz square-wave pulse generator, made on an operational amplifier DA (ОУ - КР1446УД1 in an 8-pin plastic housing of type DIP 201.8-2 contains two ОУ, manufactured according to CMOS technology), etc. changing the input control voltage from 0.1 to 3 V, the generation frequency increases linearly from 0.2 kHz to 6 kHz, the DDI binary frequency divider on the K561IE16 chip, the DD2 decimal counter / decoder on the K561IE8 chip, 6-channel inverters DD3-DD4 on K561LN1 microcircuits - NAND inverters, two micro toggle switches S1 and S2 and three micro buttons Kn.2, Kn.3, Kn.4. The DA device generator is assembled on the following elements: C1 - 0.1 microfarad, R2 - 560 k, R3 - 300 k, R4, R5 - 510 k, R6 - 200 k, R7 - 10 k, R8 - 91 k, R9 - 10 k , R10 - 15 k, R11 - 1.0 M, C2 - 10 microfarads, V2 - KD522 diode. With the indicated values of the circuit elements and the resistive divider R2-R3, the voltage Upit. = 3 V, provides a control voltage of 0.1 V, which is supplied to the control input terminal 5 of the op-amp DA, which makes the generator work with a clock frequency of 1.0 kHz. This clock frequency through the closed contacts 3-1 of the micro toggle switch S1 is fed to the input C (pin 10) of the DD1 binary frequency divider with a division ratio of 8192, after which a signal with a frequency of 0.122 Hz is fed to the input of the decimal counter / decoder DD2 (Cont. 14). The decimal counter / decoder DD2 has 10 output contacts on which a positive signal appears, corresponding to the input periods of the clock frequency of 0.122 Hz. The frequency period of 0.122 Hz of the first clock will be equal in time, 8 seconds. The control circuit uses a positive half-wave of the first cycle lasting 4 seconds. to turn on the LED of the test object and the second 4 sec. half a half-wave to pause. Here it is necessary to recall that the length of the arc with a radius of 33 cm is 103.6 cm, which fall at 90 ° of the circumference, and we have laid ten marks on the circumference of the arc with a step of 5 °, which will be a measurement range of 50 ° from the lower mark in 40 °, which is below the minimum value of the border of the field of view of a person with normal vision of 50 °. Moreover, the length of the arc between the marks of 5 ° will correspond to 2.6 cm. And the cycle or period of the low frequency of 0.122 Hz lasts 8 seconds, i.e. from the beginning of the glow of the LED of the test object from one mark to the beginning of the glow of the next LED of the test object for 8 seconds. accounts for 2.6 cm of arc length, which will correspond to the test object moving speed of 1 cm in 3.25 sec., therefore, the selected LED illumination time of the test object is 4 sec. (1.3 cm.) Is sufficient for confident fixation on the arc. So, on the first output pin 3 of the decimal counter / decoder DD2 appears the first positive signal lasting 4 seconds. after the arrival of the first frequency period with a duration of about 0.122 Hz and a duration of 8 seconds, after which 4 seconds will appear on the second output pin 2 of DD2. a positive signal when a second period of a low frequency signal from the frequency divider DDI, etc., is received at the input of the DD2 counter / decoder, until the last tenth output signal, when 10th 4 sec appears on pin 11 of DD2. positive signal. Each output pin of the decimal counter / decoder DD2 is connected to the inputs of the corresponding inverter of the DD3-DD4 circuits, which invert the input 4 seconds sequentially. positive signals of the decimal counter / decoder DD2 to negative signals. These output contacts of the DD3-DD4 inverters are connected to the cathodes of the two-color LEDs V3-V12. And so, after passing the first period of frequency 0.122 Hz through the counter / decoder DD2, a negative 4 sec will appear at the output of the first inverter DD3 (output pin 5). signal that turns on the V3 LED. It must be borne in mind that the light emission of two-color V3-V12 LEDs depends on the resistance value R12, which is selected by the weak glow of the V3-V12 LEDs and the position of the micro toggle switch S2 and the micro button Kn.4. The fact is that two color LEDs have two anodes, one to turn on the red radiation crystal and the second to turn on the green LED crystal. All the anodes of the V3-V12 LEDs are connected in parallel with each other and through the closed contacts 1-3 of the micro toggle switch S2 and the terminating resistor R12 are soldered to the + 3 V power bus. The position of the closed contacts 3-1 of the micro toggle switch S2 corresponds to the red glow of the LEDs, and when the position is closed pins 3-2 of the micro toggle switch S2 corresponds to the green LED. When the micro button Kn.4 is on, the anodes of the red and green crystals of the LEDs are combined and a third yellow glow of the LEDs is obtained. The micro toggle switch S1 of the device serves to turn off the clock frequency of the DA generator, in which the test object moves along a string of lights connected in parallel with the V3-V12 LEDs and stops in an arc to take readings of the position of the test object in degrees. The button Kn.3 through closed contacts when pressed serves to reset the decimal counter / decoder DD2 to continue diagnostics of the patient's vision on the next meridian.

The board (3) control the test object is carried out in the following sequence. The initial state of the buttons and toggle switches of the electric circuit are set in the following position: the micro button Kn.2 is pressed (the electric control circuit is disconnected from the power supply Ε + 3 V), the micro button KN. 3 pressed, micro toggle switch S1 off. (contacts 2-3 closed), the position of the micro toggle switch S2 can be any (for a red glow when contacts 1-3 are closed, or green when contacts 2-3 are closed), the micro button Kn.4 is depressed. To operate the control board, the first button Kn.2 is turned on and a + 3 V supply voltage is supplied through its closed contacts to the electrical circuit of the control board, and the generator on the DA chip is turned on, from the output of which a signal with a frequency of 1 kHz goes to the input of the binary divider DD1 with the division coefficient 8192, then the button Kn.3 is pressed and the decimal counter / decoder DD2 is reset, then the micro toggle switch S1 is turned on (its contacts 1-3 are closed), and at the input of the decimal counter / decoder DD2 pin 14 receives a signal with divides A DD1 low frequency 0.122 Hz. Then, after the first clock cycle of the low-frequency signal (0.122 Hz) received at the input of the decimal counter / decoder DD2, a positive signal of the first half-cycle, lasting 4 seconds and 4 seconds, will appear on its first output of pin 3. signal of the second half-cycle low level. The positive signal is inverted by the first inverter DD3 to a negative potential of a low level, at which a potential difference appears on the red crystal of the V3 LED, which causes the red light to light for 4 seconds, and on the second half of the cycle, the V3 LED turns off. That is, during the duration of the signal of the first clock cycle (8 seconds) from the output of the counter / decoder DD2, the LED of the test object V3 at the arc mark of 90 ° will light for 4 seconds, and then for 4 seconds. will turn off. Then, a second low-frequency signal of 0.122 Hz is fed to the binary counter / decoder DD2, after which it will turn on for 4 seconds from the second decimal output of the counter / decoder DD2 (pin 2). LED of test object V4 at the arc mark of 85 °, after which for 4 seconds. will turn off. Thus, during the action of ten clock cycles of low frequency from the output of the counter / decoder DD2, the test object is consecutive for 4 seconds. pauses will be sequentially marked for 4 seconds. by illuminating the test object of the garland LEDs, starting from the first LED V3 of the first arc mark at 90 ° down to the last arc mark at 40 ° by illuminating the LED V12. In general, it looks like a traveling wave, only very slow. The patient can only report, seen by the open eye appeared luminous test object on the periphery. The control board (3) by moving the LED of the test object being determined is fixed on the outer side of the upper edge of the arc using 4 screws with M3 nuts. In general, essentially, controlling the movement of the luminous test object along the arc is reduced to turning on two micro toggle switches S2 and S1 (select the color of the LED glow of the test object, turn on / stop the generator) and the micro button Kn.3 (reset the counter / decoder). As the LEDs of the test object under test, represented by the V3-V12 LEDs, which provide three color emissions, you can use the matte two-color LED of the L115VEGW RED / GREEN model (red / green) with a lens diameter of 3 mm and a lens length of 5 mm. A significant advantage of a dual LED is that it occupies one place, but allows you to provide three color emissions R, G and Ye.

The value of the quenching resistor R12 is selected for the dim glow of the V3-V12 LED and can take the value 200 Ohm - 1 kOhm. As a micro toggle switch S2, switching light from red to green and vice versa, you can use the micro toggle switch model MTS101. By turning on the micro buttons with the Kn.4 lock, the anodes of the red and green crystals of the V3-V12 LEDs are combined, which allows you to get a third yellow light emission. As the micro buttons with the locking kn.2 and kn.4 you can use the micro button model B374, 6 pin, size - 7 × 7 mm, handle - 5 mm. As a micro button, Kn.3, you can use the micro button of the MPS 580 model. As a micro toggle switch S1, you can use the micro toggle switch of the MTS-123 model (ON-OFF). The board (3) for controlling the movement of the LEDs of the determined test object can be powered from two 1.5 V batteries (E) connected in series, such as (tablet) LR44, 386A and the like, which are installed on the same board, or from a network adapter by + 3 V. FIG. Figure 5 shows the board (2) assembly, for fixing the patient’s open eye, on which the LED VI, the quenching resistor R1, the micro button with fixing the position of the patient’s open eye Kn1 and two 1.5 V tablet (E) batteries are soldered. The micro button Kn1 serves for On / Off. LED V1. In FIG. Figure 6 shows the control board (3) for the test object being determined, which is made of foil fiberglass with a thickness of not more than 1.5 mm. The connections between the elements of the electric circuit of FIG. 4 are performed by conductors made by chemical etching in an iron chloride solution Fe ₂ Cl ₃ .

The determination of the boundaries of the peripheral field of view and color sensitivity of the eyes on the arcuate perimeter using the utility model is carried out in the following sequence. The nurse presses the micro button Kn.1 on the board (2), which is located in the middle of the arc and turns on the green LED V1, then she presses the micro button Kn.2 and the power supply voltage + 3 V is applied to the board 3 for controlling the movement of the test object to be determined. puts his head on the chin of the arched perimeter and fixes with one eye (the other is covered by a shutter) a luminous green dot on the board (2) in the center of the arc. Then the nurse sets the arc to the desired position (meridian) and the micro toggle switch S2 selects the color of the test object to be determined (red or green) to fix the patient’s open eye, presses the button Kn.3, after which the decimal counter / decoder DD2 is reset and ready to work forming a sequence of signals of the test object. After this, the nurse explains to the patient that he saw the test object from the periphery, should be marked with his voice, or with another sign, and turn off the light in the room. Further, the nurse reminds the patient about the need to use a fixed open eye on the green glow of the LED in the center of the arc to focus on the appearance of the test object on the periphery and turn on the S1 micro toggle switch. After that, the 1 kHz clock frequency of the DA generator, divided into 8192 by the binary counter DD1, is fed to the input of the decimal counter / decoder DD2, which starts to read and set the positive signals of each input low-frequency cycle 0.122 Hz to the DD3-DD4 inverters. Inverters DD3-DD4 invert the input signals from the decoder DD2 and start alternately with a pause of 4 seconds. turn on for 4 sec. LEDs of the test object V3-V12, starting from the upper arc mark - 90 ° (upper V3 LED) at the arc marks 5 ° to the lower mark of the field of view at 40 ° (lower LED V12), marking a glowing test moving 5 ° along the arc object from top to bottom. The speed of movement of the luminous test object is chosen precisely such that it is impossible to miss or overlook the luminous test object. And so, as soon as the patient sees with a peripheral vision a luminous test object that has appeared on the periphery, he informs the nurse who switches off the DA generator from the frequency divider and DD1, DD2 counter / decoder chips with the S1 toggle switch, and the LED test object corresponding to peripheral vision on this meridian in degrees, which is recorded in the patient’s personal card. This will be the value of the external border of the field of view for a given meridian and for a given color of the test object. Further, the position of the arc changes to the position of the next meridian and the verification of the peripheral field of view continues. At the same time, the color sensitivity of the patient to the color of the test object is noted. It should be noted here that against a dark background, the color sensitivity of the retina photoreceptors of a healthy eye is very good. Colors to the patient appear very vibrant. If the patient has vision problems, then this will also affect color perception. The boundaries of the visual fields and the quality of color sensitivity are recorded in an individual map of the visual fields. Next, the nurse switches the micro toggle switch S2 to a different color of light emission, and the procedure for determining the boundary of the peripheral field of view and the quality of color sensitivity on the modified test object continues. If the ophthalmologist deems it necessary, the procedure can be continued on the third light emission, for which it is enough to press the micro button Kn.4 to get yellow light emission. All results of the peripheral field of view and color sensitivity for all colors and meridians are recorded in an individual map of the patient's field of vision. After the procedure for determining the boundaries of the peripheral field of view, the light is switched on in all the meridians in the room. The nurse, clicking on the micro buttons of Kn.1, Kn.2 of the device, turns off the utility model.

As a result of the practical application of the utility model, the accuracy of determining the boundaries of the peripheral visual field and the sensitivity (color sensitivity) of the peripheral photoreceptors of the retina of the eye are increased, due to the sharp contrast between the dark background and the luminous color test object, more confident registration with uniform movement of the test object along the arc due to greater luminous flux entering the retina of the diagnosed eye, which will more accurately indicate the state of vision of the patient’s eyes and Avoid recommendations for certain prophylaxis in the future to maintain vision in good condition.

Literature:

1. Balashevich LI, "Methods of the study of the field of view", Textbook, St. Petersburg, ed. SPbMAPO House - 2004 - 55 p. ... - St. Petersburg: Humanism, 2009.

2. S.N. Basinsky, E.A. Egorov: "Clinical Lectures in Ophthalmology", 2007, ed. GEOTAR-Media INSBN.

3. Shamshinova A.M., Volkov VV, chapter "Light perception and visual adaptation", ed. 1999 year

Claims (1)

A device for determining the boundaries of the peripheral field of view, including a perimeter in the form of an arc of 180 °, and a test object, characterized in that in the middle of the arc to fix the patient’s open eye, a board is mounted with a matte green LED installed on it and connected by a damping resistor, a micro button and two 1.5 V batteries, and the test object being defined is made in the form of 10 parallel-connected two-color R / G LEDs mounted on the central axis from the inside of the arc from the upper edge at 90 ° with a step of 5 ° to the bottom of the arc about 40 °, controlled by a circuit mounted on the outer side of the upper edge of the perimeter arc and containing a 1 kHz rectangular pulse generator connected through a frequency divider with a division coefficient of 8192 and a decimal counter / decoder with two inverter circuits, and made with the possibility of alternating switching on for 4 s and a pause in 4 s of LEDs, by means of two micro-tumblers and three micro-buttons.

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