RU168520U1 - DEVICE OF LIGHT INFLUENCE ON THE VISUAL SYSTEM OF THE PATIENT - Google Patents

Abstract

The utility model relates to the field of medical technology and can be used to study and functional assessment of the psychophysiological state of a person, degree of fatigue, diagnosis of neuropsychiatric abnormalities. The essence of the claimed utility model is that in the device of light exposure to the patient’s visual system, including a power source, a semiconductor light emitter, an microcontroller electrically connected to it, providing light emission with predetermined parameters, made with the possibility of its connection with an external control device that sets the parameters of light radiation, while the semiconductor emitter is mounted in the housing of the optical unit placed on the patient’s head and contains many semiconductor light sources located in the fields of view of the right and left eyes, according to a utility model, the power supply is made as a built-in battery optical unit, the microcontroller is mounted on a board built into the optical unit case, semiconductor the emitter is made in the form of OLED displays located in the optical block body in the fields of view of the right and left eyes, while the device contains a radio module mounted on the board and integrated in the optical block body, connected to the microcontroller and allowing its radio communication with an external control device, and also an ocular optical system mounted in the optical unit, located after the OLED displays in the direction of the light radiation. The technical result achieved by the implementation of the utility model,

Description

The utility model relates to the field of medical technology and can be used for research and functional assessment of a person’s psychophysiological state, degree of fatigue, diagnosis of neuropsychic abnormalities, which is especially important for professional selection and admission to certain types of work that require a quick reaction and concentration with prolonged visual voltage (operators, air traffic controllers, etc.).

Ophthalmological and physiotherapeutic devices are known that provide exposure to the human eye with variable light radiation (as a rule, light-flickering with different frequencies, as well as brightness and spectral characteristics), which has either a therapeutic effect or is used to study the eye and diagnose psychophysiological and psychoemotional state of a person.

The results of the study and diagnosis are based on the analysis of the patient's response to a particular light exposure with certain characteristics, to which the patient responds, as a rule, by pressing a button at the moment of perception of the specified exposure.

A device for light exposure of the patient’s visual system is used to correct depressive conditions and auto-aggressive human behavioral reactions [RU 2479325].

The device in question contains an LED emitter based on single LEDs of various colors, as well as a control and electric pulse generation unit that defines the operating modes of the LED emitter. The structural units included in the device are connected using wire connections. The LED emitter, in particular, is mounted in a spectacle mount.

The device under consideration allows you to vary the brightness, color and geometry of the radiation field.

The disadvantages of this device are the presence in its composition of several nodes interconnected by wire connections, which reduces the compactness of the device and limits the possibility of mutual spatial arrangement of its components. In addition, due to the use of a source containing a limited number of single LEDs, the device does not allow smoothly changing the parameters of light radiation over a wide range, which can reduce the efficiency of light exposure on the patient.

These factors reduce the usability of the device.

A device for light exposure to the visual system of a patient is known [RU 2214150], used for computer diagnostics of unilateral atrophy of the optic nerve fibers, which is selected as the closest analogue.

The device contains an LED emitter of light pulses, a power source for the LED emitter, and a microcontroller electrically connected to the LED source, ensuring the achievement of the specified parameters of the light pulses. In this case, the microcontroller is configured to communicate with an external control device that sets the required parameters of the light pulses.

The LED emitter is mounted in an optical unit mounted on the patient’s head in the form of a spectacle frame. The specified frame contains two opaque hemispheres, on which in the fields of view of the right and left eyes there are groups of single two and three-color LEDs located at an angle to the main optical axis of the corresponding eye, and two two-color LEDs located along the optical axis of the corresponding eye.

The microcontroller is made in the form of a separate unit, which contains means for generating and generating electrical pulses that determine the spectral-light and geometric parameters of the glow field of the LED emitter.

As an external control device, a personal computer with a display was used.

The microcontroller is electrically connected to the LED emitter and to an external control device using wired connections.

In this device, due to the presence of many LEDs in the LED source, it is possible to block the field of view of the eye with a relatively small step.

However, the presence in the composition of the device of blocks remote from each other connected by wire connections, reduces the compactness of the device, and also limits the possibility of mutual spatial arrangement of its components. In addition, since the LED source still contains a limited number of single LEDs, in the device under consideration it is not possible to achieve smooth regulation of the spectral-color and geometric parameters of the glow field.

These factors reduce the usability of the device.

The problem to be solved when implementing the inventive device is to improve usability.

The essence of the claimed utility model lies in the fact that in the device of light exposure to the patient’s visual system, including a power source, a semiconductor light emitter, a microcontroller electrically connected to it, providing light emission with predetermined parameters, configured to communicate with an external control device, specifying the parameters of light radiation, while the semiconductor emitter is mounted in the housing of the optical unit placed on the patient’s head and there are many semiconductor light sources located in the fields of view of the right and left eye, according to a utility model, the power supply is made in the form of an optical battery pack integrated into the housing of the battery, the microcontroller is mounted on a circuit board integrated in the optical unit housing, the semiconductor emitter is made in the form of OLED displays located in the case of the optical unit in the fields of view of the right and left eyes, the device comprises a radio module mounted on a board and built into the body of the optical unit, connected with the microcontroller and providing the possibility of its radio communication with an external control device, as well as an ocular optical system mounted in the optical unit, located after the OLED displays along the light path.

Essentially important in the claimed device is that its main functional units are made in the form of miniature parts and boards mounted in a single optical unit housing, such as flat OLED displays (electroluminescent displays on organic light-emitting semiconductors, the thickness of which does not exceed 1 mm), installed on the board, in particular, on two boards in the fields of view of the right and left eye, a microcontroller mounted on the board of the radio module. Thanks to this, the compactness of the design of the claimed device and the convenience of its assembly in the assembled form on the patient's head are achieved.

Moreover, the presence of a radio module allows you to receive signals from an external control device via a wireless radio link, which provides convenience and freedom of placement of the claimed device relative to the specified external device, including the possibility of their remote relative positioning. In particular, radio communication may be via a Bluetooth communication channel.

In addition, the use of semiconductor OLED displays rather than single semiconductor sources (light emitting diodes) as a light source makes it easier, within a wider range and for a larger number of parameters, to control the optical characteristics of the light radiation emitted from the displays (light test pulses) using a microcontroller.

Thus, in particular, OLED-controlled microcontroller displays provide the possibility of obtaining a light spot, the size of which varies in the range from 1 mm to 10 mm in 0.5 mm increments, and the possibility of varying the position of the light beam in the field of view ± 50 ° from the optical axis in increments 1 °, the possibility of varying the spectral color characteristics of light radiation in four ranges: blue from 430 to 470 nm, yellow-green from 540 to 580 nm, orange from 600 to 620 nm and red from 640 to 660 nm.

Since the displays are located near the patient’s eyes in the operating position of the device, the device contains eyepieces that are mounted in the optical module and are located in the fields of the right and left eyes along the light rays after OLED displays, which form a visible image of the emitted light signals for the eyes.

Thus, the technical result achieved by the implementation of the utility model is the creation of a device that is convenient for practical use for the light exposure of the patient’s visual system, which allows for smooth adjustment of light emission modes over a wide range.

In FIG. 1 shows a functional diagram of the inventive device, in FIG. 2 is a drawing showing a detail of the inventive device in a perspective view; FIG. 3 is a drawing explaining the operation of the device.

The device comprises a power source 1, electrically connected to the microcontroller 2, which is electrically connected to the semiconductor radiation source 3, and also to the radio module 4. The device also contains an optical system containing eyepieces 5, designed to perceive the light signal generated by the displays 3 by the patient's right and left eyes , as well as holders 6 (Fig. 2).

The power source 1 is made, in particular, in the form of rechargeable flat Li-ion batteries. The radiation source 3 is made in the form of two OLED displays that generate light radiation (in the form of light test pulses), designed to affect the right and left eyes of the patient. The microcontroller 2 includes a generator and an electric pulse generator mounted on the board (not shown in the drawing) and is configured to generate electrical pulses that enable OLED displays 3 to generate a light signal with specified optical parameters. The microcontroller 2 is made, in particular, in the form of two separate boards, each of which is electrically connected to one of the OLED displays 3. The radio module 4 is mounted on the board and configured to receive a radio signal from an external control device 7 (Fig. 3) that sets the required parameters light radiation, and converting the specified radio signal into an electrical signal that controls the operation of the microcontroller 2. In particular, the radio module 4 is configured to receive the radio signal via Bluetooth.

All of the above nodes of the claimed device are mounted in a light-absorbing case 8 (Fig. 2 and Fig. 3) of an optical unit made in the form of a modified spectacle frame fixed to the patient’s head.

The device operates as follows.

The inventive device mounted in the housing 8 of the optical unit is placed on the patient's head in such a way that the eyepieces 5 are located opposite his right and left eyes.

Using an external control device 7 (Fig. 3) set the required optical parameters of the light test pulse. The external control device 7 is made, in particular, on the basis of the tablet. The device 7 generates a control radio signal, which is transmitted via Bluetooth to the radio module 4. Based on the control signal received by the radio module 4, the microcontroller 2 sets the modes for generating light pulses. OLED displays 3 and an ocular optical system containing eyepieces 5 generates light test pulses with predetermined optical characteristics that affect the visual system of the patient.

Registration of the patient's response to light radiation is carried out using an external reaction sensor 9 (Fig. 3). The reaction sensor 9 contains a button 10 (Fig. 3), when pressed, the sensor 9 generates a reaction signal, in particular, transmitted in the form of a radio signal via Bluetooth to an external control device 7.

In particular, the repetition rate of light pulses is varied and the critical flicker fusion frequency is determined, that is, the frequency at which the test eye begins to perceive radiation as continuous (at this moment the patient presses button 10 of the reaction sensor 9). The value of the specified frequency via Bluetooth from the sensor 9 is transmitted to the control device 7, where it is entered into the database. Switch to another test eye and repeat these steps. The following test cycle is carried out with other parameters of the light test pulse, which determine the geometry, brightness, color of the light radiation. The resulting data array is analyzed and, on this basis, a diagnosis of the visual system or assessment of the patient’s condition is made.

Claims (1)

A light exposure device for the patient’s visual system, including a power source, a semiconductor light emitter, a microcontroller electrically connected to it, providing light emission with predetermined parameters, configured to communicate with an external control device defining light radiation parameters, while the semiconductor emitter is mounted in the housing placed on the patient’s head of the optical unit and contains many semiconductor light sources, located data in the fields of view of the right and left eyes, characterized in that the power source is made in the form of an optical battery pack integrated into the housing of the battery, the microcontroller is mounted on a circuit board built into the optical housing, the semiconductor emitter is made in the form of OLED displays located in the optical housing in fields of view of the right and left eyes, while the device contains a radio module mounted on the board and built into the body of the optical unit, connected to the microcontroller and allowing it to be communication with an external control device, as well as an ocular optical system mounted in the optical unit, located after OLED displays along the path of light emission.

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