RU2197895C1 - Method and device for controlling human health state - Google Patents

Abstract

FIELD: medical engineering; medicine. SUBSTANCE: method involves sending emitted signals for instance along eyelid surface. The eyelid being closed, test signal refraction coefficient of propagation external layer like waveguide. It causes test signal damping. The emitted test signals are also sent in the direction of internal surface of the eyelid. When the eyelid is closed the test signals reflect from the eyelid. The eyelid being open, the test signals are scattered in the surrounding space. The device has test signal emitters, main and auxiliary test signal receivers, unit for data processing, alarm signal broadcast transmitter test signal and autonomous power supply source. The units are spaced over surface or inside of a contact lens in its peripheral part. The number of test signal transmitters and receivers is the same. The device also has alarm signal transceiver positioned outside of patient eye. EFFECT: enhanced effectiveness of control; improved noise immunity and reliability of operation. 10 cl, 3 dwg

Description

 The invention relates to the field of radio electronics and can be used to monitor the condition of a person mainly in critical situations (when the driver of a moving vehicle falls asleep, the patient worsens, the offender is attacked, etc.).

 A known method of monitoring the condition of a person, comprising emitting in a continuous or intermittent mode a test signal of the radio wave range, for example, the optical, and in particular infrared, wave range along the outer surface of the eye of a controlled person, modulating its intensity by exposing the emitted test signal to the eyelid when its blinking due to interruption of the test signal when closing the eyelid, receiving a test signal, its analysis and the formation of an alarm, such as a siren (US 5402109 A, 1995).

 This method is implemented by a device known from the same patent, comprising a continuous or intermittent test signal of a radio wave range connected to a power source and serially connected to a test signal receiver, an information processing unit and an alarm generating unit located outside the eye of a controlled person, the emitter and the receiver of the test signal is mutually arranged so that at least one eye eyelid of a controlled person is partially ill when moving during blinking completely overlaps the path test signal, wherein said elements can be placed, for example, eyeglass frame, worn on the person monitored.

 These method and device are ineffective. This is due to the fact that the possibility of false alarms, for example, during sudden movements of a controlled person, is not eliminated. It is only envisaged to detect sleep with the closed eyelids of a controlled person, which does not allow, for example, to detect a state of loss of consciousness in which the eyelids can remain open. The placement of device elements external to the eye of a controlled person requires their precise adjustment both during calibration of the device and during its operation.

 Of the known methods, the closest to the proposed one is a method for monitoring a person’s condition, including periodically emitting a test signal at a radio frequency along or in the direction of the eye eyelid of a controlled person, modulating its intensity by affecting the emitted test signal with an eye eyelid, receiving a test signal and its processing by converting it into an electrical signal, analyzing this signal and generating an alarm (US 6087941 A, 2000). Radiation, modulation, reception and processing of the test signal in this method is carried out from the outside of the eye eyelid of a controlled person.

 This method allows you to determine whether the controlled person falls asleep or falls asleep. When the eyelids of the controlled person become heavier or close, which interrupts for a predetermined period of time a test signal directed from the outside, for example, to a detectable distinguishing feature in the eye eyelid, an alarm signal is generated that awakens the controlled person.

 In the same patent, in one embodiment, a device for monitoring a person’s condition, which is closest to the one proposed, is described. It contains an ophthalmic contact lens located on the eye of a controlled person, equipped with an autonomous power source of at least one emitter of the test signal, the frequency of which is selected in the radio frequency range, located in the peripheral part of the ophthalmic contact lens, and serially connected to the main receiver of the test signal located in relation to the emitters of the test signal with the possibility of changing the intensity of the emitted test signal during blinking of the eyelid, the image processing unit information bots and an alarm generation unit. The main receiver of the test signal and the information processing units for generating an alarm are placed outside the eyes of the controlled person, for example, on a body opposite the head of the driver of the vehicle.

 The specified method and device is also not effective enough. The test signal is open to external influences, which reduces noise immunity. Placing most of the elements outside the eye of a controlled person does not provide stealth, which is especially important, for example, when attacking a controlled person by an attacker. It is possible to detect only a state of sleep or falling asleep of a controlled person, a decrease in the frequency of blinking (which precedes, for example, loss of consciousness) and the absence of blinking with constantly open eyelids is not analyzed. Not always the test signal falls on the main receiver of the test signal, for example, due to unexpected sudden movements of the head or the characteristics of the blinking of a particular controlled person, since there is only one such receiver of the test signal. Finally, the device does not contain elements that allow you to transmit an alarm signal at a distance, which does not allow you to quickly monitor a person’s condition and limits the possibility of external assistance.

 The problem solved by the invention is to create a method for monitoring the condition of a person and a device for monitoring the condition of a person without the disadvantages of the prototype. The technical result provided by this method and device is to increase their efficiency. Improving the efficiency of the method, in particular, is achieved by increasing the noise immunity and stealth control. Improving the efficiency of a device for monitoring the state of a person, in particular, is achieved by increasing the objectivity, noise immunity, stealth and speed of control of such a device, as well as increasing its operational reliability.

 This is achieved by the fact that in a method for monitoring a person’s condition, including periodically emitting a test signal at a radio frequency along or in the direction of the eye eyelid of a controlled person, modulating its intensity by affecting the emitted test signal with an eye eyelid, receiving a test signal and processing it by converting it into an electrical signal, analyzing this signal and generating an alarm, radiation, modulation, reception and processing of the test signal is carried out in the space between the eyeball and the ophthalmic century. The intensity of the test signal emitted along the inner surface of the eyelid can be modulated by changing the refractive index of the medium in which the test signal propagates. The intensity of the test signal emitted in the direction of the eyelid can be modulated by changing the reflection coefficient from its inner surface.

 Distinctive features of the proposed method are operations with a test signal in the space between the eyeball and the eyelid of a controlled person.

 The achievement of the above technical result is provided by a device for monitoring the condition of a person, which, like the device closest to it according to US Pat. No. 6087941, contains an ophthalmic contact lens placed on the eye of a controlled person, equipped with an autonomous power source of at least one emitter of a test signal whose frequency is selected in the radio frequency range, located in the peripheral part of the ophthalmic contact lens, and series-connected to the main receiver t-signal, located in relation to the emitters of the test signal with the possibility of changing the intensity of the emitted test signal during blinking of the eyelid, an information processing unit and an alarm signal generating unit.

 In contrast to the known device, the proposed device contains additional test signal receivers, the number of emitters and test signal receivers being the same, the test signal receivers and the information processing unit are located in the peripheral part of the ophthalmic contact lens, and the emitters and receivers of the test signal form pairs, in each of which the emitter and receiver of the test signal are located with the possibility of changing the intensity of the emitted test signal when the eye surface blinks Moreover, the alarm generating unit is made in the form of an alarm transmitter located in the peripheral part of the ophthalmic contact lens and an alarm transceiver located outside the human eye at a distance from it, selected from the condition of stable radio communication between the transmitter and the transceiver of the alarm signal.

 The emitters and receivers of the test signal, the information processing unit and the alarm transmitter can be placed on the surface of the ophthalmic contact lens. The emitters and receivers of the test signal, the information processing unit and the alarm transmitter can be placed inside an ophthalmic contact lens. The alarm transceiver may be in the form of a cell phone. Autonomous power supply can be made in the form of a solar battery. In each pair between the emitter and the receiver of the test signal can be placed a waveguide. The emitter and receiver of the test signal in each of the pairs can be combined. The information processing unit and the alarm transmitter can also be combined.

The proposed invention is illustrated by drawings, which depict:
in FIG. 1 is a structural block diagram of a device for monitoring human condition;
in FIG. 2 - an example of the placement and interaction of elements during the propagation of a test signal emitted along the inner surface of the eye eyelid (one pair of emitter-receiver of the test signal is conventionally shown);
in FIG. 3 is an example of the placement and interaction of elements during the propagation of a test signal emitted in the direction of the eye eyelid (one pair of emitter-receiver of the test signal is conventionally shown).

 In accordance with the proposed method, all operations with a test signal (test signals) are carried out between the eyeball (including the pupil 1 and the iris 2) and the eye eyelid 3 (figure 3 shows the upper eye eyelid 3) of a controlled person. Moreover, in one embodiment of the method, the emitted test signal, the direction of which (the path) is conventionally indicated by arrow 4, is directed along the inner surface of the eye eyelid 3 (Fig. 2). At the moment when the eyelid 3 does not cover the surface along which the test signal propagates, it passes along this surface freely. When the eyelid 3 is closed and touches the surface along which the test signal propagates, the refractive index of the outer layer of this surface changes and the test signal weakens or decays. In another embodiment of the method, the emitted test signal is sent in the direction of the eye eyelid 3 (FIG. 3). At the moment when the eyelid 3 is closed, the test signal is reflected from its inner surface, when it is open, the test signal passes out and is scattered in the surrounding space.

 The proposed device for monitoring human condition contains emitters of the test signal 5, the main 6 and additional 7 test signal receivers, an information processing unit 8, an alarm transmitter 9, made, for example, in the form of microchips, and an autonomous power source 10 connected to the above elements that can be made, for example, in the form of a solar battery. The wavelength and energy of the test signal are selected in such a way as not to interfere with the eye of a controlled person and not to produce harmful effects on his organs. The listed elements are placed on the surface or inside the ophthalmic contact lens 11 mounted on the eye of a controlled person, in its peripheral part, so as not to interfere with the eye and not irritate the inner surfaces of the eyelids 3. Set of elements 5, 6, 7, 8, 9 , 10 or 6, 7, 8, 9, 10, or in another embodiment, combinations can be made in the form of a single microchip. The number of emitters of the test signal 5 and the number of all receivers of the test signal 6, 7 are chosen the same. They form pairs, the number of which is determined by the condition of complete or at least significant overlapping by the inner surface of the eye eyelid 3 of the corresponding part of the ophthalmic contact lens 11. Mostly their number is two or three pairs (in the extreme case, their number is equal to one, as in one of variants of the prototype device). The emitters 5 and receivers 6, 7 of the test signal in each pair are located on the ophthalmic contact lens 11 (outside or inside it) so that it is possible to influence the inner surface of the eye eyelid 3 on the path 4 of the test signal. The device also contains an alarm transceiver 12, for example, in the form of a cell phone, placed, for example, in the pocket of the clothes of a controlled person.

 Depending on the choice of the direction 4 of the test signal, toward the inner surface of the eye eyelid 3 or along it, the functioning of the proposed device has its own characteristics.

 In one embodiment of the proposed method and device, which is simpler (Fig. 3), emitters of the test signal 5, for example, in the amount of three (in Fig. 3 the second and third emitters of the test signal 5 are not shown for simplicity) form the output of the test signals, which are mainly a sequence of pulses emitted in the direction 4 to the inner surface of the eyelid 3. When the eyelid 3 is open, the test signals, or at least most of them, go into the surrounding space and are scattered there. When the eyelid 3 is closed, the test signals are reflected from its inner surface and enter the corresponding main 6 and additional 7 test signal receivers (in Fig. 3, test signal receivers 6, 7, as well as information processing unit 8 and an autonomous power supply , not shown for simplicity). In the process of "normal" blinking, the inner surface of the eye eyelid 3 periodically with a frequency of normal blinking reflects the test signal.

 The test signals detected mainly by 6 and 7 additional receivers are fed to information processing unit 8, in which, in accordance with a predetermined algorithm, the modulation frequency is analyzed and compared with the “normal” frequency. At the same time, the algorithm of its operation takes into account the probability that, for example, one of the test signals did not reflect from the closed eye eyelid 3, for example, due to the peculiarities of human blinking. In the case of a “normal” flashing process, the corresponding signal is absent at the output of this unit and the alarm transmitter 9 does not generate and does not transmit an alarm signal. In the case when the controlled person is, for example, in a state of drowsiness, the blinking frequency becomes abnormally high and the information processing unit 8 provides a corresponding signal to the alarm transmitter 9, the output of which is an alarm, for example, a radio signal that is transmitted to the signal transceiver anxiety 12.

 The alarm transceiver 12 generates, for example, an acoustic signal that interrupts drowsiness. In the case when the controlled person is close to a state of loss of consciousness (fainting), the frequency of blinking becomes abnormally low, and an alarm signal is also generated in a similar way. In the event that a sudden state of sleep, loss of consciousness, or intentional closing of the eye (s) of a controlled person who is in an alarming position (for example, when the offender attacks him or other people nearby to secretly give an alarm) is made, when closed eye eyelids 3 test signals begin to arrive in the main 6 and additional 7 test signal receivers for a long time, which also leads to the formation of an alarm. In the case when there is a sudden loss of consciousness with open eyelids 3, the test signals cease to come in the main 6 and additional 7 receivers of the test signal, which also due to the specified algorithm of the information processing unit 8 provides the formation of an alarm.

 In this case, the alarm transceiver 12, for example, in the form of a cell (mobile) telephone, can transmit the alarm signal over a considerable distance, for example, to the rescue service. At the same time as an alarm, service information can be transmitted that allows you to identify a controlled person who needs help, including blood type, intolerable medicines, etc. If your cell phone is equipped with a location function (for example, has a built-in GPS receiver), then at the same time, information about the location of a person in need of assistance can be transmitted. When using the "Bluetooth" technology as a means of transmitting an alarm signal, it is possible to send back to a controlled person a secret signal that information has been received from him and, for example, the corresponding group of rescuers has been sent to the scene.

 In another embodiment of the proposed method and device for monitoring the human condition (Fig. 2), emitters of the test signal 5 generate test signals in a similar manner, but in the direction 4 along the inner surface of the eye eyelid 3 to the corresponding receivers of the test signal 6, 7, mainly along waveguides 13, for example, made two-layer (for simplicity, only one emitter of the test signal 5, one waveguide 13 and not additional emitters of the test signal 7 and eye eyelid 3 are also shown in FIG. 2).

 In the described implementation example, the information processing unit 8 and the alarm transmitter 9 are made combined in the form of one unit 14. During the “normal” blinking, the inner surface of the eye eyelid 3 periodically contacts the outer surface of the waveguides 13. With this contact, the refractive index (and, therefore, the reflection coefficient) of the outer layer of the waveguides 13 changes in such a way that, for example, the conditions for total internal reflection in them are violated and the test signals partially or completely go beyond the wavelength novovod 13, without falling into the corresponding receivers of the test signal 6, 7. Thus, the modulation of the intensity of the test signals with a blinking frequency is carried out. Moreover, at the device output, as in the previous implementation example, an alarm signal is not generated.

 In the case when the controlled person is in a state of drowsiness or close to a state of loss of consciousness, an alarm signal is generated at the output of the alarm transmitter 9, and in this case block 14. It is possible to analyze not only the frequency (period) of blinking, but also a separate analysis of the time periods when the eye eyelids 3 are open and closed, as well as an analysis of the speed of closing and opening of the eye eyelids 3, for example, by measuring the fronts and decays of the corresponding pulse sequences, which allows the conclusion about the need to generate an alarm more quickly and reliably (this is ensured by setting the corresponding algorithm of block 14). In terms of alarm transmission, the operation of the described embodiment of the device does not differ from the operation of the first implementation example.

 The method of monitoring the condition of a person in accordance with the claimed invention provides, in comparison with known similar methods, an increase in its effectiveness by increasing the noise immunity and stealth control. A device for monitoring the condition of a person in accordance with the claimed invention provides, in comparison with known similar ones, an increase in its effectiveness by increasing the objectivity, stealth and efficiency of control, as well as increasing its operational reliability.

Claims (11)

 1. A method for monitoring a person’s condition, including periodically emitting a test signal at a radio frequency along or in the direction of the eye eyelid of a controlled person, modulating its intensity by affecting the emitted test signal with an eye eyelid, receiving a test signal and processing it by converting it to electrical signal analysis of this signal and the formation of an alarm, characterized in that the radiation, modulation, reception and processing of the test signal is carried out in the space between the eyeball and the eye th.  2. The method of monitoring the human condition according to claim 1, characterized in that the intensity of the test signal emitted along the inner surface of the eyelid is modulated by changing the refractive index of the medium in which the test signal propagates.  3. The method of monitoring the human condition according to claim 1, characterized in that the intensity of the test signal emitted in the direction of the eyelid is modulated by changing the reflection coefficient from its inner surface.  4. A device for monitoring the condition of a person, containing an ophthalmic contact lens placed on the eye of the controlled person, equipped with an autonomous power source at least one emitter of a test signal, the frequency of which is selected in the radio frequency range, located in the peripheral part of the ophthalmic contact lens, and connected in series the main receiver of the test signal, located in relation to the emitters of the test signal with the possibility of changing the intensity of the emitted test a blinker of the eyelid, an information processing unit and an alarm generating unit, characterized in that it contains additional test signal receivers, the number of emitters and test signal receivers being the same, the test signal receivers and the information processing unit are located in the peripheral part an ophthalmic contact lens, and the emitters and receivers of the test signal form pairs, in each of which the emitter and receiver of the test signal are arranged with the possibility of changing the intensity and the irradiated test signal when the eyelid blinks on its inner surface, while the alarm generation unit is made in the form of an alarm transmitter located in the peripheral part of the ophthalmic contact lens, and an alarm transceiver located outside the human eye at a distance from it, selected from the condition stable radio communication between the transmitter and the transceiver of the alarm.  5. The device for monitoring the human condition according to claim 4, characterized in that the emitters and receivers of the test signal, the information processing unit and the alarm transmitter are located on the surface of the ophthalmic contact lens.  6. The device for monitoring the human condition according to claim 4, characterized in that the emitters and receivers of the test signal, the information processing unit and the alarm transmitter are located inside the ophthalmic contact lens.  7. The device for monitoring the human condition according to claim 4, characterized in that the alarm transceiver is made in the form of a cell phone.  8. The device for monitoring the human condition according to claim 4, characterized in that the autonomous power source is made in the form of a solar battery.  9. A device for monitoring a person’s state according to claim 4, characterized in that a waveguide is placed in each pair between the emitter and the receiver of the test signal.  10. The device for monitoring the human condition according to claim 4, characterized in that the emitter and receiver of the test signal in each of the pairs are made combined.  11. The device for monitoring the human condition according to claim 4, characterized in that the information processing unit and the alarm transmitter are made combined.

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