WO2022139619A1 - Wearable device for storing information about a user - Google Patents

Abstract

The present technical solution relates, in general, to wearable systems for monitoring the state of a user, and more specifically to smart elements of clothing for monitoring biometric indicators of a user and interacting with said user. The main technical result constitutes creating an efficient wearable article for receiving and storing information relating to the state of health of a user. Proposed in a preferred embodiment of the claimed solution is a wearable device for storing information about a user, said device comprising: at least one item of clothing made from fabric; at least one human-machine interaction module which is disposed on the at least one item of clothing and is capable of interacting with the user of the wearable device; at least one processor capable of interacting with the human-machine interaction module; at least one means for storing information, which means is connected to the human-machine interaction module; and a transceiver module.

Description

WEARABLE DEVICE FOR STORING INFORMATION ABOUT USER

FIELD OF TECHNOLOGY

[1] The present technical solution generally relates to wearable user monitoring systems, and more specifically to smart clothing items for monitoring and interacting with the user's biometrics.

BACKGROUND OF THE INVENTION

[2] Currently, there is a high interest in the world in the development of smart clothes, as well as the introduction of technologies that expand the functionality of such clothes. Smart clothing refers to a type of clothing with built-in electronic elements. Typically, these garments can be made with smart fabrics, e-textiles or e-textiles (e-textiles) and have built-in sensors. Smart clothing is capable of monitoring the user's biometric indicators and transmitting monitoring data to computing devices in a timely manner. Elements of smart clothing can be applied in sports, fitness, health, physiotherapy, medicine and other areas of life to determine the main vital signs, such as heart rate, respiration, temperature, electromyography and other biometric indicators

[3] Prior to the widespread use of smart clothing, sensors were individually attached to the observed person in various locations depending on the information being tracked to measure and monitor the user's biometrics. This was time consuming, especially when measuring several different biometrics. In addition, such sensors could move, slip, or restrict the user's movement when active, which could lead to inaccurate measurements and incorrect diagnosis.

[4] In this regard, smart clothes are most widely used in areas where there is a risk to human life and health.

[5] However, despite the intensive development of technologies for monitoring the state of the user using smart clothes, there are currently a number of problems associated with the use of such clothes.

[6] Thus, clothing for accommodating a plurality of sensors for monitoring the health of a patient is known from the prior art, described in international patent application No. WO 2010038176 Al (KONINKLIJKE PHILIPS ELECTRONICS; PHILIPS INTELLECTUAL PROPERTY), publ. 04/08/2010. Said clothing is made of elastic material. The main feature of this invention is the ability to install on the side of the clothing in contact with the skin of the user, a removable sensor holder made of a flexible and inextensible material, with appropriate sensors for measuring the user's indicators, and the sensors on the specified holder are located in predetermined positions.

[7] The disadvantages of this device include the bulkiness of the design with sensors, which in turn can cause discomfort when worn by the user, because the holder is inextensible, the absence of informative interaction with the user, and also the inapplicability of the user during active physical exertion (due to design features). Another disadvantage is the inability to use these clothes in telemedicine.

[8] Also, the prior art wearable device, made in the form of clothes, for monitoring the biometric parameters of the patient, described in US patent No. US 7319895 B2 (TAM TELESANTE), publ. 01/15/2008. Said clothing is made of an elastic material containing flexible sensors for monitoring the patient's biometric indicators, a power source and elastic conductive threads that connect the sensors and clothing items. Said clothing is configured to transmit data received from sensors to an external device.

[9] The disadvantages of such a device include a limited set (due to the characteristics of the device) of the patient's biometric indicators, the lack of means of interaction with the patient, as well as the impossibility of remote informative notification of the patient undergoing treatment at home about the course and process of treatment and the impossibility of reminding the patient about the implementation doctor's instructions prescribed to him, which also complicates the use of this device in telemedicine.

[10] Common shortcomings of existing solutions in this area are the lack of smart garments that provide effective user interaction, which can be used in telemedicine, while maintaining the comfort and versatility of the garment itself.

ESSENCE OF THE TECHNICAL SOLUTION

[11] This technical solution is aimed at eliminating the shortcomings inherent in existing solutions known from the prior art. [12] The claimed solution allows solving a technical problem in terms of creating a new and efficient wearable device for measuring, storing information about the user and interacting with him.

[13] The main technical result is the creation of an effective wearable product for receiving and storing information related to the health of the user.

[14] Also, due to the creation of the claimed product, the arsenal of technical means of wearable devices is expanding to obtain information about the user's health status.

[15] The claimed technical result is achieved through the implementation of a wearable device for storing information about the user, containing:

• at least one piece of clothing made of fabric;

• at least one human-machine interaction module located on at least one piece of clothing, configured to interact with the user of the wearable device;

• at least one processor configured to interact with the human-machine interaction module;

• at least one information storage means associated with the human-machine interaction module;

• receiving-transmitting module.

[16] In one particular embodiment, at least one garment is a compression garment.

[17] In another particular implementation, at least one garment may be at least the following items: a suit, a waist garment, a shoulder garment, a jumpsuit.

[18] In another particular embodiment, at least one garment further comprises a conductive layer.

[19] In another particular embodiment, the conductive layer is a stretchable conductive ink.

[20] In another particular embodiment, at least one garment further comprises at least one electromagnetic emitter, one electromagnetic receiver, and one electromagnetic conductive track.

[21] In another particular implementation, at least one electromagnetic conductive path is located on the garment in the area of the wearer's joints. [22] In another particular embodiment, at least one garment further comprises at least one sensor configured to monitor performance.

[23] In another particular implementation, at least one sensor represents at least one sensor selected from the group: accelerometer, gyroscope, electrocardiogram (ECG) sensor, electroencephalography (EEG) sensor, electromyography (EMG) sensor, strain gauge, temperature sensor , pulse oximeter, respiration sensor, humidity sensor, pressure sensor, carbon dioxide sensor, or combinations thereof.

[24] In another particular embodiment, the human-machine interaction module comprises at least one of: a display, a speaker, a microphone, or combinations thereof.

[25] In another particular implementation, the display is at least one display selected from the group: touch display, LCD display, flexible display, E-ink display, or combinations thereof.

[26] In another particular implementation, at least one display is located on the garment in the area corresponding to the user's body part.

[27] In another particular implementation, the processor is configured to notify the user, using a human-machine interaction module, of scheduled procedures.

[28] In another particular embodiment, the processor is further configured to generate a user profile based on data received from at least one sensor.

[29] In another particular implementation, the processor is configured to send an alarm signal to the computing device upon receipt of critical readings from at least one sensor.

[30] In another particular implementation, at least one garment contains a unique identifier.

[31] In another particular embodiment, the unique identifier is associated with at least the user's electronic medical record.

[32] In another particular embodiment, an electronic health record is synchronized with a wearable device in terms of transmitting data about medical prescriptions.

[33] In another particular embodiment, at least one garment further comprises a stimulant. [34] In another particular embodiment, at least one garment further comprises thermal control elements.

[35] In another particular embodiment, at least one garment further comprises LED elements.

[36] In another particular embodiment, the transceiver module is at least one of: NFC module, Bluetooth, BLE, Wi-Fi module, GSM module, LTE module.

[37] In another particular embodiment, the device further comprises a GPS module.

[38] In another particular embodiment, the device further comprises an external power source.

[39] In another particular embodiment, the external power source is solar panels located on at least one piece of clothing.

[40] In another particular implementation, when synchronized with a medical record, information is displayed on the display of a wearable device.

[41] In another particular implementation, an alert is additionally generated in the form of a sound signal, a vibration signal, or a digital message.

[42] In another particular embodiment, the digital message is transmitted to at least one computing device.

DESCRIPTION OF THE DRAWINGS

[43] The features and advantages of the present invention will become apparent from the following detailed description of the invention and the accompanying drawings, in which:

[44] FIG. 1A illustrates an overview of a wearable device for storing user information.

[45] FIG. 1B illustrates an example general view of a wearable device for storing information about a user.

[46] FIG. 2 illustrates an example of a system for interacting a smart garment with a computing device.

[47] FIG. 3 illustrates an example of the interaction of several devices.

IMPLEMENTATION OF THE INVENTION

[48] The claimed solution provides the possibility of effective use of smart clothing elements in telemedicine, by providing informative interaction of smart clothing elements with its wearer, continuous tracking of both biometric and environmental indicators, transmission of measured indicators to a computing device, as well as the possibility of notifying and reminding the wearer of the suit about the planned procedures and tracking their correct implementation. In addition, the claimed wearable device provides a comfortable and convenient fit on the user's body, while maintaining high measurement accuracy.

[49] In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the various embodiments of the claimed technical solution. However, one skilled in the art will appreciate that various embodiments of the present technical solution may be practiced without some of these specific details. The following description provides only exemplary embodiments and is not intended to limit the scope or applicability of the disclosure. Also, it should be appreciated that the elements of the claimed solution may be practiced in a variety of ways beyond the specific details set forth herein.

[50] FIG. 1A is a perspective view of wearable device 10. Device 10 in one embodiment includes at least one garment 20 that includes: at least one human-machine interaction module, at least one computing module, such as a processor or microcontroller, at least one information storage means and a transceiver module. A more detailed description of the wearable device 10 is provided in FIG. 1B.

[51] In FIG. 1B shows an example of a general view of the wearable device 10.

[52] In general, the computing device 10 comprises one or more computing modules connected by a common information exchange bus, for example, one or more processors 101, a memory 102, which may include memory means such as RAM and ROM, one or more data transmission means 103 input/output interfaces 104, input/output devices 105.

[53] The processor 101 (or multiple processors, multi-core processor, etc.) may be selected from a variety of devices currently widely used, for example, manufacturers such as: Intel™, AMD™, Apple™, Samsung Exynos™, MediaTEK™, Qualcomm Snapdragon™, etc. Under the processor or one of the processors used in the device 100, it is also necessary to take into account the graphics processor, for example, an NVIDIA or Graphcore GPU, the type of which is also suitable for full or partial execution of the execution of the control module, and can also be used to train and apply machine learning models in various information systems.

[54] The memory 102 may include a RAM 102, which is a random access memory and is designed to store machine-readable instructions executable by the processor 101 to perform the necessary data logical processing operations. RAM typically contains the executable instructions of the operating system and associated software components (applications, program modules, etc.). In this case, the RAM 102 may be the available memory of the graphics card or graphics processor.

[55] A ROM may be one or more persistent storage devices such as a hard disk drive (HDD), a solid state drive (SSD), flash memory (EEPROM, NAND, etc.), optical storage media (CD- R/RW, DVD-R/RW, BlueRay Disc, MD), etc.

[56] To organize the operation of the components of the computing device 10 and organize the operation of external connected devices, various types of I / O interfaces 104 are used. The choice of appropriate interfaces depends on the specific design of the computing device, which can be, but are not limited to: PCI, AGP, PS / 2 , IrDa, FireWire, LPT, COM, SATA, IDE, Lightning, USB (2.0, 3.0, 3.1, micro, mini, type C), TRS/Audio jack (2.5, 3.5, 6.35), HDMI, DVI, VGA, Display Port, RJ45, RS232, etc.

[57] To ensure user interaction with the computing device 100, various I/O information means 105 are used, for example, a keyboard, a display (monitor), a touch display, a touch pad, a joystick, a mouse, a light pen, a stylus, a touch pad, a trackball , speakers, microphone, augmented reality tools, optical sensors, tablet, indicator lights, projector, camera, biometric identification tools (retinal scanner, fingerprint scanner, voice recognition module), biometric sensors, etc.

[58] The communication means 103 enables data transmission via an internal or external computer network, such as an Intranet, Internet, LAN, and the like. As one or more means 103 can be used, but not limited to: Ethernet card, GSM modem, GPRS modem, LTE modem, 5G modem, satellite communication module, NFC module, Bluetooth and / or BLE module, Wi-Fi module, etc.

[59] In addition, the device 10 may additionally contain satellite navigation tools, such as GPS, GLONASS, BeiDou, Galileo. [60] Returning to FIG. 1A, garment 20 may be any wearable garment by the wearer, such as a suit, waist garment, shoulder garment, overalls, etc. The garment 20 may be made of fabric, for example. The fabric can be selected based on the characteristics of the use of the specified garment 20. For example, in one particular embodiment, at least the following types of fabric can be selected: knitwear, cotton, wool, lycra, acrylic, nylon, polyester, spandex, microfiber, elastane, antibacterial fiber, etc. Some of these types of fabrics may provide a good fit to the surface of the garment against the wearer's body, or be used to make compression garments. For example, garment 20 may be made from polyester to provide compressive properties.

[61] The garment 20 may also include a conductive layer. Said layer is configured to connect elements of the suit, such as a processor, a storage device, a human-machine interaction module, a transceiver module. For example, the garment 20 may be made from a conventional fabric in which the electrodes are embedded. Said electrode may be made of conductive yarn which is placed in the fabric of the garment 20 by weaving, knitting, braiding, embroidery or crochet. Other forms of textile electrodes can be positioned within or on fabric by applying a conductive dye to said fabric. In addition, the garment may include a top layer, which is located on top of the fabric. The top layer contains a chromium compound. In one particular embodiment, the top layer is a textile layer impregnated with a paint containing a chromium compound.

[62] In another particular implementation, the garment 20 may contain stretchable conductive ink. The conductive ink may include, for example, a flexible adhesive layer, a conductive ink layer, and a gradient region between the adhesive and conductive ink layers. The conductive ink may be composed of conductive particles, such as carbon black particles, or one or more of the following: mica, carbon black, graphene, graphite, metallic silver powder, metallic copper powder, or metallic iron powder.

[63] The conductive ink may be printed, pasted or applied in any known manner on the garment 20 to form a pattern or pattern. The conductive ink can be applied to both the outside of the garment and the inside. The conductive ink pattern may be parallel straight lines, zigzag lines, curved lines, wavy lines, and so on. Pattern conductive ink can be used as a sensor, electrode, bus bar. The connection line may combine the conductive ink patterns with the processor of the wearable device 10, the storage medium, the human-machine interaction module, and the transceiver module.

[64] One of ordinary skill in the art will appreciate that garment 20 may comprise any of the conductive layers applied either with stretchable conductive ink, directly conductive fabric, or any other method known in the art.

[65] In yet another embodiment, the garment 20 may further comprise at least one electromagnetic energy emitter, at least one electromagnetic energy receiver, flexible conduits connecting the at least one emitter and receiver. It is also worth noting that the channels can be located on moving parts of the body, such as the user's joints. When the joint moves, said joint stretches and/or bends the channel in which energy flows, thereby changing the parameters of said energy flow. The stream parameters may then be passed to the processor of device 10 for further processing.

[66] In another particular embodiment, the collected data can be transferred to the patient's medical record located, for example, on a remote server for further analysis by a qualified specialist (physician) and decision-making on the results of the collected data. The electromagnetic elements can preferably be used to capture the movement of a user, control the user's posture, control exercise, and so on. Thus, the specified functionality provided by the specified elements described above can be used, for example, to control physiotherapy exercises prescribed by a doctor to the user of the device 10, who performs them in a place remote from the medical organization. The main advantage of using electromagnetic elements to detect the user's movement is the high accuracy of fixing movements, which, as a result, can increase the accuracy of the diagnosis and the effectiveness of prescribed physiotherapy exercises.

[67] For a person skilled in the art, it will be obvious that motion detection can also occur using sensors made with conductive ink and/or sensors sewn into the garment 20. Said motion detection method can be selected depending on the required accuracy. measurements, user activity, diagnosis, etc. [68] In yet another embodiment, the garment 20 may include sensors for monitoring performance. The sensors may be embedded in the garment 20 and connected to the processor 101 of the device 10, for example, via a conductive layer. The sensors can be made using the conductive ink described above. As discussed above, the garment 20 may be a compression garment that provides a snug fit for the sensors to the wearer's body. The sensors may represent at least the following types of sensors: ECG sensor, respiration sensor, PPG sensor, temperature sensor, EMG sensor, accelerometer, gyroscope, electroencephalography sensor, strain gauge, pulse oximeter, humidity sensor, pressure sensor, carbon dioxide sensor, etc. These sensors are configured to collect biometric information from the wearable device user and transfer said information to the processor for further processing. The sensors may communicate with the processor, for example, through patterns of conductive ink applied to the garment 20.

[69] In addition, in addition to biometric sensors, the device 10 may additionally contain temperature control elements. These elements are configured to monitor environmental performance and regulate the internal performance of the garment 20 based on monitoring data. Also, additional environmental indicators can be obtained remotely using a transceiver module. Based on the environment, the device 10 can warn the user about low humidity, low temperature, for example. In yet another embodiment, environmental monitoring may be used in conjunction with the wearer's medical record. Thus, if dry air is contraindicated for the patient, then the processor 10 may notify the user of the need to change the microclimate of both the outer and the inside of the garment 20. In yet another embodiment, the temperature control elements are configured to change the microclimate inside the garment 20 based on external indicators. Thus, for example, the thermostatic element may be, for example, a heating element. When the temperature inside the garment 20 falls, the thermoregulatory element may be activated to normalize the internal temperature of said element 20.

[70] In yet another embodiment, device 10 may further comprise a stimulator located, for example, in the chest region. Said stimulator may be a pacemaker, vibration motor, defibrillator, etc. The specified stimulator can be intended, for example, for tactile interaction with the wearer of the garment 20, for conducting electrical impulse therapy, for normalizing the heart rhythm, etc. Moreover, in yet another embodiment, said stimulant may also be used in the application of user interaction scenarios, described in more detail below.

[71] The human-machine interaction module may consist of a graphical user interface display (display, screen), voice user interface alerts (speakers), microphone array or microphone, touch screen, and so on. It should be noted that the aforementioned module may represent one or more I/O means 105. As noted above, the human-machine interaction module may interact with the processor via a bus, wires, and so on.

[72] The display may be a liquid crystal display (LCD), a touch display, a flexible display, an E-ink display, and the like. The human-machine interaction module is also configured to interact with a user of the wearable device 10. In one embodiment, at least one human-machine interaction module may be located on the garment 20 in an area that corresponds to a part of the user's body. Thus, for example, the displays may be integrated into the garment 20, for example, in the thigh area, etc. not limited.

[73] The human-machine interaction module is also configured to notify the user about the treatment process, the need to perform the planned procedure. In addition, in one particular embodiment, the human-machine interaction module is configured to receive a command to accompany (both audio and visual) user actions from the processor 10 based on the indicators collected by the sensors of the garment 20. So, for example, when the processor receives indicators that exceed the threshold value, the human-machine interaction module is configured to notify the user about the need to rest or take drugs that stabilize the indicators, or perform actions pre-assigned to the user, etc.

[74] The processor 101, as mentioned above, can also be a controller or microcontroller, as well as any other device capable of performing a given, well-defined sequence of computational operations (actions, instructions). The processor 101 may be embedded in the garment 20 and connected to the sensors, the human-machine interaction module described above by, for example, a connecting bus, wires, etc.

[75] The processor 101 is usually configured to receive, process and analyze indicators from sensors, interact with computing devices using the transceiver module 103, control the human-machine interaction module, form a user profile based on the collected data, send notifications and reminders of scheduled procedures and the time of taking medications, sending alarms.

[76] The user profile may represent, for example, biometric indicators (pulse, heart rate, blood oxygen saturation, average daily activity, etc.). These indicators can be obtained both in the process of long-term monitoring and, for example, from the user's electronic medical record. Based on the specified user profile, the processor is configured to record the deviation of at least one indicator from the norm, and assess the degree of deviation and execute user interaction scenarios.

[77] So, for example, with a critical deviation of vital signs, such as heart rate, pressure, etc., from normal indicators for a particular user, a critical scenario can be executed. In such a scenario, the processor is configured to send, via a transceiver module, an alarm signal to the emergency service. The alarm signal may contain at least the following data: user coordinates, critical indicator, associated user indicators. In addition to sending the signal, the processor may also be configured to broadcast first aid instructions to the human-machine interaction module before medical personnel arrive. In a frequent embodiment, instructions may be selected based on a critical metric. In yet another particular implementation, the processor may be configured to activate a stimulator, such as a defibrillator, in cases where a critical scenario is associated with cardiac abnormalities.

[78] A corrective scenario can be used in cases where non-critical user indicators deviate from the norm, for example, when receiving data on a long-term violation of posture, due to incorrect position on a chair, the processor is configured to notify the user and broadcast instructions to normalize indicators.

[79] The term "instructions" as used in this application may refer, in general, to program instructions or program instructions that are written on a given a programming language for performing a specific function, such as, for example, receiving and processing data, generating a user profile, receiving and transmitting signals, analyzing received data, identifying a user, and the like. The instructions may be implemented in a variety of ways, including, for example, object-oriented methods. For example, the instructions may be implemented using the C++ programming language, Java, Python, various libraries (eg “MFC”; Microsoft Foundation Classes), etc. Instructions that carry out the processes described in this solution can be transmitted over both wired and wireless data transmission channels, for example, Wi-Fi, Bluetooth, USB, WLAN, LAN, etc.

[80] In FIG. 2 shows an example of an interaction system between device 10 and computing device 210.

[81] Computing device 210 may be a server of a medical organization, a remote server, etc. Said device 210 may be configured to store data from a plurality of devices 10 and then analyze such data. When the user first visits a medical organization and receives the device 10, the unique identifier of the device 10 is linked to the user's electronic medical record. The electronic health record may be stored on computing device 210. In one embodiment, the association may be via data network 220, such as through two-factor authentication.

[82] In addition, the device 10 is also configured to communicate with the user's personal device 230. The personal device 230 may be, for example, a smartphone, tablet, etc.

[83] After the device 10 has been associated with the user's medical record, the specified device 10 is configured to communicate with the server of the medical organization through the data communication network 220.

[84] In a particular implementation, device 210 is configured to collect data, such as a user profile, from multiple devices 10 for further analysis and grouping by similar metrics. Thus, for example, the device 210 may be configured to form a group of users having a similar diagnosis, as well as physiological characteristics, such as weight, age, build, etc., to analyze and identify the most effective treatment therapies in this group. In addition, such therapies may also be offered to the remaining devices 10 based on the advice of their physician. [85] In another particular embodiment, the processor 101 of the device 10 is configured to authenticate the wearer of the suit against biometrics received from the sensors of the garment 20. For example, the processor 101 may be configured to receive data from the skin conductivity sensors located in item of clothing 20 and comparing the received data with a saved user profile with a given biometric pattern stored, for example, in a telemedicine system on a remote server, or a server of a medical organization. Such a solution can be used for the purpose of strong carrier authentication for access to sensitive and/or personal information, for example, the results of examinations, analyzes, etc. The carrier may also be authenticated by the processor 101 based on pulse readings, skin pattern, heart rate pattern, etc.

[86] If the data received by the sensors of the device 10, when they are subsequently compared with the stored biometric information template, match, then the user of the device 10 is authorized in the required system and gains access to the data. Also, this access method can be used to send sensitive information to a remote server. The processor 101 can also be additionally configured to encrypt all data received and sent to remote computing devices, such as, for example, a server of a medical organization. As encryption algorithms, for example, DES, AES, RSA, etc. can be used. This authentication process can ensure the validity and integrity of the data, as well as ensure their protection.

[87] In yet another common embodiment, in addition to or instead of authentication based on the skin conductivity sensor, authentication can be performed by entering a password on the display, speaking a phrase as both dependent text (saying the control phrase from the screen) and independent text (saying an arbitrary text), for example, a biometric sample of a voice applied to the corresponding sensor with a finger, palm! and/or key carrier.

[88] These authentication methods can be performed, for example, by equipping the device 10 with an appropriate means of obtaining biometric information. For a person skilled in the art, it is obvious that any parameters known from the prior art, collected by existing solutions and sensors that can be obviously used in the claimed solution, can be used as biometric authentication parameters. [89] In yet another embodiment, the device 10 may further comprise a power source connected to the conductive layer and the remaining elements of the device 10 described above. The power source may be either external or built directly into the garment 20. In one particular embodiment, the power source may be solar panels located on at least one garment.

[90] In the following, preferred embodiments of said wearable device 10 will be discussed.

[91] In one preferred embodiment, the implementation of the specified device 10 can be used in the field of telemedicine.

[92] Since there are a number of circumstances that impede the physical session of the user in a medical organization, the use of telemedicine can significantly speed up and correct the process of treating a patient using a remote consultation. As a rule, for such a consultation, the doctor must have a certain set of measured biometric indicators of the user, so the use of the wearable device 10 can increase the efficiency of remote consultations with the attending physician (telemedicine session).

[93] Consider a typical use case for the device 10. The use of the device 10 can be directly prescribed by a physician after reviewing the patient's medical history. However, for a person skilled in the art it is obvious that the device 10 can be used in cases where a diagnosis is required, i.e. at the stage of examination of the patient. It's worth noting that depending on the user's complaints, the wear time of the suit may also vary.

[94] After the user has been assigned to wear the device 10, said device 10 can be synchronized with the patient's electronic health record. Synchronization can occur using a unique identifier of the device 10. Based on the data of the medical card, as well as on the basis of biometric and other indicators obtained from the sensors of the device 10, the specified device is configured to generate a user profile. So, for example, a user profile can take into account the average biometric indicators of the user and take them as a reference. In addition, data from the electronic medical record is also taken into account when calculating the reference indicators for a particular user. In one embodiment, the user profile may further comprise patient contraindications derived from medical record data. [95] In addition, based on the user profile (as discussed above), the device 10 can be configured to activate scripts. So, in case of a critical deviation of vital indicators, such as heart rate, pressure, etc., from the indicators normal for a particular user, a critical scenario can be executed. In such a scenario, the processor is configured to send, via a transceiver module, an alarm signal to the emergency service. The alarm signal may contain at least the following data: user coordinates, critical indicator, associated user indicators. In addition to sending the signal, the processor may also be configured to broadcast instructions to the human-machine interaction module to provide first aid to the surrounding people prior to the arrival of the medics. In a frequent embodiment, instructions may be selected based on a critical metric.

[96] A corrective scenario can be used in cases where non-critical user indicators deviate from the norm, for example, when receiving data on a long-term violation of posture, due to incorrect position on a chair, the processor is configured to notify the user and broadcast instructions to normalize indicators.

[97] In addition, in addition to monitoring the biometrics, the device 10 is configured to transmit the prescriptions contained in the electronic health record, for example, at a predetermined time interval or on a schedule. Thus, for example, if a patient using the device 10 suffers from memory problems, the device 10 is configured to alert the user to take medications and/or undergo certain procedures. The alert can be visual, acoustic or tactile. The notification is performed by appropriate means 105, such as a display, speaker, vibration motors, and the like. In this case, a visual alert may be displayed on a body part for which a procedure and/or medication is required, which may be displayed directly on the display or multiple displays located on the device 10, or on the user's device, for example, a smartphone associated with the device.

[98] In yet another particular embodiment, the visualization of device 10 data can occur, for example, using augmented reality technology (augmented reality or AR). Thus, when pointing the camera of a computing device 230, such as a smartphone or tablet, at the device 10, the user profile, electronic medical record and other necessary data of the carrier can be displayed. suit. When the user of the device 10 undergoes examinations in a medical organization, the corresponding information can be displayed on the corresponding part of the user's body when the device 230 is pointed at the device 10 and synchronized with the processor 101. In this case, this information can only be provided to trusted devices in order to respect the privacy of the wearer of the garment 20.

[99] In another example, displaying the information and media of the device 20 using the device 230 (or other computing device associated with the device 10) can be performed using a three-dimensional anatomical atlas (for example, https://anatomy3datlas.com/), displaying the resulting information during the passage of a medical examination on the corresponding part of the three-dimensional model. The displayed information can correspond to a given nosology when receiving information about the examination and be used for further diagnosing the corresponding diagnosis with the issuance of recommendations for its treatment and/or prevention.

[100] In addition, in another embodiment, when the critical scenario of the device 10 is activated, using augmented reality technology, a sequence of first aid actions can be displayed and / or an instruction is displayed indicating the points on the body of the wearer of the device 10 with which it is necessary to contact during first aid.

[101] In another embodiment, the device 10 is configured to monitor the performance of physical therapy exercises. So, if the user performs certain exercises incorrectly, the device 10 can notify the user about an error in the execution technique, and also additionally display, using the human-machine interaction module, the correct example of execution. Physical therapy and other types of exercise can be controlled by controlling muscle contraction and joint mobility. This is achieved using the means described above, for example, using electromagnetic elements, sensors, etc.

[102] In another embodiment, the device 10 is configured to improve the emotional background of the patient. So, if a patient has been diagnosed with mental disorders, then the device 10, based on the recommendations stored in the electronic medical record, can reproduce soothing sounds, as well as regulate the temperature inside the suit using thermostatic elements. In addition, the device 10 is configured to activate the vibration motor to relax the physical tension of the user. The activation of the vibration motor can also take place in accordance with the prescriptions of the doctor at a certain predetermined time. In another embodiment, activation may occur based on measured performance. Also, the device 10 can additionally output inspiring texts or phrases that positively affect the emotional background of the wearer of the device 10, depending on the situation. Thus, for example, when exercising, the device 10 can detect a slowdown in the pace of exercise and begin to play phrases that encourage the user to return to a normal rhythm. The pace of exercise can also be measured using the sensors described above.

[103] Returning to the considered use case, the data measured by the device 10 is transmitted in real time to the doctor or to the server of the medical organization. Based on the received data, the doctor can adjust the treatment prescriptions, as well as more accurately assess the user's condition. In addition, the informative interaction of the device 10 with the user ensures high efficiency of remote treatment and minimizes the possibility of an inaccurate treatment process.

[104] In FIG. Figure 3 shows an example of implementing a solution based on the formed similar groups of device users 10. Organization of device 10 users into groups can be carried out, for example, according to a set of therapeutic physical exercises (exercise exercise therapy), according to medical prescriptions, psychological training, etc. The user of the device 10 may be asked to complete such exercises in groups with other users from the specified group.

[105] These group sessions can be conducted in virtual reality (VR) or through standard telemedicine tools, in particular, an information display device, such as a TV, computer, tablet, smartphone, and the like. Each of the users can be registered in a specialized system for providing medical services implemented using the server 210, where his profile is subsequently formed or stored, containing identification data, as well as information necessary to search for similar people based on certain medical prescriptions. The information collected by the device 10 may be automatically transmitted to the server 210 in order to update the data and match the appropriate users.

[106] Interaction with VR can be performed, for example, using glasses or a virtual reality helmet, widely known in the art, as well as using controls used for VR. In addition, suit sensors can provide an accurate display of the movements of the user of the device 10 in VR. Group sessions can improve exercise efficiency as well as enable users to communicate with each other for information on medical prescriptions and treatments that may be similar and allow users to compare drugs and/or procedures that are effective for a given diagnosis.

[107] In another particular embodiment, based on the similar groups formed, users can be provided with a group chat in which these users can discuss the treatment process, as well as share their own experiences. In addition, users can request and access information about the healthcare professionals who maintain each user's records.

[108] For a person skilled in the art, it is obvious that in addition to the described methods for using VR as group therapies, VR technologies can also be used for user communication, for example, in the form of a group session with a psychologist, etc.

[109] The submitted application materials disclose preferred examples of the implementation of the technical solution and should not be interpreted as limiting other, particular examples of its implementation that do not go beyond the scope of the requested legal protection, which are obvious to specialists in the relevant field of technology.

[ON] Modifications and improvements to the above-described embodiments of the present technical solution will be apparent to those skilled in the art. The previous description is presented only as an example and does not carry any restrictions for the implementation of other particular embodiments of the claimed technical solution that does not go beyond the requested scope of legal protection.

[111] Structural elements such as microcontrollers, blocks, modules, etc., described above and used in this technical solution, can be implemented using electronic components used to create digital integrated circuits.

Claims

FORMULA A wearable device for storing information about the user, containing:

• at least one piece of clothing made of fabric;

• at least one human-machine interaction module located on at least one piece of clothing, configured to interact with the user of the wearable device;

• at least one processor configured to interact with the human-machine interaction module;

• at least one information storage means associated with the human-machine interaction module;

• receiving-transmitting module. The device according to claim 1, characterized in that at least one garment is a compression garment. The device according to claim 1, characterized in that at least one garment may be at least the following items: a suit, a waist garment, a shoulder garment, a jumpsuit. The device according to claim 1, characterized in that at least one garment further comprises a conductive layer. The device according to claim 4, characterized in that the conductive layer is a stretchable conductive ink. The device according to claim 1, characterized in that at least one garment further comprises at least: one electromagnetic emitter, one electromagnetic receiver and one electromagnetic conductive path. The device according to claim 6, characterized in that at least one electromagnetic conductive path is located on the garment in the area of the wearer's joints. The device according to claim 1, characterized in that at least one garment further comprises at least one sensor configured to monitor indicators. The device according to claim 8, characterized in that at least one sensor represents at least one sensor selected from the group: accelerometer, gyroscope, electrocardiogram (ECG) sensor, electroencephalography (EEG) sensor, electromyography (EMG) sensor, strain gauge, temperature sensor, pulse oximeter, respiration sensor, humidity sensor, pressure sensor, carbon dioxide sensor, or combinations thereof.

10. The device according to claim 1, characterized in that the human-machine interaction module contains at least one of: a display, a speaker, a microphone, or combinations thereof.

I. The device according to claim 1, characterized in that the display is at least one display selected from the group: touch display, LCD display, flexible display, E-ink display, or combinations thereof.

12. The device according to claim 1, characterized in that at least one display is located on the garment in a region corresponding to a part of the wearer's body.

13. The device according to claim 1, characterized in that the processor is configured to notify the user, using the human-machine interaction module, of the scheduled procedures.

14. The device according to claim 8, characterized in that the processor is further configured to generate a user profile based on data received from at least one sensor.

15. The device according to claim 1, characterized in that the processor is configured to transmit an alarm signal to the computing device upon receipt of critical indicators from at least one sensor.

16. The device according to claim 1, characterized in that at least one garment contains a unique identifier.

17. The device according to claim 15, characterized in that the unique identifier is associated with at least the user's electronic medical record.

18. The device according to claim 16, characterized in that the electronic medical record is synchronized with the wearable device in terms of transmitting data on medical prescriptions.

19. The device according to claim 1, characterized in that at least one article of clothing additionally contains a stimulant. 0. The device according to claim 1, characterized in that at least one piece of clothing additionally contains temperature control elements. 1. The device according to claim 1, characterized in that at least one garment additionally contains LED elements. The device according to claim 1, characterized in that the transceiver module is at least one of: NFC module, Bluetooth, BLE, Wi-Fi module, GSM module, LTE module. The device according to claim 1, characterized in that it additionally contains a GPS module. The device according to claim 1, characterized in that it further comprises an external power source. The device according to claim 1, characterized in that the external power source is a solar array located on at least one piece of clothing. The device according to claim 17, characterized in that, when synchronized with a medical record, the information is displayed on the display of the wearable device. The device according to claim 25, characterized in that an alert is additionally generated in the form of a sound signal, a vibration signal, or a digital message. The device according to claim 26, characterized in that the digital message is transmitted to at least one computing device.