RU2751146C1 - Apparatus for monitoring and alerting of condition of user - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: invention relates to information technology, namely to apparatuses for monitoring the physiological indicators of the condition of the body of a user with alert issuing functions. The apparatus for monitoring and alerting about the condition of the user is comprised of a group of sensors of physiological characteristics; a group of position detection sensors; a data processing unit based on a processor module with a memory, including a first module for processing data from the sensors of physiological characteristics with inputs connected with the outputs of a group of sensors of physiological characteristics and with an output connected with the input of the estimation circuit for signals from the sensors of physiological characteristics of the alarm level estimation and alarm signal generation module, a first module for processing the position detection sensors data with inputs connected with the outputs of the group of position detection sensors and with an output connected with the input of the estimation circuit for signals from the position detecting sensors of the alarm level evaluation and alarm signal generation module.

EFFECT: technical result is aimed at increasing the accuracy of classification of the alarm signals issued by the apparatus as urgent or non-urgent in the process of generation thereof.

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Description

The invention relates to the field of technical means of monitoring, control and notification about the behavior and state of the user, namely to devices for monitoring the physiological indicators of the state of the user's body with the functions of issuing notifications (alarms), reflecting the presence of changes in the state of the user and characterized as urgent or not urgent from the point in view of the necessity (desirability) of taking any action in relation to the user upon detection of changes in the user's state. The invention can be used in solving the problems of prevention and reduction of industrial injuries and occupational morbidity of workers in manufacturing enterprises, in particular, in the process of monitoring and controlling the state of workers in manufacturing enterprises in real time while performing their professional duties.

Known mobile (wearable) device designed to identify the fact of the fall of the user, described in the application US 2019/0099114 No. 1 IPC A61B5 / 11, A61B5 / 00, A61B5 / 0205, A51B5 / 024, A61B5 / 053, publ. 04/04/2019, containing a housing, a processor, a group of sensors designed to assess the physiological state of the user and functionally connected with the processor, a motion sensor, a wireless communication module and random access memory associated with the processor and containing, among other things, a set of commands (instructions) executed by the processor. During the operation of the device, the data received from the motion sensor is constantly analyzed to detect a decrease in the value of the acceleration modulus in the projection on the direction of free fall in comparison with the value of the modulus of acceleration of gravity in the projection on the direction of free fall to a value not lower than the specified first threshold value of the modulus acceleration, if the value of the gravitational acceleration modulus in the projection to the direction of gravity is lower than the specified first threshold value, a timer is initiated, after which the data received from the motion sensor is analyzed for a change in the value of the acceleration modulus in the projection to the direction of free fall. above the predetermined second threshold value of the acceleration modulus during the first period of time (corresponds to the fall state of the user), and the data received from the motion sensor is analyzed for a change in the value of the acceleration modulus in the projection to the direction free fall is not higher than the predetermined third threshold value of the acceleration module during the second time period (corresponds to the user's ascent state), after which, if the value of the acceleration module during the first time period exceeds the predetermined second threshold value of the acceleration module, and the value of the acceleration module during the second time period does not exceed the predetermined third threshold value of the acceleration module, the wireless module is initiated, and, through it, the alarm notification. Since the threshold values of the acceleration module and time periods, as a rule, cannot always take into account the peculiarities associated with the specific place of attachment of the mobile device on the surface of the user's body and the behavior of a particular user, the time required to identify the fact of the user's fall and issue an alarm signal, can be very long. In addition, this device cannot be used to identify the user's state and control the physiological parameters of the user's state in cases where changes in the physiological parameters of the state are not accompanied by the user's fall.

A known system is made on the basis of a wearable device and is designed to identify the fact of the fall of the user, described in US patent 10198928 B1 IPC G08B21 / 04, A61B5 / 11, publ. 02/05/2019, containing a primary data processing filter with a first buffer register, a second buffer register, a low-pass filter, a feature extraction unit and a threshold sensor, an accelerometer and a transmitter intended for communication with a wearable device. In the filter of primary data processing, according to commands from the data processing device, the following is carried out: receiving initial data from the accelerometer; synchronization of the initial data obtained from the accelerometer (data synchronization implies, among other things, the display of the initial data on a fixed set of sets); obtaining a base dataset from a fixed set of sets in such a way that the base dataset would be used for pre-filtering; calculating the first value of the quantity taking into account the data from the base data set; passing the first magnitude value to a low-pass filter to generate a second magnitude value; calculating a jerk value with respect to a second magnitude value and a third magnitude value, the third magnitude value being the magnitude value supplied to the first buffer element; passing the jerk value to the second buffer element; adding the second value of the quantity to the first buffer element; transmitting the jerk value to the threshold sensitive element in accordance with the state of the feature extraction unit; transmitting the second value of the magnitude to the transmitter for communication with the wearable device in response to the threshold sensor identifying the jerk value corresponding to the sensitivity threshold of the element, wherein the threshold value is less than the pre-calculated value. Despite the fact that the jerk data is a significant addition to the acceleration data in terms of identifying the fact of a user fall and reducing the time required to identify this fact, in this device the time required to identify the fact of a user fall and issue an alarm signal can be long enough to make it impossible to use this device in real time. This device also cannot be used to identify the user's state and control the physiological parameters of the user's state in cases where changes in the physiological parameters of the state are not accompanied by the user's fall.

A known system for identifying motion artifacts, described in the patent for invention RU 2640006 C2, IPC A61B5 / 00, publ. December 25, 2017, bul. # 36, comprising: a sensor configured to measure a physiological parameter of a user and configured to generate one or more physiological signals indicative of a detected physiological parameter; accelerometer; the first block for processing physiological signals from the sensor for measuring the physiological parameter; a second processing unit for acceleration signals from the accelerometer for determining motion characteristics, the processing in the second signal processing unit being performed in parallel and independently of the processing in the first signal processing unit; a block for marking measurements of a physiological parameter with the corresponding temporal characteristics of the movement, based on certain characteristics of the movement. However, in the measurement marking unit, the output data sequence of which is coding (control) for the rejection unit that generates a control signal for the alarm system control unit that generates an alarm signal, there is no marking based on certain characteristics of physiological signals, which makes it possible to use this system only for identification of motion artifacts of a specific type (mainly falling), and only under the condition of reliability and sufficiency of the data obtained as a result of measurements of the user's physiological parameters (mainly photoplethysmographic measurements in combination with pulse oximetry are meant).

Known fall detection system, described in patent EP 2147421 B1, IPC G08B21 / 04, A61B5 / 11, comprising: a sensor module designed to be worn by a user in order to collect data on the movement of his body, such as acceleration data; a first evaluation logic module for detecting a potential drop based on the impact observed in the plurality of measured and calculated acceleration data; a second evaluation logic module for verifying the fact that the sensor module is actually being used by the user during an event identified as a shock, in order to prevent an alarm from being triggered in the event that only the sensor module falls. The second evaluation logic may comprise free fall detection means for evaluating the acceleration data from characteristics that are typical of a free fall object, such as the time of one or more complete rotations during which the magnitude of the acceleration value is relatively stable and small. Despite the fact that this system is characterized by increased resistance to false alarms, it cannot be used to identify the user's state and control the physiological parameters of the user's state in cases where changes in the physiological parameters of the state are not accompanied by the user's fall. Also, this system does not guarantee the absence or minimization of the number of false alarms in cases when they are caused by reasons other than the fall of the sensor.

A known system for monitoring the status of a patient (device), described in the application US 2019/110764 A1 IPC A61B5 / 00, A61B5 / 205, A61B5 / 145, G08B21 / 04, A61B5 / 024, G08B21 / 02, publ. 04/18/2019 and containing a group of terminal devices, including the first terminal device and the second terminal device, as well as a controller with the functions of: receiving data characterizing indicators of the patient's condition; comparing the received data with predetermined and entered into the system threshold values of one or more indicators of the patient's condition; activating a first level alarm by the first terminal device if the first alarm criterion is met; activation of the second level alarm by the second terminal device in case of the fulfillment of the second alarm criterion, different from the first alarm criterion. In this case, the first or second terminal device is capable of displaying the patient's status, as well as the state of the first-level alarm and the second-level alarm, the status includes the username, the reason for the activation of the first-level alarm or the second-level alarm, and information about the person who cares a patient to respond to a Level 1 alarm or Level 2 alarm. For each indicator of the patient's state, a range of the precautionary level (first-level alarm) and a range of the alarm level (second-level alarm) are defined relative to the value of the indicator of the patient’s state. When the value of the received patient status indicator falls within the range of precautionary levels, a notification and information about the patient's status is sent to the destination address of the first notification, and if the value of the received patient status indicator falls within the range of the warning level, a notification and information about the patient is sent. patient status to the destination of the second notification, by switching notification destinations based on the patient status information, you can ensure that notification is responded appropriately and action is taken quickly. Such a system is characterized by limited functionality, has a very narrow area of practical application (use in hospital-type institutions for monitoring the health of patients, mainly bedridden patients) and requires specially trained personnel on constant duty. In addition, the system does not provide for the presence of sensors capable of registering the characteristics of the patient's movement (movement, linear acceleration, etc.), for example, in the event of a sudden fall, and transferring the values of the recorded movement characteristics to the controller.

A known system for generating alarms from the patient's side using a multistage alarm generation circuit described in patent EP 2696746 B1 IPC A61B5 / 1455, G08B21 / 02, A61B5 / 00, G08B21 / 04, G06F19 / 00, publ. 06/14/2017 bul. No. 2017/24 and containing a group of one or more processors designed to obtain information about the indicators of the physiological state of the patient and / or their values; comparing the values of indicators of the physiological state of the patient and / or their estimates with a group of values of the levels of anxiety; issuing an alarm signal in the event that the received or estimated value of a separate indicator of the patient's physiological state falls within the range corresponding to the non-prohibited alarm levels; establishing the first prohibition period for non-prohibited alarm levels after the alarm is issued, while the prohibition period is the set period of the set value, within which, until its end, the prohibition on initiating an alarm at certain levels is in effect; re-issuing an alarm on condition that one or more conditions from the group of re-enabling conditions are met, including the first re-connection condition, which consists in meeting the requirements for the expiration of a given period of time, the absence of events in a given period of time, the difference in a particular individual physiological indicator and / or its value differs by a predetermined amount in comparison with a previously determined physiological indicator and / or its value for the worse and includes a second reconnection condition, which consists in fulfilling the requirements for the expiration of a predetermined period of time, the presence of an event in a predetermined period of time, and the fulfillment of the repeat condition and fulfilling the requirement for the physiological parameter and / or its use value in calculating the vital signs index value calculated based on the physiological parameter values using the predictive model of the physiological state stability. The use of this system in practice is based on the assumption that any alarm after the first alarm is likely to be based on similar physiological data and, thus, does not provide any additional information to the clinician who, by that time, either already plans to receive measures for the patient's treatment, if he agrees with the alarm or doubts the reliability of the alarm and allows to eliminate such a disadvantage as the absence of additional alarms in the event that the patient's condition worsens during the period of suppression of the alarm during the restarting phase, as well as to adapt to the dynamics of a specific a person in time is and use corrected predictive models based on information about the healthy or initial physiological dynamics of a particular patient. Such a system is also characterized by limited functionality, has a very narrow field of practical application and requires specially trained personnel on constant duty.

Known patient monitoring system described in US patent 10311696 B2, IPC G08B21 / 04, publ. 06/04/2019, containing a group of sensors designed to read data of physiological parameters from a patient, a processor, a device for determining the location of personnel (doctor), an event analysis unit based on a processor with the ability to: receive information about a first-level alarm event; obtaining information about a second-level alarm event; determining the fact whether the second-level alarm event is included in the group of events including the first-level alarm event; obtaining information about one or more subsequent alarm events, provided that an alarm event of the first level (alarm event of the second level) occurs immediately or within a specified time interval after the end of an alarm event of the second level (alarm event of the first level), respectively; determining, for each identified subsequent alarm event, whether the corresponding subsequent alarm event is part of a group of events including a first level alarm event; determining the location of the personnel (doctor) and determining the moment of completion of the group of events based on the information about the location of the personnel (doctor) and generating the event group indicator identifying the group of events. The functioning of such a system can be relatively effective only if the second-level alarming events are exclusively signals of malfunctioning of technical means that collect data from the patient (signaling of irregularities in the operation of stationary or mobile devices associated with the patient), and only in if the patient is practically immobilized.

A device for monitoring physiological parameters with an alarm control function is known, as described in US patent 9398884 B2 IPC G08B23 / 00, A61B5 / 00, A61B5 / 1465, publ. 07/26/2016 containing an alarm controller configured to change the nature of the issued alarm from a first level alarm according to the first priority to a second level alarm according to the second priority, and if the requirement of the first priority is satisfied, the first alarm is output level, but if the second priority condition is satisfied, then the second level alarm is output instead of the first level alarm according to the second priority condition. This device has an extremely limited scope of application, mainly in pulse oximetry and only for the case when the first level alarms represent information about the exceeding of the measured physiological indicator values, and the second level alarms represent information about the violation of the reference values of the physiological indicator or a malfunction. devices.

The closest in technical essence is the device for identifying the user's state, described in the patent for invention RU 2629795 C2 IPC G08B21 / 04, A61B5 / 11 and containing a group of physiological characteristics sensors, a group of position detection sensors, a data processing unit based on a processor module with memory, the first a physiological data processing module associated with a group of physiological characteristics sensors, a first position detection sensor data processing module associated with a group of position detection sensors, an alarm level estimation and alarm generation module with the ability to generate an alarm as an urgent alarm or a non-urgent alarm, a transceiver unit and a unit for issuing alarms. In the process of device operation, if the fact of a change in the user's state (falling) is identified, the parameters (values) of the user's physiological characteristics are determined, and, if one or more physiological characteristics have a value that goes beyond a certain range of values, an urgent signal is automatically issued. anxiety. The urgent alarm is issued until the expiration of the cancellation period or as long as at least one of the physiological characteristics has a value outside the specified range of values. In the case when the values of one or several physiological characteristics do not go beyond the specified intervals or, over time, cease to go beyond the specified intervals, a non-urgent alarm is initiated and issued. Despite the fact that this device allows you to detect the fall of the user and identify the alarm as urgent or non-urgent in the presence or absence of deviation of the value of at least one physiological characteristic from the norm, the use of this device in the case when the change in position of the user is not accompanied by a simultaneous fall or deviation from the norm in the value of one or more physiological characteristics is not accompanied by a simultaneous fall, and leads to incorrect identification of alarms as urgent or non-urgent.

The technical result is to increase the reliability of classifying the alarms issued by the device as urgent or non-urgent in the process of their formation in the case of identifying changes in the user's state during the operation of the device. The technical result is achieved due to the fact that in the device for monitoring and alerting about the state of the user, containing a group of sensors of physiological characteristics; a group of position detection sensors; a data processing unit based on a processor module with memory, including a first module for processing data from physiological characteristics sensors with inputs associated with the outputs of a group of physiological characteristics sensors and with an output associated with the input of the circuit for evaluating signals from physiological characteristics sensors of the module for evaluating the alarm level and generating an alarm signal, a first module for processing position detection sensors data with inputs associated with the outputs of a group of position detection sensors and with an output associated with an input of a circuit for evaluating signals of position detecting sensors of the module for evaluating an alarm level and generating an alarm signal; a submodule for generating an alarm of the module for evaluating the alarm level and generating an alarm signal; an alarm signal generating unit with inputs connected to the outputs of the submodule for generating an alarm of the module for evaluating the alarm level and generating an alarm signal; transceiver unit; into the data processing unit based on the processor module with memory: the second module for processing data from physiological characteristics sensors with inputs connected to the outputs of a group of physiological characteristics sensors, with an output connected to the input of the circuit for evaluating signals from physiological characteristics sensors of the module for evaluating the alarm level and generating an alarm and with additional inputs connected to the outputs of the circuit for evaluating the signals of the sensors of the physiological characteristics of the module for evaluating the alarm level and generating an alarm signal and outputs of the circuit for evaluating the signals of the sensors for determining the position of the module for evaluating the alarm level and generating an alarm signal; the second module for processing position detection sensors data with inputs associated with the outputs of a group of position detection sensors, with an output associated with the input of the signal estimation circuit for detecting the position of the alarm level estimation module and generating an alarm signal, and with additional inputs associated with the outputs of the signal estimation circuit sensors of physiological characteristics of the module for evaluating the alarm level and generating an alarm signal and outputs of the circuit for evaluating signals from the sensors for determining the position of the module for evaluating the alarm level and generating an alarm signal; a module for checking and monitoring the functioning of sensors, connected through inputs-outputs with inputs-outputs of a group of physiological characteristics sensors and a group of position detection sensors and connected through inputs-outputs with inputs-outputs of a circuit for evaluating signals of physiological characteristics of a module for evaluating an alarm level and generating an alarm; and circuits for evaluating sensor signals for determining the position of the module for evaluating the alarm level and generating an alarm signal; in the module for assessing the alarm level and generating an alarm signal, a circuit for adjusting the assessment parameters was introduced with outputs associated with the inputs of the circuit for assessing signals of physiological characteristics of the module for assessing the alarm level and generating an alarm signal and inputs of the circuit for assessing sensor signals for determining the position of the module for assessing the alarm level and generating an alarm signal , and the circuit for evaluating the signals of the sensors of the physiological characteristics of the module for evaluating the alarm level and generating an alarm signal and the circuit for evaluating the signals of the sensors for determining the position of the module for evaluating the alarm level and generating an alarm signal have outputs associated with the inputs of the circuit for generating non-urgent alarm signals of the submodule for generating alarms of the module for evaluating the alarm level and the generation of an alarm signal and the inputs of the circuit for generating urgent alarm signals of the submodule for generating alarms of the module for evaluating the alarm level and generating an alarm signal, while the circuit for generating signals is not An urgent alarm of the submodule for generating alarms of the module for assessing the alarm level and generating an alarm signal has an output connected to the input of the circuit for generating urgent alarms of the submodule for generating alarms of the module for assessing the alarm level and generating an alarm signal.

The invention is illustrated by the figures:

Fig. 1 - A block diagram of the device in the basic version;

FIG. 2 - An image of the block diagram of the device in the version with additional sensors;

FIG. 3 - An image of a block diagram of the operation algorithm of the device in the basic version;

FIG. 4 - An image of a block diagram of the operation algorithm of the device in the version with additional sensors;

The following designations have been introduced:

BVST - block for issuing an alarm signal;

BODPMP - data processing unit based on a processor module with memory;

GrDopD - a group of additional sensors;

ГрДП - a group of position detection sensors;

ГрДФХ - a group of physiological characteristics sensors;

МODDP1 - the first module for processing position sensor data;

МODDP2 - second module for processing position sensor data;

MODOP - module for processing data of additional sensors;

МДФХ1 - the first module for processing data of physiological characteristics;

МДФХ2 - the second module for processing data of physiological characteristics;

MOFST - module for assessing the alarm level and generating an alarm signal;

MPKFD - module for checking and monitoring the functioning of sensors;

PMFST - submodule for generating alarm signals;

SKPO - scheme for correcting evaluation parameters

SODD - scheme for evaluating additional sensor signals;

SODP — scheme for evaluating signals from position detection sensors;

SOFH - scheme for evaluating signals from sensors of physiological characteristics;

SFNST - scheme for generating a non-urgent alarm signal;

SFSST - urgent alarm signal generation circuit;

In general, the device for monitoring and notifying the user's state is shown in Fig. 1 (a block diagram of the device in the basic version is shown).

The group of sensors of physiological characteristics of GrDPC consists of one or more sensors designed to register signals of physiological characteristics from the surface of the user's body (in particular, these can be sensors of photoplethysmographic signals, as well as sensors of electrocardiographic signals, body surface temperature sensors or blood pressure sensors) and conversion their shape, which is convenient for subsequent transmission via a wired or wireless data transmission channel to a data processing unit based on a processor module with a BODPMP memory. The group of sensors for detecting the position of the GDR consists of one or more sensors designed to register signals characterizing the change in the position of the user's body or individual parts of the user's body (for example, these can be sensors based on triaxial accelerometers) and transforming their shape, convenient for subsequent transmission via wired or a wireless data transmission channel in the BODPMP. The nomenclature of sensors (number, types, etc.) as part of the GRDFH and GRDP is formed by the developer of the device based on the intended specific field of application and the methods used in it for determining the state of the user and his control, either independently or taking into account the recommendations of the persons responsible for the activities monitoring and controlling the state of the user in the implementation of professional activities by the user of the device and / or monitoring the state of the user in the exercise of his professional activities.

The data processing unit based on the processor module with the BODPMP memory is the main part of the device, in which signals are received from the sensors included in the GRDFH and GRDP, their subsequent processing, the analysis of the obtained processing results for compliance with the specified criteria for detecting a change in the user's state (signal generation criteria alarms), generating alarm signals and classifying them as urgent or non-urgent in accordance with the specified criteria, transmitting the generated alarm signal to the BVST alarm signaling unit. The processor module as part of the BODPMP (not shown in Fig. 1), on the basis of which the BODPMP is possible, can be performed both in a single-processor version (based on a single-core processor or a multi-core processor in a single-chip version), and in a multiprocessor (distributed) version with shared cache memory (not shown in Fig. 1) under the control of one program or operating system.

Physically, cache memory can be implemented in both lumped and distributed versions. The BODPMP also includes a software module (not shown in Fig. 1) containing fully or partially embedded software designed to generate commands that control the operation of individual modules and circuits of the BODPMP and the device as a whole. A set of software codes can be written in both machine-level and high-level languages, while the software can be able to remotely or directly (from physical media) update individual executable fragments.

Modules for processing data from sensors of physiological characteristics MODFKh1, MODFKh2 are intended for primary processing of signals from sensors included in the GRDFKh (amplification of input signals, filtering noise, analog-to-digital conversion), subsequent processing of digitized data in order to isolate diagnostically significant indicators and the subsequent issuance of data characterizing diagnostically significant indicators, into the module for assessing the alarm level and generating an alarm signal MOFST. Modules for processing data from position sensors MODDP1, MODDP2 are intended for primary processing of signals from position sensors included in the GDRP (amplification of input signals, filtering noise, analog-to-digital conversion), subsequent processing of digitized data resulting from primary processing, in order to highlight significant indicators, characterizing the change in the position of the user, and the subsequent issuance of data characterizing significant indicators to the module for assessing the alarm level and generating the MOFST alarm signal. Modules for processing data from position sensors MODDP1, MODDP2 and modules for processing data from physiological characteristics sensors MODFKh1, MODFKh2 can be implemented both on the basis of a processor or a group of processors of the BODPMP processor module, and on the basis of one or several special processors for digital signal processing, focused on solving processing problems signals from a specific type of sensors.

The module for assessing the alarm level and generating an alarm signal MOFST is a part of a data processing unit based on a processor module with a memory of the BODPMP and is designed to process data characterizing significant indicators and transmitted to the MOFST from the with the specified criteria for generating alarms, classifying the generated alarm in the process of formation as urgent or non-urgent in accordance with the specified criteria for generating alarms and classifying the finally generated alarm as urgent or non-urgent in accordance with the specified criteria for generating alarms, correcting the generated signal alarms during the operation of the device and the issuance of the generated alarm signal to the unit for issuing alarms BVST.

The scheme for evaluating the signals of the sensors of the physiological characteristics of SOPC is intended for the analysis of data received by the MOFST from MDFKh1 and MDFKh2, characterizing diagnostically significant indicators, in order to identify changes in the user's state by physiological indicators in the process of carrying out activities, and, if any, to transfer the analyzed data characterizing diagnostically significant indicators and / or transferring the results of the analysis of these data to the submodule for generating alarms PMFST, which is part of the MFST. The scheme for evaluating the signals from the sensors for determining the position of the DDS is designed to analyze the data received by the MFST from the MODDP1 and MODDP2, characterizing significant indicators, in order to identify changes in the user's state in terms of indicators characterizing the movement and changes in the user's position in the course of the activity, and, if such , for transferring the analyzed data characterizing significant indicators and / or transferring the analysis results of these data to the PMFST submodule for generating alarms, which is part of the MFST. The scheme for correcting the parameters of the assessment of the SQME is designed to provide data that allow changing the nature of functional dependencies that implement the specified criteria for generating alarms. The SOFH, SODP and SKPO schemes can be implemented both on the basis of a processor or a group of processors of the BODPMP processor module, and on the basis of one or several specialized microcircuits.

The submodule for generating alarms PMFST is a part of the module for assessing the alarm level and generating an alarm signal MOFST and is designed to generate an alarm based on the results of analyzing data characterizing significant indicators received from the modules alarm in the process of formation and assignment of the finally generated alarm to the category of urgent or non-urgent in accordance with the specified criteria for generating alarms, issuing the finally generated alarm to the unit for issuing alarms BVST. It includes a circuit for generating an SFSST non-urgent alarm signal and a circuit for generating an SFSST urgent alarm signal. In the scheme for generating a non-urgent alarm signal SFNST, an alarm signal is generated, assigned in accordance with the specified criteria for generating alarms to the category of non-urgent alarm signals, the final generated non-urgent alarm signal intended for issuing to the BVST is generated in accordance with the specified criteria for generating alarms and issuing the finally generated non-urgent alarm signal to the unit for issuing alarm signals BVST. In the scheme for generating an urgent alarm SFSST, the final generation of an alarm is carried out, classified in accordance with the specified criteria for generating alarms to the category of urgent alarm signals, and the final generated urgent alarm signal is issued to the BVST alarm generating unit. The SFNST and SFSST schemes can be implemented both on the basis of a processor or a group of processors of the BODPMP processor module, and on the basis of one or several specialized microcircuits.

The module for checking and monitoring the functioning of the MPKFD sensors functions as part of the data processing unit based on the processor module with the BODPMP memory and is designed to calibrate and test the sensors from the groups of sensors GRDFH and GRDP for disruption of their functioning and testing the hardware (hardware and software) BODPMP for the physiological reliability of the received data and the values of the received data falling within the limits of permissible threshold values or within the specified limits during the operation of the device. MPKFD can be implemented both on the basis of a processor or a group of processors of the BODPMP processor module, and on the basis of a specialized microcircuit.

The block for issuing alarms BVST is designed to issue a finally generated signal of urgent or non-urgent alarm in a form, the implementation of which is permissible by the hardware of the BVST. The nature and form of presentation of the issued alarm signals (sound or light-music signal, message via a wireless channel, etc.), as well as the design features of the BVST are determined based on the intended specific field of application and the methods used in it for determining the state of the user and his control.

The device as a whole can be implemented in a compact version based on a portable individual use product, which is a mobile electronic device based on microprocessors (a communicator, a smartphone, a wrist bracelet or any other gadget). the sensors included in the product can be used, the functionality of which makes it possible to determine the change in the user's position (for example, sensors based on accelerometers or gyroscopes); built-in or additional microprocessor as part of the product, and the unit for issuing alarms BVST can be made on the basis of standard mobile devices. The device can also be implemented in other versions, for example, on the basis of a laptop, personal computer or similar stationary or portable product, while both as sensors from the group of sensors for determining the position of the GRD and as sensors from the group of sensors of physiological characteristics of the GRDFH can be used as fixed sensors on the user or on the user's clothes with the ability to transmit data via a wireless channel, and fixed at a distance from the user (for example, on walls or doors when working in a production room) with the ability to transmit data via a wireless channel or a wired channel, while the data processing unit based on a processor module with memory, the BODPMP can be implemented on the basis of a built-in or additional microprocessor in a product (laptop, personal computer, etc.), on the basis of which the device is implemented, the memory can be represented by a group of memory elements, and an alarm signaling unit and BVST can be made both in a compact and distributed version with the possibility of wireless data transmission between the elements.

The device for monitoring and notifying the state of the user can be made in the version with additional sensors (see the block diagram of the device in the version with additional sensors in Fig. 2).

The group of additional sensors ГрДопД consists of one or several sensors that are converters of values characterizing the state of the environment surrounding the user, having or may affect the state of the user in the process of monitoring or controlling his condition, in a form convenient for subsequent transmission via wired or wireless a data transmission channel to a data processing unit based on a processor module with BODPMP memory. These can be both sensors that characterize the change in the physical characteristics of the environment (atmospheric pressure, humidity, temperature, electromagnetic properties of the environment, etc.), and sensors that characterize the change in the sanitary and hygienic parameters of the environment (for example, sensors for registration of permissible or maximum permissible concentration of certain substances, dust sensors, etc.). The nomenclature of sensors (number, types, etc.) as part of the GRDopD is formed by the developer of the device based on the intended specific field of application and the methods used in it for determining the state of the user and its control, either independently or taking into account the recommendations of persons responsible for monitoring activities and monitoring the state of the user in the course of professional activity by the user of the device and / or monitoring the state of the user in the course of his professional activity.

In a device with additional sensors, a data processing module based on a processor module with a BODPMP memory is inserted into the data processing unit MODOP, designed for primary processing of signals from additional sensors included in the GRDopD (amplification of input signals, filtering noise, analog-to-digital conversion), subsequent processing of the digitized data in order to isolate significant indicators characterizing the impact of the environment on the user, and the subsequent issuance of data characterizing significant indicators to the module for assessing the alarm level and generating the MOFST alarm signal. The module for processing data of additional sensors MODOP can be implemented both on the basis of a processor or a group of processors of the processor module BODPMP, and on the basis of one or several special processors for digital signal processing, focused on solving problems of processing signals from a specific type of sensors. In a device with additional sensors, the module for assessing the alarm level and generating an alarm signal MOFST introduces a scheme for evaluating signals from additional SODD sensors, designed to analyze the data received by MOFST from MODOP, characterizing significant indicators, in order to identify the characteristics of the environment or changes in the state of the environment that have or may have an impact on the user in the course of carrying out activities in terms of changing the user's state, and, if any, for transferring the analyzed data characterizing significant indicators and / or the results of the analysis of these data to the PMFST submodule for generating alarms, which is a part of MofST. The SODD scheme can be implemented both on the basis of a processor or a group of processors of the BODPMP processor module, and on the basis of one or several specialized microcircuits.

A device with additional sensors can be implemented in a compact or other version, just like a device without additional sensors. At the same time, sensors from the group of sensors for determining the position of the GrDopD can be used as sensors attached to the user or the user's clothing with the ability to transmit data via a wireless channel, and fixed at a distance from the user (for example, on walls or doors when working in a production room) sensors with the ability to transmit data both wirelessly and via a wired channel.

Figure 3 shows a block diagram of the operation algorithm of the device.

Figure 4 shows a block diagram of the operation algorithm of the device in the version with additional sensors.

Before starting the operation of the device, the device is prepared for operation, while if the device is made in a compact version based on a portable product for personal use, which is a mobile electronic device, then it can be installed in the working position by attaching it to the user's body or clothing (for example, using strap, if it is a bracelet) or in any other way, so that the user does not experience any inconvenience in the process of carrying out activities. The physiological characteristics sensors are configured and installed, which make up a group of GrDPC physiological characteristics sensors and are designed to register signals of physiological characteristics, on the surface of the user's body (for example, these can be sensors of photoplethysmographic or electrocardiographic signals) or, in the case of remote signal registration of one or more individual signals physiological characteristics (for example, it can be thermal imaging sensors), within the territory or location of the user in the process of monitoring and controlling his condition. If the design of the device (for example, on the basis of a laptop) implies the installation of position detection sensors, then the position detection sensors are configured and installed, which make up the group of position sensors of the ATS and are designed to record the characteristics of the change in the user's position, on the surface of the user's body (for example, these can be sensors based on accelerometers) or, in the case of remote registration of a position change signal (for example, these can be sensors based on laser speed and range meters), within the territory or location of the user in the process of monitoring and controlling his condition. In the case of using the device in the version with additional sensors, if the design of the device implies the installation of additional sensors, then additional sensors are installed and configured, which make up the group of additional GrDopD sensors.

Further, after the start of work, the initial calibration and adjustment of the device is carried out, which consists in checking the control and functioning of the hardware and software of the data processing unit based on the processor module with the BODPMP memory, checking the control and functioning of all sensors and the device as a whole, and initial setting the software. Initial calibration and adjustment of the device is carried out using the hardware and software of the module for checking and monitoring the functioning of the MPKFD sensors. A session with a specific individual user begins only if the initial calibration of the device was successful, otherwise they find out the reasons and take measures to eliminate these causes, and if they do not give a result, the device stops working.

In the course of a session of a particular individual user of the device about sensors from the GdPC group, there is a registration of signals of physiological characteristics, sensors from the GdP group register signals characterizing a change in the position of the user's body or individual parts of the user's body, and, if the device is used in the version with additional sensors, then sensors from the GrDopD group register values that characterize the state of the environment surrounding the user and that have or may affect the state of the user in the process of monitoring or controlling his condition. After converting the recorded values, the values into a form suitable for subsequent transmission via a wired (for example, electric current or a signal in the optical range) or wireless data transmission channel (radio waves, infrared, optical or laser radiation) into a data processing unit based on a processor module with memory BODPMP, transfer to BODPMP is carried out.

Receiving signals from the outputs of the sensors included in the GRDFKh is carried out at the inputs of the module for processing data from the sensors of physiological characteristics MODFKh1. By means of hardware MODFH1, amplification of input signals, filtering of interference, analog-to-digital conversion and, if necessary, other conversions, which are primary signal processing, are carried out. By means of hardware and software MODFKh1, the digitized data are processed, which characterize diagnostically significant indicators and are the result of primary signal processing, after which the results of processing the digitized data are received from the output of the data processing module of the physiological characteristics sensors of the MODFKh1 to the input of the circuit for evaluating the signals of the sensors of the physiological characteristics of the SOFH included in a module for assessing the alarm level and generating an alarm signal MOFST of the data processing unit based on the processor module with the BODPMP memory.

Signals are received from the outputs of the sensors that are part of the GDRP at the inputs of the data processing module of the sensors for determining the position of the MODDP1. With the help of the hardware of the MODDP1, amplification of input signals, filtering of interference, analog-to-digital conversion and, if necessary, other conversions, which are the primary processing of signals, are carried out. By means of hardware and software MODDP1 processing of digitized data characterizing significant indicators and being the result of primary signal processing is carried out, after which the results of processing of the digitized data are received from the output of the data processing module of sensors for determining the position of MODDP1 to the input of the circuit for evaluating signals from sensors for determining the position of the MOTD, which is included in the module assessment of the alarm level and the formation of an alarm signal MOFST of the data processing unit based on the processor module with the BODPMP memory. Data processing can be carried out both on the basis of well-known digital signal processing algorithms characterizing the change in the user's position, and on the basis of digital signal processing algorithms specially developed for solving specific problems characterizing the change in the user's position, while each type of sensor has its own hardware and software. MOD DP1.

Also, the reception of signals from the outputs of the sensors that are part of the GRDFKh can be carried out at the input of the data processing module of the sensors of physiological characteristics MODFKh2, and by means of the hardware MODFKh2, amplification of input signals, filtering of interference, analog-to-digital conversion and, if necessary, other transformations can be carried out. , which are the primary signal processing. By means of hardware and software MODFKh2 can be used to process digitized data that also characterize diagnostically significant indicators and are the result of primary signal processing, after which the results of processing the digitized data can be sent to a special data storage (can be associated with the memory of the BODPMP). Data processing can be carried out both on the basis of well-known algorithms for digital processing of signals of physiological characteristics, and on the basis of algorithms for digital processing of signals of physiological characteristics specially developed for solving specific problems, while each type of signals of physiological characteristics corresponds to its own hardware and software as part of MODPC2.

Receiving signals from the outputs of the sensors that are part of the GRDU can also be carried out at the input of the data processing module of the sensors for determining the position of the MODDP2. With the help of the hardware of the MODDP2, amplification of input signals, filtering of interference, analog-to-digital conversion and, if necessary, other transformations, which are the primary processing of signals, are carried out. By means of hardware and software MODDP2 processing of digitized data can be carried out, which also characterize significant indicators and are the result of primary signal processing, after which the results of processing the digitized data can be sent to a special data storage (may be associated with the memory of the BODPMP). Data processing can be carried out both on the basis of well-known digital signal processing algorithms characterizing the change in the user's position, and on the basis of digital signal processing algorithms specially developed for solving specific problems characterizing the change in the user's position, while each type of sensor has its own hardware and software. MODDP2.

The set of specific indicators characterizing the change in the physiological characteristics of the user's health in the process of performing the activity and characterizing the change in the position of the user in the process of performing the activity is determined based on the features of the use of one or another hardware and software-algorithmic support as part of the device in the intended specific field of application and based on the in it, methods for determining the state of the user and its control and can be determined by the developer either independently or taking into account the recommendations of persons responsible for monitoring and controlling the state of the user in the course of professional activities by the user of the device and / or monitoring the state of the user in the exercise of professional activities. Also, based on the peculiarities of using one or another hardware and software-algorithmic support as part of the device in the intended specific area of application and based on the methods used in it for determining the state of the user and its control, the set of indicators can be divided into two groups of indicators: the first group of indicators , including the entire set of indicators characterizing the change in the physiological characteristics of the user's health in the process of carrying out activities and characterizing the change in the position of the user in the process of carrying out activities and determined by the method used for determining the state of the user and his control in the intended or designated specific area of application and its hardware and software implementation as part of devices; the second group of indicators, which includes all the most vital and necessary indicators from the first group, as well as those indicators from the first group, the processing of which is possible in real time or in accordance with the data processing protocol based on the capabilities of the device hardware and software, while the assessment changes in the user's state according to the second group of indicators should identify the presence of changes in the user's state and, if they are detected, classify them as urgent or non-urgent from the point of view of the need (desirability) of taking any measures in relation to the user when changes in the user's state are detected in accordance with with the given criteria. The first group of indicators is digitized and analyzed using hardware and software MODFKh2 and MODDP2, and the second group of indicators is digitized and analyzed using hardware and software MODFKh1 and MODDP1. For example, an implementation scheme is possible, in which: in the first module for processing data from the sensors of physiological characteristics, MODFH1, primary processing of signals of physiological characteristics from the surface of the user's body (rheoplethysmographic or electrocardiographic signal) is carried out in real time, followed by secondary processing of the digitized data resulting from the primary processing; in the second module for processing data from the sensors of physiological characteristics of the MODPC2, the digitized data can be processed both for signals of physiological characteristics from the surface of the user's body and signals that are the first derivative and derivatives of a higher order in time from signals of physiological characteristics from the surface of the user's body, with subsequent secondary processing digitized data resulting from primary processing; in the first module for processing the data of the sensors for determining the position of the MODDP1, primary processing of signals characterizing the movement of the user, the speed of movement of the user (the first derivative with respect to time) and the acceleration of the user (the second derivative with respect to time) is carried out in real time, followed by secondary processing of the digitized data resulting from the primary processing ; in the second module for processing the data of the sensors for determining the position of the MODDP2, signals are processed that characterize the movement of the user, the speed of the user (the first derivative in time) and the acceleration of the user (the second derivative in time), as well as signals characterizing the jerk (the third derivative in time) and the jump (the fourth time derivative or the first derivative of a jerk) and data of the third and higher time derivatives from the user's movement signals with subsequent secondary processing of the digitized data resulting from the primary processing.

If the device uses additional sensors, the reception of signals from the outputs of the sensors included in the GRDopD is carried out at the inputs of the data processing module of additional MODOP sensors. Input signals amplification, noise filtering, analog-to-digital conversion and, if necessary, other transformations, which are the primary signal processing, are carried out by means of the hardware of the MODOP. By means of hardware and software MODOP processing of digitized data characterizing significant indicators and resulting from primary signal processing is carried out, after which the results of processing of digitized data are received from the output of the data processing module of additional sensors of MODOP to the input of the circuit for evaluating signals of additional sensors of SDS included in the module for assessing the level alarm and the generation of an alarm signal MOFST of the data processing unit based on the processor module with the BODPMP memory in the event that a variant of the device with additional sensors is implemented. Data processing can be carried out both on the basis of well-known digital signal processing algorithms characterizing the change in the user's position, and on the basis of digital signal processing algorithms specially developed for solving specific problems characterizing the change in the user's position, while each type of sensor has its own hardware and software. MODOP.

At the same time, in real time or based on the capabilities of the hardware and software of the device, the following occurs: in the scheme for evaluating signals from the sensors of the physiological characteristics of the SOPC, the data received from the first module for processing data of the physiological characteristics of the MODFH1 and characterizing the change in the physiological characteristics of the user's health in the course of the activity are evaluated; in the scheme for evaluating the data of the sensors for determining the position of the PDS, the data received from the data processing module of the sensors of the change in the position of the PDS1 and characterizing the change in the position of the user in the course of the activity are evaluated; in the case of using additional sensors in the scheme for evaluating the signals of additional sensors of the SODD, the evaluation of the data received from the data processing module of the additional sensors of the MODOP and characterizing the state of the environment surrounding the user, affecting or likely to affect the state of the user in the process of monitoring or controlling his state, is carried out. The criteria for evaluating the data used in the schemes of SOFH, SODP, and, if provided for by the implementation of the device, SODD, are determined based on the intended specific field of application and the methods used in it for determining the state of the user and its control, taking into account the specific hardware and software implementation. Also, taking into account a specific hardware and software implementation and based on the intended specific field of application and the methods used in it for determining the state of the user and his control, in the process of work, the evaluation parameters can be adjusted based on the evaluation criteria used in the scheme for correcting the parameters to the module for assessing the alarm level and generating an alarm signal MOFST. In this case, the correcting data from the outputs of the SKPO circuit are fed to the corresponding inputs of the SOFH, SODP, and, if provided by the device implementation option, SODD. In the scheme for adjusting the parameters of the assessment of the SCME in the module for assessing the alarm level and generating an alarm signal MFST, assessment criteria based on adaptive dependencies with variable coefficients can be used, for the construction of which data on the dynamics of the previous state of the user can be used, as well as data on the features of the dynamics of the previous or current the states of a group of one or more one other users.

If, during the operation of the device, the results when evaluating the received data in at least one of the SOFH, DODP schemes, and, if provided by the device implementation option, SODD, an alarm condition is identified, then, during the initial identification of such a state, the circuit ( ) in which the alarm state is identified, to the module for checking and monitoring the functioning of the MPPCD sensors via bidirectional data transmission channels connecting the inputs-outputs of the MPPCD and the inputs-outputs of the circuit for evaluating signals from the sensors of the physiological characteristics of the SOPH, the circuit for evaluating the signals of the sensors for determining the position of the SODP and, if provided by the option implementation of the device, a circuit for evaluating the signals of additional sensors of SODD. In turn, the MPKFD checks the control and operation of sensors from the GrDFH, GRDP groups and, if provided by the device implementation option, GrDopD, by exchanging data via bidirectional data exchange channels connecting the inputs-outputs of the MPKFD with the inputs-outputs of the group of sensors of physiological characteristics of the GrDFH, a group of sensors for determining the position of the GRD, and, if provided for by the embodiment of the device, a group of additional sensors of the GRDopD. Also, at the same time, the hardware (hardware and software) BODPMP is tested for the physiological reliability of the received data and the values of the received data falling within the permissible threshold values or within the specified limits during the operation of the device. In addition, special test checks can be carried out (for example, checking the accidental fall of the device in the event of a possible event when the device is implemented in a mobile version based on a smartphone or bracelet). Calls to the module for checking and monitoring the functioning of the MPKFD sensors are also possible with subsequent messages about the alarm state in accordance with the specified algorithm. If, as a result of checking the control and functioning of sensors and software, violations are revealed, then the session of a particular user ends. Depending on the nature of violations (for example, breakdown of sensors, etc.), the device may terminate.

If, when evaluating the received data in at least one of the SOPH, SODP circuits, and, if provided by the device implementation option, SODD, the alarm state is considered as an urgent alarm state, then the data evaluation results are sent from the outputs of these circuits to the associated inputs of the signal generation circuit urgent alarm SFSST of the submodule for generating alarms of the module for assessing the alarm level and generating the PMFST alarm signal.

If, when evaluating the received data in at least one of the SOPH, SODP schemes, and, if provided by the device implementation option, SODD, the alarm state is considered as a non-urgent alarm state, then the results of the data evaluations are sent from the outputs of these circuits to the associated inputs of the signal generation circuit non-urgent alarm SFNST of the submodule for generating alarms of the module for assessing the alarm level and generating an alarm PMFST. At the same time, the transmission of data processing results from the output of the data processing module of the position sensors MODDP2 to the input of the MODP2 circuit is initiated and the transfer of the data processing results from the output of the data processing module of the sensors of physiological characteristics MODFKh2 to the input of the SOPH circuit is initiated. Initiation of the transmission of data processing results from the output of the data processing module of the position sensors of the MODDP2 to the input of the MODDP circuit is carried out by transferring the coding data sequences from one or more outputs associated with the additional inputs of the MODDP2 from the group of outputs: SOPH output, SODP output, SODD output (if additional sensors) to the associated additional inputs of MODDP2. Initiation of the transfer of data processing results from the output of the data processing module of the sensors of physiological characteristics MODFX2 to the input of the SOFH circuit is carried out by transferring coding data sequences from one or more outputs associated with additional inputs of the MODFX2 from the group of outputs: SOFX output, SODP output, SODD output (if used additional sensors) to the associated additional inputs of MODFX2. The hardware and software-algorithmic support of the SOFH and FODP circuits of the device is made in such a way that the evaluation of the received data in the SOFH, FODP schemes would be carried out taking into account not only the data of the MODFKh1, MODDP1, but also MODFKh2, MODDP2.

The generation of a non-urgent alarm signal occurs in the scheme for generating non-urgent alarm signals SFNST of the submodule for generating alarms of the module for assessing the alarm level and generating an alarm signal PMFST using the results of the evaluations of the data received at the inputs of the scheme for generating non-urgent alarm signals SFNST in accordance with the specified algorithms (for example, it can be generalized Bayesian-type algorithms, in which a non-urgent alarm signal is generated by assigning coefficients to the data evaluation results adopted in the SFNST, followed by the generation of a non-urgent alarm signal by applying a group of logical operations on the set of assigned coefficients and the set of data evaluation results) If, in the process of formation, the generated alarm signal begins to meet the criteria according to which it should be classified as an urgent alarm, then the data is transmitted from the SFNST output to the SFSST input. After the non-urgent alarm signal has been formed, it comes from the output of the scheme for generating signals of non-urgent alarm SFNST to the associated input of the unit for issuing an alarm signal BVST.

An urgent alarm signal is generated in the SFSST urgent alarm signal generation circuit of the alarm generation submodule of the alarm level assessment module and the PMFST alarm generation based on information that during the operation of the device, the results of data assessments have appeared that assess the alarm state as an urgent alarm. After the urgent alarm signal has been formed, it comes from the output of the circuit for generating urgent alarm signals SFSST to the associated input of the unit for issuing the alarm signal BVST.

The generated alarm signal arriving at the BVST alarm signaling unit is converted into a form in which it will be issued from the outputs to the final addressees. The nature and form of presentation of the issued alarm signals (sound or light-music signal, message via a wireless channel, etc.), as well as the design features of the BVST are determined based on the intended specific field of application and the methods used in it for determining the state of the user and his control. Various variants of combinations of types of the issued alarm signal are possible (for example, in the case of a device based on a personal computer, an alarm signal is initially generated in the form of an SMS message and comes to the person who monitors the user's condition during his professional activities, which, in turn, triggers an audible alarm). Depending on the situation and the state of the user, a decision can be made to continue the work session or end the work session of an individual user, and after the end of the work session of an individual user, both the start of a new work session and the termination of work are possible.

Claims (8)

1. A device for monitoring and notifying about the state of the user, containing a group of sensors of physiological characteristics; a group of position detection sensors; a data processing unit based on a processor module with memory, including a first module for processing data from physiological characteristics sensors with inputs associated with the outputs of a group of physiological characteristics sensors and with an output associated with the input of the circuit for evaluating signals from physiological characteristics sensors of the module for evaluating the alarm level and generating an alarm signal, a first module for processing position detection sensors data with inputs associated with the outputs of a group of position detection sensors and with an output associated with an input of a circuit for evaluating signals of position detecting sensors of the module for evaluating an alarm level and generating an alarm signal; a submodule for generating an alarm of the module for evaluating the alarm level and generating an alarm signal; an alarm signal generating unit with inputs connected to the outputs of the submodule for generating an alarm of the module for evaluating the alarm level and generating an alarm signal; a transceiver, characterized in that the following are introduced into the data processing unit based on the processor module with memory: a second module for processing data from physiological characteristics sensors with inputs associated with the outputs of a group of physiological characteristics sensors, with an output associated with the input of a circuit for evaluating signals from physiological characteristics of the evaluation module the alarm level and the formation of an alarm signal, and with additional inputs associated with the outputs of the circuit for evaluating the signals of the sensors of the physiological characteristics of the module for evaluating the alarm level and generating an alarm signal and outputs of the circuit for evaluating the signals of the sensors for determining the position of the module for evaluating the alarm level and generating an alarm signal; the second module for processing position sensing sensors data with inputs connected to the outputs of a group of position sensing sensors, with an output connected to the input of the signal evaluation circuit for detecting the position of the alarm level evaluation module and generating an alarm signal, and with additional inputs connected to the outputs of the signal evaluation circuit sensors of physiological characteristics of the module for evaluating the alarm level and generating an alarm signal and outputs of the circuit for evaluating signals from the sensors for determining the position of the module for evaluating the alarm level and generating an alarm signal; a module for checking and monitoring the functioning of sensors, connected through inputs-outputs with inputs-outputs of a group of physiological characteristics sensors and a group of position detection sensors and connected through inputs-outputs with inputs-outputs of a circuit for evaluating signals of physiological characteristics of a module for evaluating an alarm level and generating an alarm; and circuits for evaluating sensor signals for determining the position of the module for evaluating the alarm level and generating an alarm signal; in the module for assessing the alarm level and generating an alarm signal, a circuit for adjusting the assessment parameters was introduced with outputs associated with the inputs of the circuit for assessing signals of physiological characteristics of the module for assessing the alarm level and generating an alarm signal and inputs of the circuit for assessing sensor signals for determining the position of the module for assessing the alarm level and generating an alarm signal , and the circuit for evaluating the signals of the sensors of the physiological characteristics of the module for evaluating the alarm level and generating an alarm signal and the circuit for evaluating the signals of the sensors for determining the position of the module for evaluating the alarm level and generating the alarm signal are connected to each other through synchronization inputs-outputs and have outputs associated with the inputs of the signal generation circuit non-urgent alarm of the submodule for generating alarms of the module for assessing the alarm level and generating an alarm signal and the inputs of the circuit for generating urgent alarms of the submodule for generating alarms of the module for assessing the alarm level and generating alarm signal generation, while the circuit for generating non-urgent alarm signals of the submodule for generating alarms of the module for assessing the alarm level and generating an alarm signal has an output connected to the input of the circuit for generating urgent alarms of the submodule for generating alarms of the module for assessing the alarm level and generating an alarm signal. 2. The device for monitoring and notifying the user state according to claim 1, characterized in that the device includes a group of additional sensors, the data processing unit based on the processor module with memory includes a signal processing module for additional sensors with inputs associated with the outputs of the group additional sensors and with an output associated with the input of the circuit for evaluating signals of additional sensors included in the module for evaluating the alarm level and generating an alarm signal of the data processing unit based on the processor module with memory, while the second data processing module for the physiological characteristics of the data processing unit based on processor module with memory and the second module for processing sensor data for determining the position of the data processing unit based on the processor module with memory contain additional inputs associated with the outputs of the circuit for evaluating signals of additional sensors of the module for evaluating the alarm level and generating an alarm, module checking and monitoring the functioning of sensors of a data processing unit based on a processor module with memory is additionally connected through inputs-outputs with inputs-outputs of a group of additional sensors and through inputs-outputs with inputs-outputs of a circuit for evaluating signals of additional sensors of the module for evaluating the alarm level and generating a block alarm data processing on the basis of a processor module with memory, the circuit for correcting the evaluation parameters in the module for evaluating the alarm level and generating an alarm signal contains an additional output connected to the corresponding input of the circuit for evaluating signals of additional sensors of the module for evaluating the alarm level and generating an alarm, a circuit for evaluating signals from additional sensors of the module for assessing the alarm level and generating an alarm signal has outputs associated with the inputs of the circuit for generating signals of a non-urgent alarm of the submodule for generating alarms of the module for assessing the alarm level and generating an alarm signal and the inputs of the circuit for generating system urgent alarm channels of the submodule for generating alarms of the module for evaluating the alarm level and generating an alarm signal. 3. The device for monitoring and notifying the state of the user according to claim 1, characterized in that it is structurally made in a mobile version. 4. The device for monitoring and alerting the user according to claim 3, characterized in that it is structurally made in the form of a bracelet. 5. The device for monitoring and alerting about the user's state according to claim 1, characterized in that the group of physiological characteristics sensors includes at least one photoplethysmographic sensor and at least one sensor from the group: an electrocardiographic signal sensor, a temperature sensor, and a blood pressure sensor. 6. The device for monitoring and notifying about the state of the user according to claim 1, characterized in that the scheme for adjusting the evaluation parameters in the module for evaluating the alarm level and generating an alarm signal uses evaluation criteria based on adaptive dependencies with variable coefficients. 7. A device for monitoring and notifying the state of the user according to claim 6, characterized in that data on the dynamics of the previous state of the user are used to build adaptive dependencies. 8. The device for monitoring and notifying about the state of the user according to claim 6, characterized in that to build adaptive dependencies, data on the dynamics of the previous or current state of a group of one or more one other users are used.

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