KR102128719B1 - Health care monitoring system using smart health care mattress - Google Patents

Abstract

The present invention relates to a healthcare management monitoring system using a smart healthcare mattress. The healthcare management monitoring system includes at least one smart healthcare mattress for non-contact detecting a signal related to biometric information of a measurement target existing on a mattress and transmitting the signal together with preset unique device identification information; and a healthcare monitoring server for receiving the unique device identification information together with the signal related to the biometric information of a corresponding measurement target transmitted from each smart healthcare mattress, and based on the unique device identification information and the signal, analyzing at least one piece of healthcare state information among the breath, heart rate, movement, distance, sleep or condition of the corresponding measurement target for each smart healthcare mattress, wherein the healthcare monitoring server provides a service that converts each healthcare status information of the corresponding measurement target analyzed by each smart healthcare mattress into a database (DB), stores and manages the healthcare status information, and allows an administrator to visually monitor the health care status of the corresponding measurement target in real time. Accordingly, it is possible to efficiently monitor in real time various health care status information such as breathing, heart rate, movement, distance, sleep, and/or condition of a patient or an individual through a mattress used in a hospital or a personal living space.

Description

Health care monitoring system using smart healthcare mattress {HEALTH CARE MONITORING SYSTEM USING SMART HEALTH CARE MATTRESS}

The present invention relates to a health care monitoring system using a smart healthcare mattress, and more specifically, using a smart healthcare mattress to efficiently monitor health care using a smart healthcare mattress for a healthy and comfortable sleep. It relates to a health care monitoring system.

In general, a biosignal such as respiratory rate is one of the most easily diagnosed factors for the health condition and abnormality of the human body. Mainly, vital signs are continuously checked by attaching a biosignal measuring device (for example, a respirator) to critically ill patients, emergency patients, patients during surgery, or elderly people vulnerable to health maintenance.

For example, an oxygen mask is attached to a patient during surgery to continuously check the patient's breathing state during surgery. The oxygen mask may give a fear to the patient, and the number of connecting lines connecting the oxygen mask and the respiratory state monitoring device Due to the constraints on the circulation of people, such as doctors, it was difficult to combine it with other procedures or surgeries.

In addition, in many cases, it is necessary to check the breathing status of people who live outside the hospital, as well as patients who are hospitalized or operated in the hospital. For example, it is necessary to measure the breathing pattern during sleep or the breathing pattern of infants and toddlers who live in a space different from the parents or the elderly who have unstable breathing patterns.

In particular, in recent years, it is necessary to go beyond the degree of diagnosing sleep apnea, a disease that does not breathe temporarily during sleep, and to measure the actual respiratory rate or respiratory volume and use it to diagnose the health condition of the person.

However, it has been difficult to obtain data by accurately measuring a user's respiratory rate and respiratory volume without a respiratory measurement device such as that provided in a hospital, and accurately delivering the obtained data to a doctor in a hospital.

In particular, the conventional method of attaching a simple sensor or the like to the body and measuring the respiratory rate using the primary signal obtained from the sensor is much shorter in its accuracy than the method of measuring the respiratory rate through hospital equipment. .

In order to solve this problem, in Korean Patent Registration No. 10-1654914 (respiratory measurement device and breathing measurement method using the same), a pad attachable to a user's body and installed on the pad, the It includes three or more sensors for measuring a signal generated according to the movement of the user's body, and a determination unit for measuring the respiratory rate of the user using signals measured by at least two or more of the three or more sensors, The sensor includes a first sensor and a second sensor, and the determining unit compares the first signal measured by the first sensor with the second signal measured by the second sensor, and within a time difference within a preset range. Disclosed is a respiratory measuring device capable of accurately and conveniently measuring a user's respiratory rate by counting the number of times the peak values of the first signal and the second signal appear and counting the respiratory rate.

In the related art, the user's breathing data during daily life outside the hospital can be transmitted to a system such as a hospital to remotely check the user's health status in real time, and the user's respiratory rate without attaching an oxygen mask or the like to the user. By measuring, it has the advantage of being able to monitor the patient's breathing status in real time, in parallel with surgery and various treatments.

However, in the prior art respiratory measurement device and respiratory measurement method, as a contact device attached to a user's body, there is a limitation in that respiratory measurement cannot be performed without the user wearing it.

Domestic patent registration No. 10-1654914 (announced on October 10, 2016) Domestic patent publication No. 10-2006-0005092 (published on Jan. 17, 2006)

The present invention has been devised to solve the above-mentioned problems, and an object of the present invention is to measure the distance of a measurement object existing on a mattress in a non-contact manner through a radar at a short distance and based on this, breathing and/or heart rate of the measurement object By using a smart healthcare mattress that detects, it effectively provides a variety of health care status information, such as the patient's or individual's breathing, heart rate, movement, distance, sleep, and/or condition, through a mattress used in a hospital or personal living space. It is to provide a health management monitoring system using a smart healthcare mattress for real-time monitoring.

In order to achieve the above object, an aspect of the present invention, at least one smart healthcare mattress that detects a non-contact signal related to the bio-information of the measurement object existing on the mattress and transmits it together with the predetermined unique device identification information. ; And by receiving unique device identification information along with signals related to the bio-information of the corresponding measurement object transmitted from each smart healthcare mattress, based on this, breathing, heart rate, movement, distance, sleep of the corresponding measurement object for each smart healthcare mattress Or, after analyzing at least one health condition information of the condition, each smart health care mattress analyzed and stored and managed each health condition information of the target object in a database (DB), and the administrator visually It is to provide a health care monitoring system using a smart health care mattress that includes a health care monitoring server that provides a service for real-time monitoring of the health condition of the measurement target.

Here, each smart healthcare mattress, the mattress is provided with at least one cushion member is laminated inside the outer shell; At least one health care sensor module mounted on a predetermined space formed in the cushion member of the mattress and using a radar to detect a signal related to the bio-information of a measurement object on the mattress in a non-contact manner; And a health care control that receives a signal related to the bio-information of the corresponding measurement object detected from each health care sensor module and controls the device to be transmitted to the health care monitoring server through a wired or wireless communication method along with preset unique device identification information. It is preferred to include modules.

Preferably, each health care sensor module, a radar transmitting unit for transmitting a first signal having a radar pulse (Radar Pulse) for the measurement object present on the mattress; A radar receiver which is reflected from the measurement object and receives a second signal related to the first signal; A signal processing unit for extracting frequencies based on first and second signals transmitted and received from the radar transmitter and the radar receiver, and processing signals related to bio-information of a corresponding measurement object according to a phase difference of the frequencies; A printed circuit board (PCB) on which the radar transmitting unit, the radar receiving unit and the signal processing unit are mounted, as well as a sensor communication with the healthcare control module and a data cable for electrically supplying a power supply; And a PCB protection part formed by molding so that the entire outside of the PCB substrate part is wrapped through an injection molding method of liquid silicone for waterproofing and preventing shock of the PCB substrate part.

Preferably, the health care control module is installed to be spaced apart from the mattress at a predetermined distance, and a main body portion forming an overall body; A cable connector provided to be exposed on the outside of the main body and electrically connected to a data cable connected to the PCB substrate; A communication unit that transmits unique device identification information in a wired or wireless communication method along with a signal related to the bio-information of the corresponding measurement object existing on the mattress; A control unit that is provided inside the main body, and controls the operation of the communication unit such that unique device identification information preset with a signal related to the biometric information of the measurement target transmitted through the cable connector is transmitted to the healthcare monitoring server. ; And it is provided inside the body portion, and may include a power supply for supplying power required for each healthcare sensor module through the cable connector, including the power required for the control unit.

Preferably, a storage unit provided on the inside/outside of the main body, and storing at least one health care status information among breath, heartbeat, movement, distance, sleep, or condition of the measurement object; And it is provided on the outside of the main body portion, the display unit for visually displaying at least one of the health status information of the measurement target breath, heart rate, movement, distance, sleep, or condition state.

Preferably, the control unit, based on a signal related to the bio-information of the measurement target transmitted through the cable connector, at least one health care state of the respiratory, heart rate, movement, distance, sleep, or condition of the measurement target After analyzing the information, the health care state information analyzed for each health care state is converted into a database (DB) to be stored and managed in the storage unit, and the display is displayed on a display screen for a user to visually check. You can control negative behavior.

Preferably, when each healthcare sensor module is composed of a plurality, the controller receives the final measurement value from each healthcare sensor module through the cable connector, and based on this, the corresponding measurement is measured from the final measurement value of each healthcare sensor module. After extracting distance information from the target, if the final measurement value of each healthcare sensor module is a preset measurement valid value, the difference is determined to be less than a preset reference distance difference value by comparing with the previously stored distance value Control the operation of the communication unit so that the final measured value of the healthcare sensor module is transmitted to the healthcare monitoring server, or the corresponding measurement is based on the final measured value of the healthcare sensor module determined to be below the preset reference distance difference value. At least one of the health status information of the subject's breathing, heart rate, movement, distance, sleep, or condition may be analyzed.

Preferably, when the final measurement value of each health care sensor module is a preset measurement valid value, the difference is compared with a previously stored distance value from a previously measured object, and the difference is determined to be greater than or equal to a preset reference distance difference value. Based on the final measured value of the care sensor module, it is determined whether or not the object to be measured is moved, and when it is determined as the motion of the measured object, the difference is compared to the last measured value of the recently stored health care sensor module, and the difference is less than or equal to a preset reference approximation. Control the operation of the communication unit so that the final measured value of the healthcare sensor module determined to be transmitted to the healthcare monitoring server, or the corresponding measurement based on the final measured value of the healthcare sensor module determined to be below the preset reference approximation value. At least one of the health status information of the subject's breathing, heart rate, movement, distance, sleep, or condition may be analyzed.

Preferably, the control unit compares with the last measured value of the recently stored health care sensor module when judged as the movement of the measurement object, and among the final measured values of the health care sensor module, the difference of which is determined to be greater than or equal to a preset reference approximation value. Control the operation of the communication unit so that the final measurement value of the health care sensor module having the smallest difference is transmitted to the health care monitoring server, or final measurement values of the health care sensor module determined to be greater than or equal to the preset reference approximation value. Based on the final measurement value of the health care sensor module having the smallest difference, it is possible to analyze at least one health care state information of the breathing, heart rate, movement, distance, sleep, or condition of the corresponding measurement object.

Preferably, the measurement intake port is formed on one side of the body portion to suck the outside air; A measurement outlet formed on the other side of the main body to discharge internal air; And it is provided inside the body portion, by inhaling the external air through the measurement inlet to detect the alpha particles in the air in real time to output a predetermined alpha particle detection signal, the predetermined measurement based on the output alpha particle detection signal After counting for a time to calculate the alpha particle concentration value, a radon measurement unit for discharging the air inside the body through the measurement outlet may be further included.

Preferably, the control unit receives the alpha particle concentration value calculated from the radon measurement unit and digitizes the measurement value of radon in the air existing around the mattress based on this, along with the unique device identification information set in advance. Control the operation of the communication unit to be transmitted to the care monitoring server, or control the data to be stored and managed in a separate storage unit by making a database (DB) of the digitized radon measurement by hour/day/day/week/month It can be controlled to be displayed on the display screen of a separate display unit so that the user can visually confirm.

Preferably, the healthcare monitoring server is provided with unique device identification information along with radon measurement values in the air present in the vicinity of each smart healthcare mattress transmitted from the communication unit through a pre-installed healthcare-related application. In accordance with the manager's request, the current radon measurement value, average radon measurement value, or pre-set reference radon in the air in the vicinity of each smart healthcare mattress by hour/day/day/week/month using a circular or bar graph Comparison with measured values Provide monitoring service to display at least one radon measured value on a display screen in real time, or measure current radon measured by each smart healthcare mattress, average radon measured value, or preset reference radon measured Comparison with the value It is possible to provide a service to store and manage at least one radon measurement value in a database (DB) by hourly/daily/weekly/weekly/monthly.

Preferably, it is provided inside the body portion, and after detecting the concentration of fine dust in the air by sucking the outside air through the measurement inlet, the fine dust detection unit for discharging the internal air through the measurement outlet; And it is provided inside the body portion, after detecting the concentration of ultra-fine dust in the air by sucking the outside air through the measurement inlet, the ultra-fine dust detector for discharging the internal air of the body through the measurement outlet further included Can.

Preferably, the control unit digitizes the fine dust concentration value and the ultrafine dust concentration value in the air detected by the fine dust detection unit and the ultrafine dust detection unit, respectively, and the health care together with preset unique device identification information. Control the operation of the communication unit to be transmitted to the monitoring server, or make the database (DB) for the hourly/daily/weekly/weekly/monthly digitized fine dust concentration and ultra-fine dust concentration values and store them in a separate storage unit. In addition to being controlled to be managed, it can be controlled to be displayed on the display screen of a separate display unit so that the user can visually confirm.

Preferably, the healthcare monitoring server is a unique device with fine dust concentration values and ultra fine dust concentration values in the air present in the vicinity of each smart healthcare mattress transmitted from the communication unit through a pre-installed healthcare-related application. Based on the identification information, the current fine dust/ultrafine dust concentration in the air in the vicinity of each smart healthcare mattress by hourly/daily/weekly/weekly/monthly based on the manager's request Measurement value, average fine dust/ultrafine dust concentration measurement value, or comparison with a preset reference fine dust/ultrafine dust concentration measurement value. At least one concentration measurement value of fine dust/ultrafine dust concentration measurement value is displayed on the display screen. Provide monitoring services to be displayed in real time, current micro dust/ultra fine dust concentration measurement value for each smart healthcare mattress, average fine dust/ultra fine dust concentration measurement value, or preset standard fine dust/ultra fine dust concentration measurement value Comparison with and can provide services to store and manage at least one concentration measurement value of fine dust/ultrafine dust concentration by database (DB) by hour/day/day/week/week/month have.

Preferably, it is installed to be exposed on the PCB protection part or is installed inside/outside the body part provided in the healthcare control module, and measures the temperature of the surroundings of each healthcare sensor module or the surroundings of the healthcare control module. A temperature measuring unit; And a humidity installed to be exposed on the PCB protection part or installed inside/outside the body part provided in the healthcare control module, and measuring humidity with respect to the periphery of each healthcare sensor module or the periphery of the healthcare control module. Measurement unit may be further included.

Preferably, the control unit provided in the health care control module, by digitizing the temperature and humidity values respectively measured from the temperature measurement unit and the humidity measurement unit to the healthcare monitoring server with a unique set of device identification information Control the operation of the communication unit to be transmitted, or control the data to be stored and managed in a separate storage unit by converting the digitized temperature and humidity values into a database (DB) for each hour/day/day/week/month. It can be controlled to be displayed on the display screen of a separate display unit for visual confirmation.

Preferably, the healthcare monitoring server is a unique device with temperature and humidity values for the periphery of each healthcare sensor module or the periphery of the healthcare control module transmitted from the communication unit through a pre-installed healthcare-related application. Based on the identification information, the current temperature/humidity measured value, average temperature/humidity measured value, or preset reference temperature/hourly/daily/weekly/weekly/monthly based on the administrator's request Comparison with humidity measurement value Provide monitoring service so that at least one measurement value of temperature/humidity measurement value is displayed on the display screen in real time, or present temperature/humidity measurement value, average temperature/humidity measurement value for each smart healthcare mattress, Alternatively, the service is to be stored and managed in a separate storage device by establishing a database (DB) for each hour/day/day/week/month/month by comparing at least one measured temperature/humidity measurement value with a preset reference temperature/humidity measurement value. Can provide.

Preferably, the carbon monoxide detection unit is provided inside the main body, detects carbon monoxide (CO) concentration in the air by inhaling external air through the measurement intake, and discharges the internal air through the measurement outlet; And a carbon dioxide detector that is provided inside the main body part, detects carbon dioxide (CO ₂ ) concentration in the air by inhaling external air through the measurement inlet, and then discharges the internal air through the measurement outlet. Can.

Preferably, the control unit digitizes the carbon monoxide concentration value and the carbon dioxide concentration value in the air present in the periphery of each smart healthcare mattress sensed by the carbon monoxide detection unit and the carbon dioxide detection unit, and presets unique device identification information and Control the operation of the communication unit to be transmitted to the healthcare monitoring server together, or store the DB (DB) by hourly/daily/weekly/weekly/monthly in the digitized carbon monoxide concentration and carbon dioxide concentration values in a separate storage unit And it can be controlled to be displayed on the display screen of a separate display unit for control so that the user can visually check the control to be managed.

Preferably, the healthcare monitoring server receives unique device identification information along with carbon monoxide concentration and carbon dioxide concentration values for the periphery of each smart healthcare mattress transmitted from the communication unit through a pre-installed healthcare-related application. Based on the administrator's request, the current carbon monoxide/carbon dioxide concentration measurement value, average carbon monoxide/carbon dioxide concentration measurement value by hour/daily/day/weekly/monthly using a circular or bar graph, or a preset reference carbon monoxide/carbon dioxide concentration measurement value Compare with and provide monitoring service to display at least one concentration measurement value among carbon monoxide/carbon dioxide concentration measurements in real time on the display screen, or present current carbon monoxide/carbon dioxide concentration measurement value for each smart healthcare mattress, average carbon monoxide/carbon dioxide concentration measurement value , Or comparison with a preset reference carbon monoxide/carbon dioxide concentration measurement value. At least one concentration measurement value among carbon monoxide/carbon dioxide concentration measurement values is stored in a separate storage device by database (DB) by hourly/daily/day/weekly/monthly And services to be managed.

Preferably, the health care monitoring server, by using a pre-installed health care-related application for each smart health care mattress analyzed each health status information of the measurement target according to the administrator's request using a circular or bar graph hourly / Provide monitoring service to display at least one status measurement value among the current status measurement value, average status measurement value, or comparison status measurement value with a preset reference status measurement value on a daily/day/weekly/monthly basis. Can.

Preferably, the health care monitoring server, each smart health care mattress is analyzed by each of the measurement target breath, heart rate, movement, distance, sleep, or at least one of the current health care status measurement value of the pre-set each criterion When the health measurement value is exceeded, a service is provided so that the manager can audibly or visually check the health care warning message corresponding to the current health care health measurement value, or the measurement target of each smart healthcare mattress is auditory The service can be provided to be transmitted to a separate voice output unit or display unit connected to each smart healthcare mattress for red or visual confirmation.

Preferably, the healthcare monitoring server may provide a cloud computing service in response to a request from an external client terminal.

Preferably, the client terminal, by using the client member login cloud web service of the healthcare monitoring server, the respiratory, heart rate, movement, distance of the corresponding measurement object analyzed and stored for each smart healthcare mattress on the healthcare monitoring server. , At least one of the health status information of the sleep or condition may be searched in real time and displayed on the display screen.

Preferably, the healthcare monitoring server, database (DB) of at least one healthcare state information of the respiratory, heart rate, movement, distance, sleep, or condition of the corresponding measurement object analyzed for each smart healthcare mattress When storing, at least one of the health status information of the respiratory, heart rate, movement, distance, sleep, or condition of the corresponding measurement object analyzed for each smart healthcare mattress is encrypted and stored using a symmetric or asymmetric encryption method. A service is provided so that a decryption key capable of decrypting at least one health status information of breath, heartbeat, movement, distance, sleep, or condition of the measurement target for each of the encrypted smart health care mattresses is transmitted to the client terminal. Can provide.

Preferably, the client terminal uses the decryption key transmitted from the healthcare monitoring server together with the corresponding client member login information to breathe and heartbeat the corresponding measurement target for each smart healthcare mattress stored and encrypted in the healthcare monitoring server. , At least one of the health status information of the movement, distance, sleep, or condition may be decoded and displayed in real time on a search and display screen.

Preferably, the healthcare monitoring server can download at least one healthcare state information of breath, heart rate, movement, distance, sleep, or condition of each measurement object for each smart healthcare mattress through the client terminal. Cloud web services.

Preferably, the client terminal, the breathing, heart rate, movement, distance, sleep, or the corresponding measurement target of each smart healthcare mattress stored in the healthcare monitoring server through the healthcare-related application downloaded from the healthcare monitoring server, or At least one health status information of the condition status may be displayed on a real-time search and display screen.

According to the health care monitoring system using the smart healthcare mattress of the present invention as described above, through a radar at a short distance to measure the distance of the measurement object present on the mattress non-contact and based on this, breathing and / / of the measurement object Or by using a smart health care mattress that detects the heart rate, various health care status information such as breathing, heart rate, movement, distance, sleep, and/or condition of a patient or individual through a mattress used in a hospital or a personal living space It has the advantage of being able to efficiently monitor in real time.

1 is an overall block diagram for explaining a health care monitoring system using a smart healthcare mattress according to an embodiment of the present invention.
2 is an overall installation configuration diagram for explaining a smart healthcare mattress applied to an embodiment of the present invention.
3 is an overall block configuration diagram illustrating a smart healthcare mattress applied to an embodiment of the present invention.
4 is a perspective view and a cross-sectional view of each healthcare sensor module applied to an embodiment of the present invention.
5 is a block diagram for explaining each health care sensor module applied to an embodiment of the present invention.
6 is a detailed block diagram illustrating a healthcare control module applied to an embodiment of the present invention.
7 is a flowchart for explaining a process of performing a control of the healthcare control module when each healthcare sensor module applied to an embodiment of the present invention is composed of a plurality.
8 is a detailed block diagram illustrating an external terminal applied to an embodiment of the present invention.

The above-described objects, features, and advantages will be described in detail below with reference to the accompanying drawings, and accordingly, a person skilled in the art to which the present invention pertains can easily implement the technical spirit of the present invention. In the description of the present invention, when it is determined that detailed descriptions of known technologies related to the present invention may unnecessarily obscure the subject matter of the present invention, detailed descriptions will be omitted.

Terms including ordinal numbers such as first and second may be used to describe various components, but the components are not limited by the terms. The terms are used only for the purpose of distinguishing one component from other components. For example, the first component may be referred to as a second component without departing from the scope of the present invention, and similarly, the second component may be referred to as a first component. The terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

The terminology used in the present invention has been selected, while considering the functions in the present invention, general terms that are currently widely used have been selected, but this may vary according to the intention or precedent of a person skilled in the art or the appearance of new technologies. In addition, in certain cases, some terms are arbitrarily selected by the applicant, and in this case, their meanings will be described in detail in the description of the applicable invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the entire contents of the present invention, not a simple term name.

When a certain part of the specification "includes" a certain component, this means that other components may be further included rather than excluding other components unless otherwise specified. In addition, terms such as "... unit" and "module" described in the specification mean a unit that processes at least one function or operation, which may be implemented in hardware or software, or a combination of hardware and software. .

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the embodiments of the present invention illustrated below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art.

Combinations of each block in the accompanying block diagrams and steps of the flow charts may be performed by computer program instructions (execution engines), which are executed by a general purpose computer, special purpose computer, or other programmable data processing equipment processor. Since it can be mounted, the instructions executed through a processor of a computer or other programmable data processing equipment create a means to perform the functions described in each block of the block diagram or in each step of the flowchart. These computer program instructions can also be stored in computer readable or computer readable memory that can be oriented to a computer or other programmable data processing equipment to implement functionality in a particular way, so that computer readable or computer readable memory The instructions stored in it are also possible to produce an article of manufacture containing instructions means for performing the functions described in each block of the block diagram or in each step of the flowchart.

In addition, since computer program instructions may be mounted on a computer or other programmable data processing equipment, a series of operation steps are performed on a computer or other programmable data processing equipment to create a process executed by the computer to generate a computer or other program. It is also possible for instructions to perform possible data processing equipment to provide steps for executing the functions described in each block of the block diagram and in each step of the flowchart.

Further, each block or each step can represent a module, segment, or portion of code that includes one or more executable instructions for executing specified logical functions, and in some alternative embodiments, referred to in blocks or steps It should be noted that it is also possible for functions to occur out of sequence. For example, two blocks or steps shown in succession may in fact be executed substantially simultaneously, and it is also possible that the blocks or steps are performed in the reverse order of the corresponding function as necessary.

1 is an overall block diagram illustrating a health care monitoring system using a smart healthcare mattress according to an embodiment of the present invention, and FIG. 2 is a view illustrating a smart healthcare mattress applied to an embodiment of the present invention. 3 is an overall installation configuration diagram, and FIG. 3 is an overall block configuration diagram for explaining a smart healthcare mattress applied to an embodiment of the present invention, and FIG. 4 is a perspective view of each healthcare sensor module applied to an embodiment of the present invention, and Cross-sectional view, Figure 5 is a block diagram for explaining each health care sensor module applied to an embodiment of the present invention, Figure 6 is a detailed block configuration for explaining a health care control module applied to an embodiment of the present invention 7 is a flow chart for explaining the process of performing the control of the health care control module when each health care sensor module applied to one embodiment of the present invention is formed in a plurality, and FIG. 8 is applied to an embodiment of the present invention. It is a detailed block configuration diagram for describing an external terminal.

1 to 8, the health care monitoring system using a smart healthcare mattress according to an embodiment of the present invention, at least one smart healthcare mattress (1000-1 to 1000-N), and healthcare It comprises a monitoring server 2000 and the like. In addition, the health care monitoring system using a smart healthcare mattress according to an embodiment of the present invention may further include an external terminal (or client terminal) 20 and the like. On the other hand, since the components shown in FIGS. 1 to 8 are not essential, the health care monitoring system using a smart healthcare mattress according to an embodiment of the present invention has more or less components. It might be.

Hereinafter, the components of the health care monitoring system using the smart healthcare mattress according to an embodiment of the present invention will be described in detail as follows.

Each smart healthcare mattress (1000-1 to 1000-N) detects a signal related to the bio-information of a measurement target (eg, a patient, the general public, etc.) existing on the mattress 100 in a non-contact manner and uniquely identifies a preset device. The information is transmitted to the healthcare monitoring server 2000.

Each of these smart health care mattresses 1000-1 to 1000-N is largely as shown in FIGS. 2 to 7, and the mattress 100, at least one health care sensor module 200-1 to 200-N, It comprises a health care control module 300, and the power supply module 400. On the other hand, since the components shown in FIGS. 2 to 7 are not essential, each smart healthcare mattress (1000-1 to 1000-N) applied to an embodiment of the present invention has more or less components. It may have components.

Hereinafter, the components of each smart healthcare mattress 1000-1 to 1000-N applied to one embodiment of the present invention will be described in detail.

The mattress 100 is usually a flat, rectangular mat made of at least one cushion member (eg, spring, sponge, heat insulating material, etc.) laminated inside the outer shell, and is mainly used in the form of laying on a bed frame. It is preferable, but is not limited thereto, and may be, for example, in the form of a mattress topper used for laying on the floor or the main mattress.

Each health care sensor module (200-1 to 200-N) is mounted in a predetermined space portion (A) formed on the cushion member of the mattress 100, and is electrically connected to the health care control module 300, Under the control of the healthcare control module 300, a radar sensor is used to non-contactly detect a signal related to the bio-information of a measurement object existing on the mattress 100.

At this time, the radar sensor is a sensor that transmits electromagnetic waves in a specific direction, for example, may include a millimeter wave radar sensor (mmWave Radar Sensor). The millimeter wave radar sensor is a sensor that uses a frequency between 60 GHz and 70 GHz.

Since the frequencies between 60 GHz and 70 GHz have directivity to focus electromagnetic waves in a specific direction, electromagnetic waves composed of frequencies having the characteristics of such directivity are not affected by other external motions, so that multiple human body biological sensing It may be possible.

For example, when the electromagnetic wave output from the millimeter wave radar sensor compares data (RSS value) of reflected electromagnetic waves reflected by people and objects, objects and people reflect different amounts of objects according to the dielectric constants of objects and people. It can be observed to reflect the amount of electromagnetic waves, and it is possible to distinguish whether the object reflecting the electromagnetic wave is an object or a person through regression analysis on the reflected electromagnetic wave versus the output electromagnetic wave.

Meanwhile, the radar sensor may use an IR-UWB (Impulse-Radio Ultra WideBand) technology that irradiates an ultra-wideband (UWB) impulse signal at a short distance and measures a reflected radio signal.

IR-UWB technology has recently been introduced as a high-accuracy position estimation technology, because IR-UWB uses a very narrow impulse ranging from ns to hundreds of ps, compared to narrowband signals. This is because it has strong characteristics in multi-path.

In addition, the IR-UWB method is a technology that uses a frequency band of several GHZ or more in a base band without using a radio carrier, and is a new radio technology applied to communication or radar. IR-UWB technology has the advantage of using a very narrow pulse of a few nanoseconds or a few picoseconds, which can be implemented with low power and can be used in conjunction with a conventional communication system.

Each of these healthcare sensor modules 200-1 to 200-N, as shown in FIGS. 4 and 5, is largely a radar transmitter 210, a radar receiver 220, a signal processor 230, a PCB substrate portion 240, and PCB protection unit 250, and the like.

Here, the radar transmitting unit 210 performs a function of transmitting a first signal having a radar pulse (Radar Pulse) for the corresponding measurement object existing on the mattress 100.

That is, the radar transmitter 210 transmits a first signal having a radar pulse to a corresponding measurement object existing on the mattress 100, and emits an impulse signal for detection of the measurement object to the outside (Radiation) component, although not shown in the drawing, may typically include an impulse generator (Impulse Generator), a transmit antenna (Transmit Antenna), and a transmission controller (Controller).

Here, the impulse generator may generate an impulse based on data for generating an impulse provided from the transmission control unit. For reference, in a UWB radar, the shorter the pulse period may contain more information. According to the FCC definition, a pulse signal having a pulse width of only several ns is generated, and the bandwidth exceeds 500 MHz or the center frequency. If the contrast bandwidth is more than about 20% to be included in the ultra-wideband (UWB) radar, the impulse generator may generate an impulse meeting this definition.

The transmitting antenna may radiate a pulse signal generated by the impulse generator to the outside, and at this time, a pulse signal may be generated in a preset region. For reference, it is preferable that the transmission antenna is an ultra-wideband antenna having high directivity.

The transmission control unit may provide data for generating an impulse to the impulse generator, and under the control of the transmission control unit, the impulse generator may generate an impulse.

The radar receiver 220 is reflected from the measurement object and performs a function of receiving a second signal related to the first signal.

Although the radar receiving unit 220 is not illustrated in the drawing, it may include a receiving antenna, a receiving controller, and the like.

Here, the receiving antenna may receive a reflected signal of a pulse emitted by the radar transmitter 210, and an ultra-wideband antenna having high directivity may be used.

The reception control unit may analyze a signal received by the reception antenna. The signal received through the receiving antenna includes not only the reflected signal of the measurement target, which is the detection target, but also the reflection signal of the surrounding object, and for accurate measurement of the measurement target, signals other than the object must be removed.

In addition, the reception control unit may include common components, such as an amplification unit, an A/D conversion unit, a D/A conversion unit, a sampling unit, a demodulation unit, and a filter unit, and these components are common radars. Since it is the same as, detailed description thereof will be omitted.

The signal processing unit 230 extracts frequencies based on the first and second signals transmitted and received from the radar transmitter 210 and the radar receiver 220, and signals related to the biometric information of the measurement target according to the phase difference of the frequencies It performs the function of processing.

That is, the signal processing unit 230 may extract a frequency from data of reflected electromagnetic waves and preprocess the phase of the extracted frequency. Here, the data of the reflected electromagnetic wave may include a frequency domain including motion information about a person's breathing or heartbeat. A dominant frequency peak occurs at a frequency extracted from the reflected electromagnetic wave data, and the frequency of the frequency peak may be related to a person's respiratory rate or heart rate.

The signal processing unit 230 converts the data of the reflected electromagnetic wave into the frequency domain through a Fast Fourier Transform (FFT), and the peak value of the frequency in a frequency domain corresponding to a preset frequency range among the converted frequency domains. Detecting and measuring the phase value of the frequency over time using the detected peak value of the frequency.

Specifically, the signal processing unit 230 collects and collects data on a plurality of reflected electromagnetic waves (eg, directly reflected electromagnetic waves, reflected N electromagnetic waves, etc.) that are reflected back when the transmitted electromagnetic waves return. Among the plurality of reflected electromagnetic waves, only data of the same frequency band can be acquired.

Then, the signal processing unit 230 converts the data of a plurality of reflected frequencies of the same frequency band obtained through fast Fourier transform (FFT) into the frequency domain, and extracts frequencies related to respiratory rate and heart rate from the converted frequency domain. can do.

In addition, the signal processing unit 230 may convert the converted frequency domain into a time domain to detect a peak value, and measure a distance between the detected peak values to calculate a correlation coefficient related to the human heart rate.

Also, the signal processing unit 230 may process phase unwrapping on the extracted frequency. For example, the signal processing unit 230 may process phase unwrapping by adding or subtracting 2π from the phase when the phase difference between continuous values is greater than or less than ㅁπ because the phase values are between [-π and π]. have.

In addition, the signal processing unit 230 may process a phase difference (Phase Difference) that subtracts a continuous phase value with respect to the phase where the phase unwrapping is processed. Through the processing of the phase difference, it is possible to improve the accuracy of the human heart rate data and help to eliminate the phase deviation.

In addition, the signal processing unit 230 may determine a person's respiratory rate and heart rate by performing spectrum estimation on a frequency where the phase unwrapping and phase difference are processed.

That is, the signal processing unit 230 generates a correlation expression of the respiration rate with respect to the frequency peak using the frequency related to the extracted respiration rate, and a preset respiration rate frequency range (eg, 0.5 at 0.1 Hz) at a frequency related to the extracted respiration rate. Human respiratory rate may be determined based on the frequency data included in Hz.

In addition, the signal processing unit 230 generates a correlation expression of the heart rate with respect to the frequency peak using the frequency associated with the extracted heart rate, and in a preset heart rate frequency range (for example, between 0.8 Hz and 4.0 Hz) at a frequency related to the extracted heart rate. A human heart rate may be determined based on the data of the included frequencies.

The PCB substrate unit 240 is equipped with a radar transmitter 210, a radar receiver 220, and a signal processor 230 on the predetermined printed circuit board (PCB), as well as an electronic circuit element required for a radar sensor, and health. The data cable C for sensor communication and power supply with the care control module 300 is electrically connected.

The PCB protection unit 250 is molded so that the entire outer surface of the PCB substrate portion 240 is wrapped through an injection molding method of liquid silicone for waterproofing and impact prevention of the PCB substrate portion 240.

The health care control module 300 performs overall control of each smart health care mattress (1000-1 to 1000-N) applied to an embodiment of the present invention, in particular, each health care sensor module (200-1 to 200) -N) receiving a signal related to the bio-information of the target to be measured, and controlling the function to be transmitted to the healthcare monitoring server 2000 through wired and/or wireless communication method with unique device identification information that has been set. Perform.

At this time, the predetermined unique device identification information, for example, the name of the smart healthcare mattress, the password of the smart healthcare mattress, the serial number of the smart healthcare mattress, the type of the smart healthcare mattress, the manufacturer of the smart healthcare mattress , MAC address of smart healthcare mattress, IP address of smart healthcare mattress, Internet Protocol (IP) address, model of smart healthcare mattress and version of smart healthcare mattress, secret key or smart key of smart healthcare mattress It is preferable to include at least one of the authentication information of the smart healthcare mattress generated by the base private key.

6, the healthcare control module 300 includes a main body 301, a cable connector 302, a communication unit 303, a control unit 304, and a power supply unit 305 as shown in FIG. 6. Is done by In addition, the healthcare control module 300 applied to an embodiment of the present invention includes a storage unit 306, a display unit 307, a radon measurement unit 308, a fine dust detection unit 309, an ultra fine dust detection unit 310, a temperature measurement unit 311, a humidity measurement unit 312, a carbon monoxide detection unit 313, and/or a carbon dioxide detection unit 314, and the like. On the other hand, since the components shown in FIG. 6 are not essential, the healthcare control module 300 applied to an embodiment of the present invention may have more components or fewer components.

Hereinafter, the components of the healthcare control module 300 applied to an embodiment of the present invention will be described in detail.

The body portion 301 is installed to be spaced apart from the mattress 100 at a predetermined distance, and forms a whole body in a box shape. On one side thereof, a measurement suction port 301-a for sucking external air is formed. , On the other side, a measurement outlet (301-b) for discharging internal air is formed.

The cable connector 302 is provided to be exposed to the outside of the body portion 301, and is electrically connected to a data cable C connected to the PCB substrate portion 240.

The communication unit 303 performs a function of transmitting unique device identification information in a wired and/or wireless communication method along with a signal related to the bio-information of the corresponding measurement object existing on the mattress 100.

Also, the communication unit 303 transmits unique device identification information along with at least one of health status information of the target breathing, heart rate, movement, distance, sleep, and/or condition to wired and/or wireless communication methods. It can perform the function of transmitting.

Also, the communication unit 303 wires and measures at least one healthcare environment measurement value of the radon measurement value, the fine dust concentration value, the ultrafine dust concentration value, the temperature value, the humidity value, the carbon monoxide concentration value, and/or the carbon dioxide concentration value. Alternatively, a function of transmitting in a wireless communication method may be performed.

The communication unit 303 is preferably implemented to be wired and/or wirelessly communicated through the communication network 10, but is not limited thereto, and the wireless communication method is, for example, Bluetooth communication, ZigBee communication, UWB (Ultra Wideband) communication, RFID (Radio Frequency Identification) communication, or infrared (IR) communication may be implemented to be any one of the short-range wireless communication.

At this time, the communication network 10 is a communication network that is a high-speed period network of a large-scale communication network capable of high-capacity, long-distance voice and data services, and is provided with Wi-Fi, WiGig to provide Internet or high-speed multimedia services. It may be a next-generation wireless communication network including WiBro (Wireless Broadband Internet, Wibro), WiMax (World Interoperability for Microwave Access, Wimax), and the like.

The Internet is a TCP/IP protocol and various services existing in a higher layer, namely, Hyper Text Transfer Protocol (HTTP), Telnet, File Transfer Protocol (FTP), Domain Name System (DNS), Simple Mail Transfer Protocol (SMTP), Refers to a global open computer network structure that provides Simple Network Management Protocol (SNMP), Network File Service (NFS), Network Information Service (NIS), etc., and the communication unit 303 is an external terminal 20 and/or health. It provides an environment that allows access to the care monitoring server 2000. Meanwhile, the Internet may be a wired or wireless Internet, or may be a core network integrated with a wired public network, a wireless mobile communication network, or a portable Internet.

If the communication network 10 is a mobile communication network, it may be a synchronous mobile communication network or an asynchronous mobile communication network. An example of the asynchronous mobile communication network is a wideband code division multiple access (WCDMA) communication network. In this case, although not shown in the drawings, the mobile communication network may include, for example, a radio network controller (RNC). Meanwhile, although the WCDMA network is taken as an example, it may be a next-generation communication network such as a cellular-based 3G network, an LTE network, a 4G network, a 5G network, or an IP network based on other IPs. The communication network 10 transmits signals and data to and from the communication unit 303 of each smart healthcare mattress 1000-1 to 1000-N and the external terminal 20 and/or healthcare monitoring server 2000. Play a role.

In addition, the control unit 304 is provided inside the main body 301, and performs overall control of the healthcare control module 300 applied to an embodiment of the present invention, in particular the cable connector 302. The operation of the communication unit 303 so as to receive a signal related to the bio-information of the corresponding measurement target transmitted through this and transmit the unique device identification information previously set to the healthcare monitoring server 2000 and/or the external terminal 20 It performs the function of controlling.

In addition, the control unit 304 receives a signal related to the bio-information of the measurement object transmitted through the cable connector 302, and based on this, the breathing, heart rate, movement, distance, sleep, and/or condition of the measurement object After analyzing at least one of the health status information, the health status information analyzed for each health status is converted into a database (DB), controlled to be stored and managed in a separate storage unit 306, and the user is visualized. A function of controlling the operation of the separate display unit 307 to be displayed on the display screen so as to be confirmed may be performed.

In addition, the control unit 304 receives a signal related to the bio-information of the measurement object transmitted through the cable connector 302, and based on this, the breathing, heart rate, movement, distance, sleep, and/or condition of the measurement object After analyzing at least one of the health status information, the unique device identification information set together with the health status information analyzed for each health status is the health care monitoring server 2000 and/or the external terminal 20. It may perform a function of controlling the operation of the communication unit 303 to be transmitted to.

In addition, in the control unit 304, when each healthcare sensor module 200-1 to 200-N is formed in plural, as shown in FIG. 7 (unless otherwise specified, the control unit 304 is mainly performed) , Receiving the final measurement value from each health care sensor module 200-1 to 200-N (eg, sensors 1 to sensor n) through the cable connector 302, based on this, each health care sensor module 200-1 To 200-N), the distance information from the measurement target is extracted from the final measurement value (that is, distance information is extracted for each sensor).

Thereafter, the control unit 304 determines whether the sensor measurement value is an effective value. That is, when it is determined that the final measurement value of each healthcare sensor module 200-1 to 200-N is a preset measurement valid value, it is determined whether it is close to a recent measurement distance.

That is, the control unit 304, the distance value between the corresponding measurement object extracted from each health care sensor module (200-1 to 200-N) determined as the preset measurement valid value and the distance value between the previously stored measurement object When the difference is determined to be equal to or less than a preset reference distance difference value, that is, the final measurement value of the healthcare sensor modules 200-1 to 200-N close to the recent measurement distance is sent to the healthcare monitoring server 2000. A function of controlling the operation of the communication unit 303 to be transmitted may be performed.

In addition, the control unit 304, the distance value between the corresponding measurement object extracted from each health care sensor module (200-1 to 200-N) determined as the preset measurement valid value and the previously stored distance value between the measurement object When the difference is determined to be equal to or less than a preset reference distance difference value, that is, breathing of the measurement target based on the final measurement value of the health care sensor modules 200-1 to 200-N close to the recent measurement distance, It may perform a function of analyzing health status information of at least one of heart rate, movement, distance, sleep, and/or condition.

Meanwhile, in the control unit 304, the distance value between the corresponding measurement object extracted from each healthcare sensor module 200-1 to 200-N determined as the preset measurement valid value and the distance value between the previously stored measurement object When the difference is determined to be greater than or equal to a preset reference distance difference value, that is, the movement of the measurement object based on the final measurement value of the health care sensor modules 200-1 to 200-N that are not close to the recent measurement distance Judge whether or not.

Then, when the control unit 304 determines that the final measurement value of the health care sensor modules 200-1 to 200-N that are not close to the recent measurement distance is the movement of the corresponding measurement object, it determines whether it is close to the recent measurement value. do.

That is, the control unit 304 compares the last measured value of the health care sensor modules 200-1 to 200-N that are not close to the last measured distance and the last measured value of the previously stored health care sensor module, and the difference is preset. When it is determined that the reference approximation is less than or equal to the reference value, a function of controlling the operation of the communication unit 303 is performed so that the final measurement values of the corresponding healthcare sensor modules 200-1 to 200-N are transmitted to the healthcare monitoring server 2000. Can.

In addition, the control unit 304 compares the last measurement value of the health care sensor modules 200-1 to 200-N that are not close to the last measurement distance and the last measurement value of the recently stored health care sensor module, and the difference is preset. If it is determined to be less than or equal to a reference approximation value, based on the final measurement values of the corresponding healthcare sensor modules 200-1 to 200-N, at least one of breath, heart rate, movement, distance, sleep, and/or condition of the measurement object It can perform a function of analyzing one health condition information.

On the other hand, the control unit 304 compares the last measurement value of the health care sensor modules 200-1 to 200-N that are not close to the last measurement distance and the last measurement value of the recently stored health care sensor module, and the difference is preset. When it is judged that it is more than the reference approximation value, the sensor sensor outputs the least converted value, that is, the health care sensor module having the smallest difference among the final measurement values of the corresponding health care sensor modules 200-1 to 200-N. A function of controlling the operation of the communication unit 303 may be performed so that the final measurement values (200-1 to 200-N) are transmitted to the healthcare monitoring server 2000.

In addition, the control unit 304 compares the last measurement value of the health care sensor modules 200-1 to 200-N that are not close to the last measurement distance and the last measurement value of the recently stored health care sensor module, and the difference is preset. When it is judged that it is more than the reference approximation value, the sensor sensor outputs the least converted value, that is, the health care sensor module having the smallest difference among the final measurement values of the corresponding health care sensor modules 200-1 to 200-N. Based on the final measurement value of (200-1 to 200-N) to perform the function of analyzing at least one health care status information of the respiratory, heart rate, movement, distance, sleep, and / or condition of the measurement target Can.

In addition, the control unit 304 transmits the health care status information analyzed for each health care status to the external terminal 20 and/or the health care monitoring server 2000 through a wired and/or wireless communication method through the communication network 10. A function of controlling the operation of the communication unit 303 to be transmitted may be performed.

In addition, the control unit 304 receives the alpha particle concentration value calculated from the radon measurement unit 308 and based on this, the radon measurement value in the air existing around the mattress 100 is numerically quantified, and unique preset device identification information. In addition, it is possible to perform a function of controlling the operation of the communication unit 303 to be transmitted to the external terminal 20 and/or the healthcare monitoring server 2000 by wired and/or wireless communication methods through the communication network 10. .

In addition, the control unit 304 can be stored and managed in a separate storage unit 306 by converting the digitized radon measurement value into an hourly and/or daily and/or weekly and/or weekly and/or monthly database (DB). In addition to the control box, a function of controlling to be displayed on the display screen of the separate display unit 307 can be performed so that the user can visually confirm the display.

In addition, the control unit 304, the fine dust concentration value and / or ultra-fine dust in the air present in the vicinity of the mattress 100, respectively detected from the fine dust detection unit 309 and / or the ultra-fine dust detection unit 310 The communication unit 303 so that the concentration value is digitized and transmitted to the external terminal 20 and/or the health care monitoring server 2000 through a wired and/or wireless communication method through the communication network 10 together with the preset unique device identification information. ) Can perform the function of controlling the operation.

In addition, the control unit 304 stores the digitized fine dust concentration value and/or ultrafine dust concentration value hourly and/or daily and/or weekly and/or weekly and/or monthly in a database (DB) to be stored separately. In addition to controlling to be stored and managed in the unit 306, a function of controlling to be displayed on the display screen of the separate display unit 307 can be performed so that the user can visually confirm the information.

In addition, the control unit 304 numerically measures the temperature value and/or humidity value respectively measured from the temperature measurement unit 311 and/or the humidity measurement unit 312 to establish the communication network 10 with unique device identification information. Through the wired and / or wireless communication method may perform a function of controlling the operation of the communication unit 303 to be transmitted to the external terminal 20 and / or health care monitoring server 2000.

In addition, the control unit 304 converts the digitized temperature and/or humidity values into a database (DB) for each hour and/or daily and/or day and/or weekly and/or monthly to a separate storage unit 306. In addition to controlling to be stored and managed, a function of controlling to be displayed on the display screen of the separate display unit 307 can be performed so that the user can visually check it.

In addition, the control unit 304 is a carbon monoxide detection unit 313 and / or carbon dioxide detection unit 314 by detecting the carbon monoxide concentration value and / or carbon dioxide concentration value in the air present in the vicinity of the mattress 100, respectively Controlling the operation of the communication unit 303 to be transmitted to the external terminal 20 and/or the healthcare monitoring server 2000 by wired and/or wireless communication method through the communication network 10 along with the unique device identification information set. Can perform a function.

In addition, the controller 304 converts the digitized carbon monoxide concentration value and/or carbon dioxide concentration value into a database (DB) for each hour and/or daily and/or day of the week, and/or weekly and/or monthly to separate storage unit 306 ) And can be controlled to be displayed on the display screen of the separate display unit 307 so that the user can visually check it.

The various embodiments described herein can be implemented in a computer- or similar device-readable recording medium using, for example, software, hardware, or a combination thereof.

According to a hardware implementation, the embodiments described herein include application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs) , It can be implemented using at least one of processors, controllers, micro-controllers, microprocessors, and electrical units for performing functions. In some cases, such embodiments may be implemented by the control unit 304.

According to a software implementation, embodiments such as procedures or functions can be implemented with separate software modules that perform at least one function or operation. The software code can be implemented by software applications written in the appropriate programming language. Further, the software code is stored in the storage unit 306, and can be executed by the control unit 304.

In addition, the power supply unit 305 is provided inside the body unit 301, and the above-described respective units, that is, the communication unit 303, the control unit 304, the storage unit 306, the display unit 307, radon measurement Part 308, fine dust detector 309, ultrafine dust detector 310, temperature measuring unit 311, humidity measuring unit 312, carbon monoxide detector 313, and/or carbon dioxide detector ( 314) to perform the function of supplying the power required for each health care sensor module (200-1 to 200-N) through the cable connector 302, as well as the power required for commercial bar (AC) for continuous power supply ) It is desirable to implement a power source (eg, AC 220V) to be converted into a direct current (DC) and/or alternating current (AC) power source, but is not limited thereto, and may be implemented including a conventional portable battery.

Additionally, the storage unit 306 is electrically connected to the control unit 304, and unique device identification along with a signal related to the bio-information of the corresponding measurement object existing on the mattress 100 under the control of the control unit 304. It performs the function of storing information.

In addition, the storage unit 306 performs a function of storing health status information of at least one of breath, heart rate, movement, distance, sleep, and/or condition of the measurement target.

The storage unit 306 may include, for example, a flash memory type, hard disk type, multimedia card micro type, or card type memory (for example, SD or XD memory) Etc.), RAM (Random Access Memory, RAM), SRAM (Static Random Access Memory), ROM (Read-Only Memory, ROM), EEPROM (Electrically Erasable Programmable Read-Only Memory), PROM (Programmable Read-Only Memory), A storage medium of at least one type of magnetic memory, magnetic disk, or optical disk may be included.

The display unit 307 is electrically connected to the control unit 304 and under the control of the control unit 304, at least one health care among breath, heart rate, movement, distance, sleep, and/or condition of the corresponding measurement object It performs the function of visually displaying status information.

The display unit 307 includes, for example, a liquid crystal display (LCD), a light emitting diode display (LED), a thin film transistor liquid crystal display (Thin Film Transistor-Liquid Crystal Display, TFT LCD), an organic light emitting diode (Organic Light Emitting Diode, OLED), Flexible Display, Plasma Display Panel (PDP), Surface Alternating Lighting (ALiS), Digital Light Source Processing (DLP), Silicon Liquid Crystal (LCoS), Surface Conduction Type electron-emitting device display (SED), field emission display (FED), laser TV (quantum dot laser, liquid crystal laser), photoelectric liquid display (FLD), interferometric modulator display (iMoD), thick film dielectric electricity (TDEL), It may include at least one of a quantum dot display (QD-LED), a telescopic pixel display (TPD), an organic light emitting transistor (OLET), a laser fluorescent display (LPD), and a three-dimensional display (3D display), but is not limited thereto. As long as it can display information related to healthcare, it can include anything.

In addition, the radon measurement unit 308 is provided inside the body unit 301, and sucks external air through the measurement intake port 301-a to detect alpha particles in the air in real time to detect a predetermined alpha particle detection signal. A function of outputting, counting for a preset measurement time based on the output alpha particle detection signal, calculating an alpha particle concentration value, and then discharging the internal air of the body portion 301 through the measurement outlet 301-b To perform.

The radon measurement unit 308 is a sensor unit for measuring radon concentration data for the periphery of the mattress 100, and is preferably made of, for example, an ionization chamber type radon measurement sensor, but is not limited thereto. As a device for detecting particles, a surface barrier type, a high-purity semiconductor detector (pure Ge), a scintillation detector, and a solid state junction counter may be applied.

That is, the radon measurement sensor of the ionized chamber (pulsed ionization chamber) is a structure in which a probe-shaped electrode is installed in the center of a metal cylindrical box and a bias voltage is applied between the metal cylinder and the inner probe to form an electric field.

When the alpha decay occurs inside the ionization chamber and the alpha particles are released, the alpha particles are extinguished due to collision with the air, but ionic charge is generated, so that they can be absorbed through the central probe and amplify the signal to detect the alpha particles. The sensor itself is composed of a metal cylinder and a probe, so it is very inexpensive, durable, and irrespective of light.

Looking at the surface barrier type detector, the surface of the semiconductor is formed with a depletion layer such as a p-n junction due to a surface level or an oxide film, so that the vicinity of the surface is an obstacle to charge transfer. As a practical example, gold is deposited on the surface of the n-type si at about 100 µm/cm 2 to make it one electrode, and radiation is incident on the back surface. Here, the thickness of the depletion layer is about 50 to 500 μm, and there are various types, and since energy loss on the surface is small, it is mainly used for detection of charged particles generated by alpha radiation and has good energy resolution.

The high purity semiconductor detector is also generally referred to as a pure Ge detector. It is a high-purity Ge crystal with very little impurity concentration or defects. It has a very high electrical resistance at low temperatures and a high bias voltage. The difference from Ge(Li) is that it can be stored at room temperature and cooled down with liquid nitrogen only for measurement, so it is easy to maintain and its energy resolution is inferior to Ge(Li).

Looking at the scintillation detector, it has been known for a long time that charged particles emit light when they hit a certain substance, but the emission by alpha radiation of zinc emulsion (ZnS) or NaI coating is particularly strong, and detection and counting are possible with a magnifier in the dark.

Such luminescence is called scintillation, and a substance exhibiting this phenomenon is called scintillator. The combination of a photomultiplier tube with a scintillator is called a scintillation detector, but a method used for counting as a pulse output is called a scintillation counter.

On the other hand, the method that reads the output in direct current is mainly used for dosimetry and uses a scintillator, so it is called a scintillation dosimeter, and any solid, liquid, or gas is used in the scintillator. It says.

The solid junction counter is a solid reverse-biased p-n junction semiconductor that can be manufactured in a compact and mobile form with a counter designed to collect ionic charges from alpha particles passing through a depletion layer.

In addition, the fine dust detection unit 309 is provided inside the body unit 301, and after detecting the concentration of fine dust in the air by inhaling external air through the measurement inlet (301-a), the body unit 301 ) Performs the function of discharging the internal air through the measurement outlet (301-b).

The fine dust detector 309 is a sensor for measuring fine dust having a particle diameter of about 10 μm or less, for example, measuring air pollutants of at least one of sulfur dioxide, nitrogen oxide, lead, ozone, and/or carbon monoxide. It may include at least one fine dust sensor.

In addition, the ultra-fine dust detection unit 310 is provided inside the main body 301, and after inhaling external air through the measurement intake 301-a to detect the ultra-fine dust concentration in the air, the main body It performs the function of discharging the internal air of the (301) through the measurement outlet (301-b).

The ultra-fine dust detector 310 is a detector for measuring ultra-fine dust having a particle diameter of about 2.5 μm or less, for example, at least one measuring total carbon, organic carbon, and elemental carbon contained in the ultra-fine dust. It may be made, including ultra-fine dust sensor.

In addition, the temperature measuring unit 311 is installed to be exposed on the PCB protection unit 250 or is installed inside/outside of the body unit 301, each of the health care sensor module (200-1 to 200-N) It performs a function of measuring the temperature of the surroundings and/or the surroundings of the healthcare control module 300.

The temperature measuring unit 311 is a sensor unit for measuring the temperature in the air, and a thermistor element whose internal resistance value changes according to a change in ambient temperature may be used. The thermistor element may be a negative characteristic thermistor (NTC thermister), a positive characteristic thermistor (PTC thermistor), or a critical characteristic thermistor (CRT).

The temperature measurement unit 311 is preferably configured as a contact temperature sensor using a thermistor element, but is not limited thereto, and may be, for example, a thermocouple sensor, a bimetal, an IC temperature sensor, and a non-contact infrared sensor.

In addition, the humidity measurement unit 312 is installed to be exposed on the PCB protection unit 250 or is installed inside/outside of the body unit 301, each of the health care sensor module (200-1 to 200-N) It performs a function of measuring humidity for the surroundings and/or the surroundings of the healthcare control module 300.

The humidity measuring unit 312 is a sensor unit for measuring humidity in the air, and usually measures humidity using a change in electrical properties of a moisture-sensitive material due to moisture.

The humidity measurement unit 312 can be largely divided into a resistance humidity sensor and a capacitive humidity sensor, and in order to make automobiles and medical devices, air purification systems, and automatic heating and cooling systems in an optimal state, as well as home appliances and mobiles. It is widely applied.

The resistance-type humidity sensor measures humidity using a change in resistance caused by humidity. This resistive humidity sensor has been used a lot because it has a relatively competitive price compared to a capacitive humidity sensor.

However, in recent years, as the capacitive humidity sensor can be manufactured in the form of a one chip on a semiconductor substrate, it is possible to secure a price competitive advantage over the resistive humidity sensor, and thus the usage is increasing. In particular, the capacitive humidity sensor has the advantage of being superior in reliability compared to the resistive humidity sensor, but having a linear sensor characteristic and little influence of temperature.

Such a capacitive humidity sensor is a sensor using a principle in which the capacitance changes according to the molecular weight of water adsorbed on a moisture absorbing film, and absorbs moisture such as polyimide or ceramic, whose dielectric constant changes when moisture is absorbed. It operates in the form of a capacitor made of dielectric material. In other words, there is a moisture-sensitive layer that detects humidity, and it is a principle that detects that the dielectric constant changes and the capacitance changes accordingly as moisture enters through the moisture-sensitive layer.

In addition, the carbon monoxide detection unit 313 is provided inside the main body 301, and after detecting the concentration of carbon monoxide (CO) in the air by inhaling external air through the measurement intake 301-a, the main body ( 301) performs the function of discharging the internal air through the measurement outlet (301-b).

In addition, the carbon dioxide detector 313 is provided inside the body portion 301, and after detecting the concentration of carbon dioxide (CO ₂ ) in the air by inhaling external air through the measurement inlet 301-a, the body portion It performs the function of discharging the internal air of the (301) through the measurement outlet (301-b).

The power supply module 400 performs the functions of supplying power required for each of the modules described above, that is, each of the health care sensor modules 200-1 to 200-N, and the health care control module 300, and so on. It is preferable to implement commercial AC (AC) power (eg, AC 220V) to be converted to DC (DC) and/or AC (AC) power for the purpose of supplying power, but is not limited thereto. ).

In addition, the power supply module 400 may include a power management unit (not shown) that protects parts from external power shock and outputs a constant voltage. The power management unit may include an ESD (Electro Static Damage) protector, a power detector, a rectifier, and a power breaker.

Here, the ESD protector is configured to protect the electric components from static electricity or sudden power shock. The power detector is configured to send a cut-off signal to the power breaker when a voltage outside the allowable voltage range flows, and transmit a boost or step-down signal to the rectifier according to a voltage change within the allowable voltage range. The rectifier is configured to perform a step-up or step-down rectification operation according to the signal of the power detector so that a constant voltage is supplied by minimizing the variation of the input voltage. The power breaker is configured to cut off power supplied from a battery according to a cutoff signal transmitted from the power detector.

And, the healthcare monitoring server 2000 is connected to each smart healthcare mattress (1000-1 to 1000-N) and/or external terminals (or client terminals) 20 through the communication network 10, each By receiving unique device identification information along with signals related to the bio-information of the corresponding measurement object transmitted from the smart healthcare mattress (1000-1 to 1000-N), based on this, breathing of the corresponding measurement object for each smart healthcare mattress, After analyzing at least one health condition information of heart rate, movement, distance, sleep, and/or condition, each health care condition information analyzed for each smart health care mattress is converted into a database (DB) In addition to storage and management, it performs a function of providing a service so that an administrator can visually monitor the health status of the measurement target in real time.

At this time, the breath (normal/high/low), heart rate (normal/high/low), movement (normal/active/small), distance (normal/active/small), sleep (normal/sleep excessive/sleep) Lack), and/or analysis of health condition information such as condition (stable/unstable) condition may be performed through a normal pattern analysis.

In addition, the health care monitoring server 2000 is sent to each smart healthcare mattress (1000-1 to 1000) from the communication unit 303 of each smart healthcare mattress (1000-1 to 1000-N) through a pre-installed healthcare-related application. 1000-N) received unique device identification information along with radon measurement values in the air, and based on this, by using the circular and/or bar graph, hourly and/or daily and/or weekly And/or current radon measurements, average radon measurements, and/or preset reference radon measurements in the air present around each smart healthcare mattress (1000-1 to 1000-N) on a weekly and/or monthly basis. It is possible to perform a function of providing a monitoring service so that at least one radon measurement value of the comparison radon measurement value is displayed in real time on a display screen.

In addition, the health care monitoring server 2000 may measure at least one radon measurement value of the current radon measurement value of each smart healthcare mattress, an average radon measurement value, or a comparison radon measurement value with a preset reference radon measurement value by time and/or Alternatively, a function of providing a service to be stored and managed in a separate storage device (not shown) by performing a database (DB) by day and/or by day and/or by week and/or month may be performed.

In addition, the health care monitoring server 2000 is sent to each smart healthcare mattress (1000-1 to 1000) from the communication unit 303 of each smart healthcare mattress (1000-1 to 1000-N) through a pre-installed healthcare-related application. 1000-N) is provided with unique device identification information along with the fine dust concentration value and/or the ultrafine dust concentration value in the air around it, and based on this, using the circular and/or bar graph Measurement of current fine dust and/or ultrafine dust concentrations in the air present around each smart healthcare mattress (1000-1 to 1000-N) hourly and/or daily and/or weekly and/or weekly and/or monthly At least one of a value, an average fine dust and/or ultra fine dust concentration measurement, and/or a comparison with a preset reference fine dust and/or ultra fine dust concentration measurement. It is possible to perform a function of providing a monitoring service so that the concentration measurement value is displayed in real time on a display screen.

In addition, the health care monitoring server 2000 may measure current fine dust and/or ultrafine dust concentrations, average fine dust and/or ultrafine dust concentrations, and/or preset reference fine dust for each smart healthcare mattress. And/or comparison with the ultrafine dust concentration measurement. The concentration measurement of at least one of the fine dust and/or ultrafine dust concentration measurements is hourly and/or daily and/or day and/or weekly and/or monthly. (DB) can be performed to provide a service to be stored and managed in a separate storage device (not shown).

In addition, the health care monitoring server 2000, each health care sensor module (200-1 to) transmitted from the communication unit 303 of each smart health care mattress (1000-1 to 1000-N) through a pre-installed health care-related application 200-N), and/or unique device identification information along with temperature and/or humidity values for the periphery of the health care control module 300, and based on this, circular and/or bar according to the administrator's request Current temperature and/or humidity readings, average temperature and/or humidity readings, and/or preset reference temperatures and/or hourly and/or daily and/or weekly and/or weekly and/or monthly using graphs It is possible to perform a function of providing a monitoring service so that at least one of the measured temperature and/or humidity measurement value is compared with the humidity measurement value on a display screen in real time.

In addition, the health care monitoring server 2000 compares the current temperature and/or humidity measurement value, average temperature and/or humidity measurement value, and/or a preset reference temperature and/or humidity measurement value for each smart healthcare mattress. Store and manage at least one of temperature and/or humidity measurements by database (DB) by hour and/or daily and/or weekly and/or weekly and/or monthly It is possible to perform a function of providing a service.

In addition, the health care monitoring server 2000 is sent to each smart healthcare mattress (1000-1 to 1000) from the communication unit 303 of each smart healthcare mattress (1000-1 to 1000-N) through a pre-installed healthcare-related application. 1000-N) received unique device identification information along with carbon monoxide concentration value and/or carbon dioxide concentration value for the periphery, and based on this, by using the circular and/or bar graph, hourly and/or daily and And/or weekly and/or weekly and/or monthly current carbon monoxide and/or carbon dioxide concentration measurements, average carbon monoxide and/or carbon dioxide concentration measurements, and/or comparison with preset reference carbon monoxide and/or carbon dioxide concentration measurements And/or providing a monitoring service so that at least one concentration measurement value of the carbon dioxide concentration measurement value is displayed in real time on a display screen.

In addition, the health care monitoring server 2000 may measure current carbon monoxide and/or carbon dioxide concentrations for each smart healthcare mattress, average carbon monoxide and/or carbon dioxide concentration measurement values, and/or preset reference carbon monoxide and/or carbon dioxide concentration measurement values. Comparing with the carbon monoxide and/or carbon dioxide concentration measured at least one concentration measured hourly and / or daily and / or day and / or weekly and / or monthly database (DB) to a separate storage device (not shown) ) Can be stored and managed to provide a service.

In addition, the health care monitoring server (2000), each pre-installed health care-related application through each smart health care mattress, each health status information of the corresponding measurement target (eg, breathing, heart rate, movement, distance, sleep, condition) Etc.) using the pie and/or bar graphs according to the administrator's needs, hourly and/or daily and/or weekly and/or weekly and/or monthly, current status measurements, average status measurements, and/or presets Comparison with the reference state measurement value It is possible to perform a function of providing a monitoring service so that at least one state measurement value among the state measurement values is displayed in real time on a display screen.

In addition, the health care monitoring server 2000 is configured to set at least one current health care state measurement value of breath, heart rate, movement, distance, sleep, and/or condition state of the corresponding measurement object analyzed for each smart health care mattress. When each reference state measurement value is exceeded, a health care warning message corresponding to the current health care state measurement value may be provided to provide a service so that the corresponding manager can audibly and/or visually check the health care warning message.

In addition, the health care monitoring server 2000 is configured to set at least one current health care state measurement value of breath, heart rate, movement, distance, sleep, and/or condition state of the corresponding measurement object analyzed for each smart health care mattress. When each reference state measurement value is exceeded, a health care warning message corresponding to the current health care state measurement value is audible and/or visually measured by the corresponding measurement object of each smart healthcare mattress (1000-1 to 1000-N). To provide a service to be transmitted to a separate voice output unit (for example, a speaker, etc.) (not shown) and/or the display unit 307 connected to each smart healthcare mattress (1000-1 to 1000-N) so that it can be checked with Can perform a function.

In addition, the healthcare monitoring server 2000 may perform a function of providing a cloud computing service in response to a request from the external terminal (or client terminal) 20 through the communication network 10.

That is, the healthcare monitoring server 2000 is connected to a plurality of terminals 20 possessed by an administrator on a network through a communication network 10, and provides system resources (which are OS, CPU, memory, storage devices) to the plurality of terminals 20. It is a physical device providing a), in a cloud service environment, a plurality of servers are connected to a plurality of terminals 20 on a network, and the healthcare monitoring server 2000 includes a plurality of servers. It is shown as a concept, for example, a plurality of terminals 20 are distributed to use system resources through a guest machine on a virtual space created through virtualization technology. These may be understood as well-known general concepts.

At this time, the cloud (Cloud) service environment means an Internet-based (cloud) computing technology. The cloud computing is a cloud representation of the Internet in a computer network configuration diagram, has a hidden complex infrastructure structure, and has a computing style in which IT-related functions are provided as a service. Users can use services provided from cloud computing using the Internet.

In addition, the cloud computing is a mixture of various computing concepts and communication technologies such as virtualized computing, utility computing, and on-demand computing, and a virtualization technology for a plurality of data centers, typically composed of multiple computers. It refers to a technology that integrates into and implements one virtual computer or service, and provides various software, security solutions, and computing capabilities, etc., on-demand by users accessing them.

That is, the cloud computing is an'on-demand outsourcing service of IT resources through the Internet', and stores programs or documents individually stored on a personal computer or a corporate server in an Internet-based virtual server or storage. And, by using a variety of terminals, including personal computers, by running a cloud application (Application) such as a web browser, it is a method that allows the user to perform the desired task.

At this time, users can select and use as many cloud computing resources as cloud applications, storage, OS, and security at a desired time, and pay for them based on usage.

The healthcare monitoring server 2000 as described above may perform a function of providing a cloud computing service in response to a request from at least one external terminal 20.

That is, the healthcare monitoring server 2000 is a server that provides a cloud computing service to at least one external terminal 20, and the computing resource requested by the at least one external terminal 20 is transmitted through the communication network 10. Provide. The healthcare monitoring server 2000 may provide a computing service for using at least one external terminal 20 to request a device.

The healthcare monitoring server 2000 includes, for example, an application program file, a game program file, a text data file, a document file, a picture file, a music file, a video file, and a bar code file provider that provides a large amount of data. It has a plurality of storage devices for storing the provided files, that is, Storage (Storage).

In addition, the health care monitoring server 2000 stores at least one health care state information of breath, heart rate, movement, distance, sleep, and/or condition of the corresponding measurement object analyzed for each smart health care mattress database (DB). When it is stored and stored, it encrypts at least one health care status information of breath, heart rate, movement, distance, sleep, and/or condition of the corresponding measurement object analyzed for each smart health care mattress using a symmetric or asymmetric encryption method In addition to the storage box, a decryption key that can decrypt at least one health care state information of breath, heartbeat, movement, distance, sleep, and/or condition of the corresponding measurement target for each of the encrypted smart health care mattresses is external. A function of providing a service to be transmitted to the terminal 20 may be performed.

In addition, the health care monitoring server 2000, through the external terminal 20, at least one health care state of breath, heart rate, movement, distance, sleep, and/or condition of the corresponding measurement object for each smart health care mattress A function of providing a cloud web service so that information can be downloaded can be performed.

In addition, the external terminal 20 uses the client member login cloud web service of the healthcare monitoring server 2000 to breathe the corresponding measurement object analyzed and stored for each smart healthcare mattress on the healthcare monitoring server 2000, It is possible to perform a function of real-time searching and displaying on the display screen at least one health status information of heart rate, movement, distance, sleep, and/or condition.

In addition, the external terminal 20 uses the decryption key transmitted from the health care monitoring server 2000 together with the corresponding client member login information to measure the corresponding smart health care mattresses encrypted and stored in the health care monitoring server 2000. It may perform a function of decoding at least one health care state information of a subject's breathing, heart rate, movement, distance, sleep, and/or condition, and displaying it on a real-time search and display screen.

In addition, the external terminal 20 through the healthcare-related application downloaded from the healthcare monitoring server 2000, the respiratory, heart rate, movement of the corresponding measurement target for each smart healthcare mattress stored in the healthcare monitoring server 2000, It is possible to perform a function of real-time searching and displaying on the display screen at least one health condition information among distance, sleep, and/or condition.

In addition, the external terminal 20 receives the analyzed health care status information for each health care status transmitted from the communication unit 303 and the communication network 10 through a pre-installed health care-related application, and based on this, receives the user's request. Depending on the time and/or daily and/or day of the week and/or weekly and/or monthly, use the pie and/or bar graph to compare the current status measurements, average status measurements, and/or preset reference status measurements A function of controlling at least one of the state measurement values to be displayed on the display screen may be performed.

In addition, the external terminal 20 receives a radon measurement value in the air existing in the vicinity of the mattress 100 transmitted from the communication unit 303 and the communication network 10 through a pre-installed healthcare-related application based on this Current radon measurements, average radon measurements, and/or preset reference radon measurements hourly and/or daily and/or weekly and/or weekly and/or monthly using circular and/or bar graphs as required by A function of controlling at least one radon measurement value to be displayed on a display screen may be performed.

In addition, the external terminal 20 is a fine dust concentration value and/or ultra-fine dust in the air existing around the mattress 100 transmitted from the communication unit 303 and the communication network 10 through a pre-installed healthcare-related application. Based on the concentration value, the current fine dust and/or ultrafine dust concentration can be obtained by hourly and/or daily and/or weekly and/or weekly and/or monthly using a circular and/or bar graph according to the user's needs. At least one of the measured value, the average fine dust and/or ultrafine dust concentration measurement value, and/or the comparison with the preset reference fine dust and/or ultrafine dust concentration measurement value. It is possible to perform a function of controlling the concentration measurement value of to be displayed on the display screen.

In addition, the external terminal 20 is a periphery and/or healthcare of each healthcare sensor module 200-1 to 200-N transmitted from the communication unit 303 and the communication network 10 through a pre-installed healthcare-related application. The temperature and/or humidity values for the surroundings of the control module 300 are provided, and based on this, the time and/or daily and/or day and/or week and /Or measurement of at least one of the current temperature and/or humidity measurements, the average temperature and/or humidity measurements, and/or a comparison of the reference temperature and/or humidity measurements with a preset reference temperature and/or humidity measurement per month It can perform the function of controlling the value to be displayed on the display screen.

In addition, the external terminal 20 is a carbon monoxide concentration value and / or carbon dioxide concentration value in the air around the mattress 100 transmitted from the communication unit 303 and the communication network 10 through a pre-installed healthcare-related application. Based on this, the current carbon monoxide and/or carbon dioxide concentration measurements, average carbon monoxide and hourly and/or daily and/or weekly and/or weekly and/or monthly based on the user's needs /Or a comparison with the carbon dioxide concentration measurement value and/or a preset reference carbon monoxide and/or carbon dioxide concentration measurement, and performs a function of controlling the concentration measurement value of at least one of the carbon monoxide and/or carbon dioxide concentration measurement values to be displayed on the display screen can do.

On the other hand, the external terminal 20 applied to an embodiment of the present invention is at least one of a smart phone (Smart Phone), smart pad (Smart Pad) or smart note (Smart Note) to communicate through the wireless Internet or the mobile Internet It is preferably made of a mobile terminal device, in addition to a personal PC, notebook PC, Palm (Palm) PC, mobile game machine (Mobile play-station), DMB (Digital Multimedia Broadcasting) phone with a communication function, tablet PC, iPad ( iPad) may refer to all wired/wireless home appliances/communication devices having a user interface for accessing the communication network 10 and/or the healthcare monitoring server 2000.

8, the external terminal 20 is a wireless communication module 21, an audio/video (A/V) input module 22, a user input module 23, a sensing module 24, as shown in FIG. It may include an output module 25, a storage module 26, an interface module 27, a terminal control module 28, and a power module 29. On the other hand, since the components shown in FIG. 8 are not essential, the external terminal 20 may have more components or fewer components.

Hereinafter, the components of the external terminal 20 will be described in detail as follows.

The wireless communication module 21 may include one or more modules that enable wireless communication between the external terminal 20 and the communication unit 303 and/or the healthcare monitoring server 2000. For example, the wireless communication module 21 may include a broadcast reception module 21a, a mobile communication module 21b, a wireless Internet module 21c, a short-range communication module 21d, and a location information module 21e.

The broadcast receiving module 21a broadcasts broadcast signals (eg, TV broadcast signals, radio broadcast signals, data broadcast signals, etc.) and/or broadcasts from external broadcast management servers through various broadcast channels (eg, satellite channels, terrestrial channels, etc.). Receive relevant information.

The mobile communication module 21b transmits and receives wireless signals to and from at least one of a base station, an external terminal 20, and a server on a mobile communication network. The wireless signal may include various types of data according to transmission and reception of a voice call signal, a video call signal, or a text/multimedia message.

The wireless Internet module 21c is a module for wireless Internet access, and may be built in or external to the external terminal 20. For example, WLAN (Wi-Fi), Wibro, Wimax, HSDPA, LTE, etc. may be used as the wireless Internet technology.

The short-range communication module 21d is a module for short-range communication, for example, Bluetooth communication, ZigBee communication, UWB (Ultra Wideband) communication, RFID (Radio Frequency Identification) communication, or infrared (IrDA, infrared data association) ) Communication can be used.

The location information module 21e is a module for confirming or obtaining the location of the external terminal 20, and may acquire current location information of the external terminal 20 using a Global Position System (GPS) or the like.

On the other hand, under the control of the terminal control module 28, the wireless communication module 21 and/or the wired communication module (not shown) using the specific application program stored in the storage module 26 through the communication unit 505 and Data transmission and reception can be performed.

The A/V input module 22 is a module for inputting an audio signal or a video signal, and basically may include a camera unit 22a and a microphone unit 22b. The camera unit 22a processes image frames such as still images or moving images obtained by an image sensor in a video call mode or a shooting mode. The microphone unit 22b receives an external sound signal by a microphone in a call mode, a recording mode, a voice recognition mode, etc., and processes it as electrical voice data.

The user input module 23 is a module that generates input data for controlling the operation of the external terminal 20, in particular, any one of the data management information displayed through the display unit 25a of the output module 25 Performs a function of inputting a selection signal for, for example, a touch panel (static pressure/electrostatic) type input by a user's touch or using a separate input device (eg, keypad dome switch, jog wheel, jog switch, etc.) Can be entered.

The sensing module 24 is the open/closed state of the external terminal 20, the location of the external terminal 20, the presence or absence of user contact, the user's touch action on a specific site, the orientation of the external terminal 20, the external terminal The current state of the external terminal 20, such as acceleration/deceleration of 20, is sensed to generate a sensing signal for controlling the operation of the external terminal 20. The sensing signal is transmitted to the terminal control module 28, so that the terminal control module 28 may be a basis for performing a specific function.

The output module 25 is a module for generating output related to vision, hearing, or tactile sense, and basically includes a display unit 25a, an audio output unit 25b, an alarm unit 25c, and a haptic unit 25d. Can.

The display unit 25a is for displaying and outputting information processed by the external terminal 20. For example, when the external terminal 20 is in a call mode, a user interface (UI) or a graphical user interface (GUI) related to a call ), and in the case of a video call mode or a photographing mode, a photographed and/or received image or UI, GUI is displayed.

The audio output unit 25b may output audio data received from the wireless communication module 21 or stored in the storage module 26 in a call signal reception, a call mode or a recording mode, a voice recognition mode, a broadcast reception mode, for example. .

The alarm unit 25c may output a signal for notifying the occurrence of the event of the external terminal 20. Examples of events generated in the external terminal 20 include call signal reception, message reception, key signal input, and touch input.

The haptic portion 25d generates various tactile effects that the user can feel. Vibration is a typical example of the tactile effect generated by the haptic portion 25d. The intensity and pattern of vibration generated by the haptic portion 25d can be controlled.

The storage module 26 may store a program for the operation of the terminal control module 28, and may temporarily store input/output data (eg, a phone book, message, still image, video, etc.).

In addition, the storage module 26 may store data related to various patterns of vibration and sound output when a touch is input on the touch screen, and may store a health care-related application program.

In addition, the storage module 26 may store source data for the formation of healthcare-related information, and the healthcare-related data may be configured in the form of video and sound, and the creation of related data for healthcare is in progress. Processes and results can also be saved.

The storage module 26 is a flash memory type, hard disk type, multimedia card micro type, card type memory (for example, SD or XD memory, etc.), RAM (RAM), SRAM, ROM (ROM), EEPROM, PROM , A storage medium of at least one type of a magnetic memory, a magnetic disk, or an optical disk.

The interface module 27 serves as a passage with all external devices connected to the external terminal 20. The interface module 27 receives data from an external device or receives power and transmits it to each component inside the external terminal 20 or allows data inside the external terminal 20 to be transmitted to the external device.

The terminal control module 28 generally controls the overall operation of the external terminal 20, and performs related control and processing for, for example, voice calls, data communication, video calls, and execution of various applications.

That is, the terminal control module 28 controls the health care-related application program stored in the storage module 26 to be executed, requests the creation of health care-related data through the execution of the health care-related application program, and the health care for the health care-related data. It performs the function of controlling to receive relevant data.

Also, the terminal control module 28 displays the auxiliary elements including at least one of video, audio, or sound in the process of generating healthcare-related data desired by the user through the execution of the healthcare-related application program. It performs a function of controlling to be output through at least one of other output devices (e.g., sound output unit 25b, alarm unit 25c, haptic unit 25d).

In addition, the terminal control module 28 may constantly monitor the charging current and charging voltage of the battery unit 29a and temporarily store the monitoring values in the storage module 26. At this time, it is preferable that the storage module 26 stores battery specification information (product code, rating, etc.) as well as battery charging status information such as monitored charging current and charging voltage.

The power module 29 receives external power and internal power by the control of the terminal control module 28 and supplies power required for the operation of each component. The power supply module 29 operates by supplying power of the built-in battery unit 29a to each component, and charging of the battery is possible using a charging terminal (not shown).

The various embodiments described herein can be implemented in a computer- or similar device-readable recording medium using, for example, software, hardware, or a combination thereof.

According to a hardware implementation, the embodiments described herein include application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs) , It can be implemented using at least one of processors, controllers, micro-controllers, microprocessors, and electrical units for performing functions. In some cases, such embodiments may be implemented by the terminal control module 28.

According to a software implementation, embodiments such as procedures or functions can be implemented with separate software modules that perform at least one function or operation. The software code can be implemented by software applications written in the appropriate programming language. In addition, the software code is stored in the storage module 26 and can be executed by the terminal control module 28.

If the external terminal 20 is made of a smart phone, the smart phone is free to use and delete various application programs desired by the user, unlike a normal mobile phone (aka feature phone). As a phone based on an open operating system that can be used, there are not all functions of voice/video calls and internet data communication, as well as all mobile phones with mobile office functions or voice calls, but all Internet access is possible. It is desirable to understand as a communication device including a phone or tablet PC.

Such a smart phone may be implemented as a smart phone equipped with a variety of open operating systems, and the open operating system includes, for example, Symbian of Nokia (NOKIA), Blackberry of RIMS, Apple's iPhone, and Microsoft. (MS)'s Windows Mobile, Google's Android, Samsung Electronics' Sea, etc.

As described above, since a smart phone uses an open operating system, unlike a mobile phone having a closed operating system, a user can arbitrarily install and manage various application programs.

That is, the aforementioned smart phone basically includes a control unit, a memory unit, a screen output unit, a key input unit, a sound output unit, a sound input unit, a camera unit, a wireless network communication module, a short-range wireless communication module, and a battery for power supply. do.

The control unit is a generic term for a functional configuration that controls the operation of a smartphone, and includes at least one processor and an execution memory, and is connected to each functional component provided in the smartphone through a bus.

The controller controls the operation of the smartphone by loading and calculating at least one program code provided in the smartphone through the processor into the execution memory, and passing the result to at least one functional component through the bus. .

The memory unit is a generic term for a non-volatile memory provided in a smartphone, and stores and maintains at least one program code executed through the controller and at least one data set used by the program code. The memory unit basically stores a system program code and a system data set corresponding to the operating system of the smartphone, a communication program code and communication data set for processing a wireless communication connection of the smartphone, and at least one application program code and application data set. In addition, program codes and data sets for implementing the present invention are also stored in the memory unit.

The screen output unit is composed of a screen output device (for example, a liquid crystal display (LCD) device) and an output module driving the same, and is connected to the controller and a bus to calculate calculation results corresponding to screen output among various calculation results of the control unit Output to the screen output device.

The key input unit is composed of a key input device (or a touch screen device interworking with the screen output unit) having at least one key button and an input module that drives the key input unit. Enter a command to command, or input data necessary for the operation of the control unit.

The sound output unit is composed of a speaker that outputs a sound signal and a sound module that drives the speaker, and is connected to the controller and a bus to output a calculation result corresponding to sound output among various calculation results of the control unit through the speaker. . The sound module decodes sound data to be output through the speaker and converts the sound data into a sound signal.

The sound input unit is composed of a microphone that receives a sound signal and a sound module that drives the microphone, and transmits sound data input through the microphone to the control unit. The sound module encodes and encodes a sound signal input through the microphone.

The camera unit is composed of an optical unit and a CCD (Charge Coupled Device) and a camera module driving the same, and acquires bitmap data input to the CCD through the optical unit. The bitmap data may include both image data and video data of a still image.

The wireless network communication module is a generic term for a communication configuration for connecting wireless communication, and includes at least one antenna, an RF module, a baseband module, and a signal processing module that transmit and receive radio frequency signals in a specific frequency band. It is connected to a bus and transmits calculation results corresponding to wireless communication among various calculation results of the control unit through wireless communication, or receives and transmits data to the control unit through wireless communication, and simultaneously connects and registers the wireless communication. Maintain the procedures of communication, handoff, and so on.

In addition, the wireless network communication module includes a mobile communication configuration that performs at least one of access, location registration, call processing, call connection, data communication, and handoff to a mobile communication network according to CDMA/WCDMA standards. Meanwhile, according to the intention of a person skilled in the art, the wireless network communication module may further include a portable Internet communication configuration that performs at least one of access, location registration, data communication, and handoff according to the IEEE 802.16 standard. It is apparent that the present invention is not limited by the wireless communication configuration provided by the communication module.

The short-range wireless communication module is composed of a short-range wireless communication module that connects a communication session by using a radio frequency signal as a communication medium within a certain distance, preferably RFID communication, Bluetooth communication, Wi-Fi communication, air of the ISO 180000 series standard It may include at least one of wireless communication. In addition, the short-range wireless communication module may be integrated with the wireless network communication module.

The smart phone configured as described above refers to a terminal capable of wireless communication, and any device that can transmit and receive data through a network including the Internet in addition to the smart phone may be applied to any device. That is, the smart phone may include at least one portable terminal capable of being carried and moved in addition to a notebook PC, a tablet PC having a short message transmission function and a network connection function.

Although the preferred embodiment of the health care monitoring system using the smart healthcare mattress according to the present invention described above has been described, the present invention is not limited to this, and the scope of the claims and the detailed description of the invention and the accompanying drawings. It is possible to carry out transformation with a branch, and this also belongs to the present invention.

1000-1 to 1000-N: smart healthcare mattress,
100: mattress,
200-1 to 200-N: health care sensor module,
300: health care control module,
400: power supply module,
2000: Healthcare monitoring server

Claims (22)

At least one smart healthcare mattress that detects and transmits a signal related to the bio-information of the measurement object existing on the mattress in a non-contact manner and transmits the unique device identification information; And
By receiving unique device identification information along with signals related to the biometric information of the corresponding measurement object transmitted from each smart healthcare mattress, based on this, breathing, heart rate, movement, distance, sleep, Alternatively, after analyzing at least one health condition information of the condition, each health care condition information analyzed for each smart health care mattress is stored and managed in a database (DB), and the administrator visually applies It includes a health care monitoring server that provides a service to monitor the health status of the measurement target in real time,
Each smart healthcare mattress is mounted on a mattress provided with at least one cushion member stacked inside the outer shell and a predetermined space formed on the cushion member of the mattress, and is measured on the mattress using a radar. At least one health care sensor module that detects a signal related to the subject's biometric information in a non-contact manner, and receives a signal related to the bioinformation of the corresponding measurement target detected from each health care sensor module, along with unique device identification information that has been previously set. It includes a healthcare control module for controlling to be transmitted to the healthcare monitoring server through a wired or wireless communication method,
Each health care sensor module includes a radar transmission unit that transmits a first signal having a radar pulse to a corresponding measurement object existing on the mattress, and is reflected from the measurement object and is associated with the first signal. 2 The frequency is extracted based on the radar receiver receiving the signal, the first and second signals transmitted and received from the radar transmitter and the radar receiver, and the signals related to the bio-information of the corresponding measurement object according to the phase difference of the frequencies A signal processing unit for processing, a radar transmitting unit, the radar receiving unit and the signal processing unit mounted on a predetermined printed circuit board (PCB), and a data cable for sensor communication and power supply to the healthcare control module are electrically connected. And a PCB protection part connected to the PCB substrate and molded so as to cover the entire outside of the PCB substrate part through an injection molding method of liquid silicone for waterproof and shock prevention of the PCB substrate part,
The healthcare control module is installed to be spaced apart from the mattress at a predetermined distance, and is provided to be exposed to the outside of the main body and the main body forming the whole body, and is electrically connected to a data cable connected to the PCB substrate. A cable connector, a communication unit that transmits unique device identification information along with a signal related to biometric information of a corresponding measurement object existing on the mattress in a wired or wireless communication method, is provided inside the body unit, and the cable connector is provided. A control unit for controlling the operation of the communication unit so as to transmit predetermined device identification information together with a signal related to the bio-information of the corresponding measurement target transmitted to the healthcare monitoring server, and is provided inside the main unit, and the control unit It includes a power supply for supplying the power required for each health care sensor module through the cable connector as well as the power required for,
When each health care sensor module consists of a plurality,
The control unit receives the final measurement value from each health care sensor module through the cable connector, extracts distance information from the final measurement value of each health care sensor module based on this, and then extracts each health care sensor module. When the final measurement value of the measurement is a preset measurement valid value, the final measurement value of the health care sensor module determined to be less than or equal to a preset reference distance difference value compared with a previously stored distance measurement target value is the health care monitoring Control the operation of the communication unit to be transmitted to a server, or breath, heart rate, movement, distance, sleep, or condition of the corresponding measurement object based on the final measured value of the health care sensor module determined to be below the preset reference distance difference value Analyzes at least one health status information among states, and if the final measurement value of each healthcare sensor module is a preset measurement valid value, the difference is compared to a previously stored distance value from a recent measurement target, and the difference is a preset reference distance difference. Based on the final measured value of the health care sensor module determined to be greater than or equal to the value, the movement of the target to be measured is judged, and when determined as the movement of the target, the difference is compared with the last measured value of the recently saved health care sensor module. Control the operation of the communication unit so that the final measured value of the health care sensor module determined to be below the preset reference approximation value is transmitted to the healthcare monitoring server, or the final measurement of the health care sensor module determined to be below the preset reference approximation value. Health care monitoring system using a smart healthcare mattress, characterized in that it analyzes at least one health care status information of a breathing, heartbeat, movement, distance, sleep, or condition of a corresponding measurement object based on a value.
delete delete delete According to claim 1,
The health care control module,
A storage unit which is provided inside/outside the main body, and stores at least one health care status information among breath, heartbeat, movement, distance, sleep, or condition of the measurement object; And
It is provided on the outside of the main body, and further includes a display unit for visually displaying health status information of at least one of breath, heart rate, movement, distance, sleep, or condition of the measurement target,
The control unit analyzes at least one health care status information of a breathing, heartbeat, movement, distance, sleep, or condition of the measurement target based on a signal related to the biological information of the measurement target transmitted through the cable connector After doing this, the healthcare state information analyzed for each healthcare state is converted into a database (DB) to be stored and managed in the storage unit, and the operation of the display unit is displayed so that the user can visually check it on the display screen. Health management monitoring system using a smart healthcare mattress characterized in that the control.
delete delete According to claim 1,
The controller compares with the last measured value of the recently stored health care sensor module when judged as the movement of the measurement target, and the difference is the most difference among the last measured values of the health care sensor module determined to be greater than or equal to a preset reference approximation value. Control the operation of the communication unit so that the final measurement value of the healthcare sensor module having a small value is transmitted to the healthcare monitoring server, or the most difference among the final measurement values of the healthcare sensor module determined to be higher than the preset reference approximation value. Smart health characterized by analyzing at least one health care status information of breath, heart rate, movement, distance, sleep, or condition of the measurement target based on the final measurement value of the health care sensor module having a small value Health care monitoring system using care mattress.
According to claim 1,
The health care control module,
A measurement suction port formed on one side of the main body part to suck outside air;
A measurement outlet formed on the other side of the main body to discharge internal air; And
It is provided inside the main body, and sucks external air through the measurement inlet to detect alpha particles in the air in real time to output a predetermined alpha particle detection signal, and a preset measurement time based on the output alpha particle detection signal. After counting while calculating the alpha particle concentration value, a radon measurement unit for discharging the air inside the body through the measurement outlet is further included.
The control unit receives the alpha particle concentration value calculated from the radon measurement unit and digitizes the measurement value of radon in the air based on the mattress based on this, along with the unique device identification information, and the healthcare monitoring server. Control the operation of the communication unit to be transmitted to, or control the data to be stored and managed in a separate storage unit by converting the digitized radon measurement value into an hourly/daily/weekly/weekly/monthly database (DB). Health management monitoring system using a smart healthcare mattress, characterized in that the control to be displayed on the display screen of a separate display unit to be checked.
The method of claim 9,
The healthcare monitoring server receives unique device identification information along with radon measurement values in the air existing around the smart healthcare mattress transmitted from the communication unit through a pre-installed healthcare-related application, and based on this, receives the device identification information of the manager. According to the demand, the current radon measurement value, average radon measurement value, or preset reference radon measurement value in the air existing in the vicinity of each smart healthcare mattress by hour/day/day/week/month using a circular or bar graph Provides a monitoring service to display at least one radon measurement value of the comparison radon measurement value in real time on a display screen, or compares the current radon measurement value, average radon measurement value, or preset reference radon measurement value for each smart healthcare mattress. A smart healthcare mattress characterized by providing a service to store and manage at least one radon measurement value of a comparison radon measurement value in a database (DB) by hourly/daily/weekly/weekly/monthly Health care monitoring system used.
According to claim 1,
The health care control module,
A measurement suction port formed on one side of the main body part to suck outside air;
A measurement outlet formed on the other side of the main body to discharge internal air;
A fine dust detector which is provided inside the main body part, detects the concentration of fine dust in the air by sucking outside air through the measurement intake port, and then discharges the inside air through the measurement outlet; And
It is provided inside the body portion, and after detecting the concentration of ultra-fine dust in the air by inhaling external air through the measurement inlet, the ultra-fine dust detection unit for discharging the internal air through the measurement outlet is further included ,
The control unit digitizes the fine dust concentration value and the ultra fine dust concentration value in the air detected from the fine dust detection unit and the ultra fine dust detection unit, respectively, and sets the fine dust concentration value to the healthcare monitoring server together with preset unique device identification information. Control the operation of the communication unit to be transmitted, or control the storage and management of the digitized fine dust concentration value and ultra fine dust concentration value by hourly/daily/day/weekly/monthly database (DB) In addition, the health care monitoring system using a smart healthcare mattress, characterized in that it is controlled to be displayed on a display screen of a separate display unit so that the user can visually check it.
The method of claim 11,
The healthcare monitoring server provides unique device identification information along with fine dust concentration values and ultra fine dust concentration values in the air existing around each smart healthcare mattress transmitted from the communication unit through a pre-installed healthcare-related application. Based on this, based on the request of the manager, the current fine dust/ultrafine dust concentration measured in the air in the vicinity of each smart healthcare mattress by hour/day/day/week/month using a circular or bar graph, Compared to the average fine dust/ultrafine dust concentration measurement value or a preset reference fine dust/ultrafine dust concentration measurement value. At least one concentration measurement value of the fine dust/ultrafine dust concentration measurement value is displayed on the display screen in real time. Provides monitoring service, compares the current fine dust/ultrafine dust concentration measurement value, average fine dust/ultrafine dust concentration measurement value for each smart healthcare mattress, or compares it with the preset standard fine dust/ultrafine dust concentration measurement value It is characterized by providing services to store and manage at least one concentration measurement value of fine dust/ultrafine dust concentration by database (DB) by hour/day/day/week/month. Health care monitoring system using smart healthcare mattress.
According to claim 1,
It is installed to be exposed on the PCB protection part or is installed on the inside/outside of the body part provided in the healthcare control module, and measures the temperature to measure the temperature around each healthcare sensor module or around the healthcare control module. part; And
Humidity measurement that is installed to be exposed on the PCB protection part or installed inside/outside the body part provided in the healthcare control module, and measures humidity for the periphery of each healthcare sensor module or the periphery of the healthcare control module. More additional,
The control unit provided in the healthcare control module is configured to digitize the temperature and humidity values respectively measured from the temperature measurement unit and the humidity measurement unit, and transmit them to the healthcare monitoring server together with preset unique device identification information. Controls the operation of the communication unit, or controls the digitized temperature and humidity values to be stored and managed in a separate storage unit by making a database (DB) for each hour/day/day/week/month. Health management monitoring system using a smart healthcare mattress, characterized in that the control to be displayed on the display screen of a separate display unit.
The method of claim 13,
The healthcare monitoring server provides unique device identification information along with temperature and humidity values for the periphery of each healthcare sensor module or the periphery of the healthcare control module transmitted from the communication unit through a pre-installed healthcare-related application. Based on this, the current temperature/humidity measured value, average temperature/humidity measured value, or preset reference temperature/humidity measured value by hour/daily/day/weekly/monthly based on the administrator's request Provides monitoring service to display at least one of the measured temperature/humidity measurement values in real time on the display screen, or the current temperature/humidity measurement value, average temperature/humidity measurement value, or a preset value for each smart healthcare mattress. Comparison with the reference temperature/humidity measurement value Provides a service to store and manage at least one of the temperature/humidity measurement values in a database (DB) by hourly/daily/weekly/weekly/monthly Health management monitoring system using a smart healthcare mattress, characterized in that.
According to claim 1,
The health care control module,
A measurement suction port formed on one side of the main body part to suck outside air;
A measurement outlet formed on the other side of the main body to discharge internal air;
A carbon monoxide detector that is provided inside the main body, detects carbon monoxide (CO) concentration in the air by sucking outside air through the measurement intake, and then discharges the internal air through the measurement outlet; And
It is provided inside the main body portion, and after detecting the carbon dioxide (CO ₂ ) concentration in the air by inhaling external air through the measurement inlet, a carbon dioxide detection unit for discharging the internal air through the measurement outlet is further included ,
The control unit numerically quantifies the carbon monoxide concentration value and the carbon dioxide concentration value in the air existing around each smart healthcare mattress sensed by the carbon monoxide detector and the carbon dioxide detector, along with the unique device identification information set in advance. To control the operation of the communication unit to be transmitted to the care monitoring server, or to store and manage the numerical carbon monoxide concentration values and carbon dioxide concentration values in a database (DB) by hourly/daily/weekly/weekly/monthly A health management monitoring system using a smart healthcare mattress, characterized in that it is displayed on a display screen of a separate display unit so that the user can visually check the control box.
The method of claim 15,
The healthcare monitoring server receives the unique device identification information along with the carbon monoxide concentration and carbon dioxide concentration values for the periphery of each smart healthcare mattress transmitted from the communication unit through a pre-installed healthcare-related application, and the manager is based on this. According to the demand, the current carbon monoxide/carbon dioxide concentration measured value, average carbon monoxide/carbon dioxide concentration measured value by hour/daily/day/weekly/monthly, using a circular or bar graph, or comparison with a preset reference carbon monoxide/carbon dioxide concentration measured value Provide monitoring service to display at least one concentration measurement of carbon monoxide/carbon dioxide concentration on a display screen in real time, or measure current carbon monoxide/carbon dioxide concentration by each smart healthcare mattress, average carbon monoxide/carbon dioxide concentration measurement, or group Comparison with the set standard carbon monoxide/carbon dioxide concentration measurement value. At least one concentration measurement value among carbon monoxide/carbon dioxide concentration measurement values is databased (hourly/daily/weekly/weekly/monthly) to be stored and managed in a separate storage device. Health care monitoring system using a smart healthcare mattress characterized in that it provides a service.
According to claim 1,
The health care monitoring server, by using a pre-installed health care-related application, each health care status information analyzed for each smart health care mattress, by using a circular or bar graph according to the administrator's request, hourly/daily/weekly /Weekly/Month provides monitoring service to display real-time display of at least one of the current status measured value, average status measured value, or comparison status measured value with a preset reference status measured value on the display screen in real time. Health care monitoring system using smart healthcare mattress.
According to claim 1,
The health care monitoring server measures each reference state in which at least one current health care state measurement value of a breathing, heart rate, movement, distance, sleep, or condition of the corresponding measurement object analyzed for each smart healthcare mattress is preset. If it exceeds, provide the service so that the manager can audibly or visually check the healthcare warning message corresponding to the current healthcare condition measurement value, or the target of the measurement of each smart healthcare mattress is audible or visual Health monitoring system using a smart healthcare mattress characterized in that it provides a service to be transmitted to a separate voice output unit or display unit connected to each smart healthcare mattress to be checked.
According to claim 1,
The healthcare monitoring server provides a cloud computing service in response to a request from an external client terminal,
The client terminal, by using a client member login cloud web service of the healthcare monitoring server, breathing, heart rate, movement, distance, sleep of the corresponding measurement object analyzed and stored for each smart healthcare mattress on the healthcare monitoring server, Alternatively, a health management monitoring system using a smart healthcare mattress, characterized in that at least one of the health conditions is searched in real time and displayed on a display screen.
The method of claim 19,
When the health care monitoring server stores and stores at least one health care state information of the respiratory, heart rate, movement, distance, sleep, or condition of the corresponding measurement object analyzed for each smart health care mattress in a database (DB), Encrypting and storing at least one health care state information of breath, heart rate, movement, distance, sleep, or condition of the corresponding measurement object analyzed for each smart health care mattress using a symmetric or asymmetric encryption method, and the encrypted Provides a service so that a decryption key capable of decrypting at least one health status information of a breathing, heartbeat, movement, distance, sleep, or condition of a corresponding measurement target for each smart healthcare mattress is transmitted to the client terminal,
The client terminal, using the decryption key transmitted from the healthcare monitoring server together with the corresponding client member login information, breathing, heart rate, movement of the corresponding measurement object for each smart healthcare mattress stored and encrypted in the healthcare monitoring server, A health care monitoring system using a smart healthcare mattress, characterized in that it decodes at least one health condition information of a distance, sleep, or condition and displays it in real time and displays it on a display screen.
The method of claim 20,
The healthcare monitoring server, through the client terminal, the cloud web to download at least one of the health status information of breath, heart rate, movement, distance, sleep, or condition of each measurement target for each smart healthcare mattress. Health care monitoring system using a smart healthcare mattress characterized in that it provides a service.
The method of claim 19,
The client terminal is in the state of breathing, heart rate, movement, distance, sleep, or condition of each measurement target for each smart healthcare mattress stored in the healthcare monitoring server through a healthcare-related application downloaded from the healthcare monitoring server. A health management monitoring system using a smart healthcare mattress, characterized in that at least one healthcare status information is displayed in real time and displayed on a display screen.

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