KR20110128382A - Medical assistance system for monitoring biomedical signal - Google Patents

Abstract

PURPOSE: A life medical treatment auxiliary system for monitoring a biological signal is provided to measure the state of a person in outside by enabling a monitored person to directly confirmed measured data about the biological signal. CONSTITUTION: Sensors(12, 14, 16) measures the body state of a monitored person. A local data management unit receives measured data from the sensors. The local data management unit determines the state of the monitored person based on the measured data. A monitoring server(60) stores the measured data which receives measuring view point information in a DB(Data Base).

Description

Medical Assistance System for Monitoring Biomedical Signal

TECHNICAL FIELD The present invention relates to a telemetry system, and more particularly, to a system for telemetrically storing and storing a biological signal and providing the same to a related person.

As the transition to an aging society accelerates, as nuclear family development progresses and women's social activities become more active, the number of elderly people living alone is decreasing and the number of elderly people living alone is increasing. In general, elderly people who live alone have old age and disease, and have to manage them steadily, but there is no one to care for them, so there is an urgent need for a system that can monitor the health and safety of these elderly people living alone.

In addition to elderly people living alone, there are some diseases that require doctor's care from time to time, such as diabetes and heart disease. In the case of diabetes, patients suffering from it often need to measure blood glucose levels so that the doctor knows. In the past, patients check their blood sugar frequently, record it, and take it to a doctor for diagnosis. However, it is inconvenient to take your blood glucose record papers to your doctor from time to time. On the other hand, patients suffering from heart disease such as high blood pressure, hyperlipidemia, and arrhythmia may need to be diagnosed and treated through regular health check-ups. The situation may worsen, and if the symptoms are severe, there may be sudden death.

As such, elderly people living alone or those suffering from chronic diseases need to check their health at all times. However, in the case of frequent diagnosis to go to the hospital, not only the economic and time burden of the patient himself, but also the medical personnel are consumed in a simple diagnosis, resulting in the uneconomical management of medical personnel. Therefore, there is a need for a method for transmitting a biological signal of a monitoring target such as an elderly person living alone or a patient to a remote server and managing the same at the server.

Some ideas have been provided in this regard. For example, Patent No. 787148 (invention name: unmanned physical delivery system of the invention) unmanned measurement of the physical condition, such as blood pressure, pulse, body temperature, etc. of the person who needs to check the physical condition unattended body state unattended It presents a delivery system.

However, according to the system described in this document, the data measured by the sensor is transmitted through a dedicated terminal to the main terminal, i.e., the server, the terminal around the monitoring target only has an alarm function, the actual measurement data is the server Because it is stored only in the system, if the person to be monitored or the guardian wants to confirm the actual measurement data, the PC must be connected to the server again. In addition, when the measurement data is collected by a dedicated terminal or a PC and transmitted to the server, since the terminal or the PC must be operated for 24 hours, power consumption may be high and accordingly, an electric charge may be excessive. In addition, in the case where the person to be monitored leaves the home, measurement may be difficult.

The present invention is to solve such a problem, but to measure the biological signal of the person who needs to check the physical condition and send it to the server and keep it, so that the subject or the guardian or medical personnel to check it, but the subject It is a technical task to provide a living medical assistant system that enables the user to easily check the measurement data on the local device, to measure even when the person to be monitored goes out, and to lower power consumption in the home.

The medical care assistance system of the present invention for achieving the above technical problem comprises one or more sensors, local data management means, and a monitoring server.

The sensor measures any one of body temperature, blood pressure, pulse rate, and a combination of two or more thereof. The local data management means receives the measurement data from the sensor, adds and stores measurement time information, determines the state of the monitoring subject based on the measurement data, and provides an alarm when the state deviates from a predetermined standard. Is not received within the specified time range, it generates a measurement guide alarm and transmits the measurement data with the measurement time information added over the network. The server receives measurement data to which measurement time information is added from a local data management means through a network, stores the measurement data in a database, and provides the processed data in accordance with a request of an external client.

The local data management means is preferably implemented by a program loaded and executed in a mobile terminal.

In addition, the present invention provides a program that is suitable for implementing the above-mentioned living medical assistance system and can be executed in a mobile terminal.

The program includes a function of receiving measurement data indicative of any one of body temperature, blood pressure, pulse rate, and a combination of two or more thereof; Storing the measurement data in memory along with measurement time information; Determining a state of the monitoring subject based on the measured data and providing an alarm when the state deviates from a predetermined standard; A function of generating a measurement guide alarm when the measurement data from the sensor is not received within a predetermined time range; And transmitting the measurement data added with the measurement time information to a remote server through a network.

According to the present invention, the elderly living alone, or suffer from chronic diseases such as diabetes, heart disease, the biological signal of the monitoring subject who needs to check the physical condition is measured and sent to the server and stored in the monitoring target person or guardian or medical personnel It allows you to check. In particular, since biometric data is stored not only on the server but also on local devices such as PCs and smartphones, it is easy to check the measured data and trends of changes without monitoring the person or guardian without accessing the server through the Internet. It is also possible to conduct online medical consultations based on the accumulated data, thus eliminating the need for the monitoring subjects to visit the hospital only for examinations or consultations, and to provide medical time for patients who are not critical to the doctor. A shortening effect can be expected.

In particular, when the measurement data is collected by the smart phone as in the preferred embodiment, it is possible to measure even when the monitoring target is out, there is an additional advantage that the power consumption in the house is low.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention. In the drawings,
1 is a block diagram showing a preferred embodiment of the medical care aid system according to the present invention.
FIG. 2 is a block diagram of a measurement data processing program executed in the smartphone shown in FIG. 1.
FIG. 3 is a flowchart illustrating a process of transmitting measurement data to a monitoring server and issuing an alarm in the smartphone shown in FIG. 1.

Referring to FIG. 1, in a preferred embodiment of the present invention, the medical care assisting system includes a plurality of sensors 12 to 16 and a detection signal of the sensors 12 to 16 for sensing a physical state of a subject to be monitored. Wireless sensor network 20, the smart phone 40 and the PC 42, and the smart phone 40 or the PC 42 to deliver the data to the smart phone 40 and / or the PC 42 It is provided with the monitoring server 60 which can be connected through the internet.

The sensors 12-16 include an infrared temperature sensor 12, a blood glucose sensor 14, and a blood pressure sensor 16. The infrared temperature sensor 12 measures the body temperature of the monitoring target by measuring the infrared radiation emitted from the body of the monitoring target. The blood glucose sensor 14 may be implemented by a commercially available blood glucose measurement kit, which measures the blood sugar of the monitored subject. The blood pressure sensor 15 may be built in a blood pressure monitor that may be worn on the forearm or wrist of the monitoring target, and measures the blood pressure of the monitoring target.

In a preferred embodiment, the infrared temperature sensor 12 is non-contact, measuring body temperature at all times for the monitored subject. The blood pressure sensor 16 and the electrocardiogram sensor 18 may be contacted, and may be monitored periodically or non-periodically by the subject to measure the condition using the same.

The wireless sensor network 20 transmits a detection signal of the sensors 12 to 16 to the smartphone 40 or the PC 42, and wireless transmitters provided corresponding to the sensors 12 to 16, respectively. 22 to 26, the wireless receiver 30 wirelessly communicating with the wireless transmitters 22 to 26 and connected to the USB port of the smartphone 40 or connected to the PC 42 in a serial communication manner. It is provided. In the preferred embodiment, the radio transmitters 22 to 26 and the radio receiver 30 transmit and receive signals in a Zigbee manner based on the IEEE 802.15.4 standard. Further, in a preferred embodiment, at least some of the sensors 12-16 and radio transmitters 22-26 respectively connected thereto are so-called Zigbee motes that are physically installed in one frame, respectively. It can be implemented as a wireless sensor node. For example, the infrared temperature sensor 12 and the radio transmitter 22 may be implemented as one Zigbee mort.

The smartphone 40 or the PC 42 receives the measurement data of the sensors 12-16 through the wireless sensor network 20 and transmits the measurement data to the monitoring server 60. In a preferred embodiment, the smartphone 40 is used rather than the PC 42 to increase mobility and reduce power consumption. The smartphone 40 transmits the measurement data to the monitoring server 60 through, for example, a wireless LAN and the Internet that conforms to the IEEE802.11x standard. Hereinafter, description will be given with respect to the smartphone 40.

In the smartphone 40, the function of receiving the measurement signal and transmitting it to the monitoring server 60, the function of determining whether the measurement signal is appropriate to generate an alarm, the function of storing the measurement signal, the stored data graphic or It is preferable that a measurement data processing program that performs a function of displaying in text form is installed and executed. The program tags time information or time stamps on the detection signals of the sensors 12-16, and transmits the measurement data to which the time stamp is added to the monitoring server 60 through the Internet.

The monitoring server 60 receives the measurement data from the smartphone 40, stores it in a database, and accumulates it, and stores the accumulated data as a web service method when a client such as a monitoring subject or guardian's PC or a hospital server 80 requests it. to provide. In this case, the range of information provided according to the grade of the client user may be differentiated. Since all measurement data indicating the physical condition of the monitoring subject can be accumulated and provided in the monitoring server 60, the guardian or doctor can check the status of the monitoring subject in real time even from a remote location, and the existing physical state variation history data can be obtained. Based on this, they can refer to health care and make necessary decisions.

2 is a block diagram of a measurement data processing program executed in the smartphone 40. The measurement data processing program includes a measurement signal conversion unit 100, a storage unit 102, a display unit 106, an analysis determination unit 108, an alarm generating unit 110, a transmission unit 112, , Measurement frequency check unit 114 is included.

The measurement signal converter 100 converts the measurement data by adding a time stamp, that is, measurement time information, to the measurement data received from the sensors 12 to 16 through the wireless sensor network 20. The storage unit 102 stores the measurement data to which the time stamp is added to the memory 104 of the smartphone 40, for example, a nonvolatile memory such as a flash memory or an EEPROM. The display unit 106 calls the measurement data stored in the storage unit 104 according to the instructions of the monitoring subject or guardian and displays the measured data in a graphic or table format on the display unit of the smartphone 40.

The analysis decision unit 108 determines whether the newly received measurement data from the sensors 12 to 16 are normal. The determination as to whether the measurement data is normal can be made by comparing the predetermined criteria with respect to each of the three types of measurement data. For example, when the body temperature is lower than the predetermined first reference value or higher than the second reference value, and the state persists for a predetermined time or more, the analysis determination unit 108 may visually or audiologically through the alarm generating unit 110. An alarm can be triggered. In the case of an electrocardiogram, various physiological indexes are checked by interpreting the reconstructed electrocardiogram waveform in the time domain and the frequency domain based on the measured data. For example, the analysis judgment unit 108 may have an external contraction in which the heartbeat sometimes skips once, based on electrocardiogram measurement data, atrial fibrillation without pulse rhythm at all, or a paroxysmal pulsation or ventricular fibrillation due to the atrium moving arbitrarily. Judge. Since the normal range may be different for each measurement data for each person, the reference value applied by the analysis determination unit 108 may be adjusted by the user.

Meanwhile, the transmitter 112 transmits the measurement data to which the time stamp is added to the monitoring server 60 at every measurement. However, in the modified embodiment, the transmitter 112 may transmit a plurality of measurement data at once in a batch manner.

The measurement frequency checker 114 displays a guide message for ventilating or reminding the measurement through the display 106 when the monitoring target does not perform the physical condition measurement by the non-contact sensors 14 and 16 at a predetermined time. In addition, an alarm is generated through the alarm generator 110.

3 is a flowchart illustrating a process of transmitting measurement data to the monitoring server 60 and issuing an alarm in the smartphone 40.

The signals measured by the sensors 12-16 are transmitted to the smartphone 40 via the wireless sensor network 20. The measurement signal converter 100 converts the measurement data by adding a time stamp, that is, measurement time information, to the received measurement data. In addition, the analysis determining unit 108 determines whether the newly received measurement data from the sensors 12 to 16 are normal (operation 200).

Subsequently, the storage unit 102 stores the measurement data to which the time stamp is added to the memory 104 of the smartphone 40 (step 202). In this case, the display unit 106 may display the newly acquired measurement data together with the past measurement data stored in the storage unit 104 on the display unit of the smartphone 40.

In operation 204, the analysis determining unit 108 determines whether the newly received measurement data from the sensors 12 to 16 are normal. If the newly received measurement data is not normal, the analysis determination unit 108 may generate an alarm through the alarm generation unit 110 so that the monitored subject pays attention to the health management (step 206). At this time, the alarm generating unit 110 may provide a countermeasure to the monitoring target. For example, when the blood pressure of the monitoring target is high or the ECG is unstable, the alarm generator 110 may recommend finding a psychological margin through music listening, etc., and may recommend a hospital check if the symptoms are severe. In addition, if the body temperature is high or low can suggest a body temperature management accordingly.

Finally, the transmitter 112 transmits the measurement data along with the information on whether the signal is normal to the monitoring server 60, so that the monitoring server 60 stores it (step 208). Accordingly, the monitoring server 60 provides the client with a biometric index of the monitoring target for each of the measured time periods through a graph or the like so that the client user can conveniently check the client. In particular, a doctor located in a remote location can check the biometrics of a patient registered to him through a graph for each measured time period, thereby making a more accurate diagnosis for the patient through long-term data.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Therefore, the embodiments described above are to be understood in all respects as illustrative and not restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

Claims (3)

One or more sensors for measuring any one of body temperature, blood pressure, pulse rate, and a combination of two or more thereof;
Receives measurement data from the sensor, adds and stores measurement time information, determines the state of the monitoring subject based on the measurement data, and provides an alarm when the state deviates from a predetermined criterion. Local data management means for generating a measurement guide alarm when not received within a predetermined time range, and for transmitting the measurement data to which the measurement time information is added through a network; And
A monitoring server which receives the measurement data added with the measurement time information from the local data management means through the network, stores the measurement data in a database, and provides the processed data in a processed form according to a request of an external client;
Life medical assistant system provided with. Life care assistance system is implemented by a program that is loaded and executed in the mobile terminal the local data management means. Receiving measurement data indicative of any one of body temperature, blood pressure, pulse rate, and a combination of two or more thereof;
Storing the measurement data in memory along with measurement time information;
Determining a state of the monitoring subject based on the measured data and providing an alarm when the state deviates from a predetermined standard;
A function of generating a measurement guide alarm when the measurement data from the sensor is not received within a predetermined time range; And
Transmitting measurement data added with the measurement time information to a remote server through a network;
A mobile terminal for storing and executing a program suitable for implementing.

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