KR20150103568A - A wearable sensing device and a method of monitoring biological signal data/alerting emergencies by using thereof - Google Patents

Abstract

The wearable sensing device includes a biosensor sheet covering a part of the chest front surface and a part of the back surface of the chest centered on axilla and a biosensor control part connected to the biosensor sheet and positioned at the lower end of the chest back surface, The seat may be configured to measure at least one of a biological signal of an electrocardiogram, heart rate, body temperature, pulse, electromyogram, blood pressure, electromyogram, and respiration amount. The wearable sensing device according to the present invention and the biometric data management and emergency situation detection method using the wearable sensing device according to the present invention can rapidly determine the presence or absence of health condition and the occurrence of an emergency situation of the protection target persons in the nursing care /

Description

TECHNICAL FIELD [0001] The present invention relates to a wearable sensing device, and more particularly, to a wearable sensing device and a bio-signal data monitoring / emergency state sensing method using the wearable sensing device.

The present invention relates to a wearable sensing device and a method for monitoring bio-signal data using the wearable sensing device and detecting an emergency situation. More specifically, the present invention relates to a wearable sensing device, And a method for easily detecting the wearer of the wearable sensing device when the wearable device is in an emergency.

According to the National Statistical Office, Korea has entered an aging society with the proportion of people aged 65 and over exceeding 7.2%. In the future, the proportion of the population aged 65 or older in Korea will exceed 14.3% in 2018 and exceed 20.8% And expected to enter society. Rapid aging of this population is occurring not only in Korea but also in many countries such as Japan, USA, UK, France, Italy and Germany.

Due to such an aging phenomenon, the silver industry in various fields is highlighted by the nursing industry, the home care service industry, the medical service industry, the financial industry for the elderly, and the entertainment business.

Despite the aging of the population and the rapid increase in the proportion of single family members beyond the nuclear family and the nuclear family, despite the high demand for nursing facilities among the silver industry, the number of facilities and facilities are insufficient to support the abused persons such as the elderly It is a reality. Because of this reality, there is a growing demand for health management systems that can remotely monitor the status of protected persons, such as elderly people, in nursing homes and the like.

On the other hand, due to the development of bio-information measurement technology, biosensors equipped with personal identification function through biometric information are applied to the security industry, and the development of smart apparel that attaches bio sensors to apparel .

[0003] Reflecting the tendency of development of the bio-information measuring technique, a smart (self-contained) device having a function of measuring a body temperature, an electrocardiogram and a breath of the user in close contact with the inner side of a garment Apparel is being developed. However, even in such a method, it is difficult for a person to be protected to directly use the device because the user needs to operate the device, such as a user who wears clothes and then inputs a measurement cycle, There is a problem that it is not enough to manage people in a unified way.

The object of the present invention proposed to solve the above-mentioned problems of the prior art is to monitor the bio-signal data of the protected persons in the nursing home and to manage the presence or absence of the body abnormality in the management server in an integrated manner. In addition, the present invention provides a management server that notifies the management server of the fact that the protected persons are close to the dangerous area when the protected persons are close to the dangerous area of the nursing home designated in advance in the management server, There is another purpose for this.

According to one embodiment for achieving the above-mentioned object, a wearable sensing device which is brought into close contact with the upper body of a wearer is disclosed. Wherein the wearable sensing device includes a biosensor sheet covering a part of a chest front surface and a part of a chest back surface around an axilla and a biosensor control unit connected to the biosensor sheet and positioned at a lower end of the chest back surface, The biosensor sheet can be configured to measure at least one of biological signals such as electrocardiogram, heart rate, body temperature, pulse, electromyogram, blood pressure, and respiratory volume.

The biosensor control unit of the wearable sensing device according to an embodiment of the present invention may be configured such that when the biosensor sheet first measures the wearer's biomedical signal and transmits it to the management server, A wireless communication module that receives a data transmission period and receives the position information of the wearer in real time from a GPS satellite or an access point, and transmits a set of biometric signal data to the management server at the data transmission period; A processor for compressing and converting the identifier, the positional information, and the measured bio-signal into a set of bio-signal data so that the wireless communication module can transmit the data according to the data transmission period; And an alarm module for generating a warning indication signal and a position warning signal when the position information is close to a dangerous area designated by the management server, and when the alarm module generates the warning indication signal and the position warning signal The processor further compresses and converts the position warning signal, the identifier and the position signal into warning signal data, and the wireless communication module transmits the warning signal data to the management server.

The wireless communication module may be a Wi-Fi, an ultra wideband (UWB), a Zigbee, or a Bluetooth communication module, and is preferably a Zigbee communication module.

According to another aspect of the present invention, there is provided a wearable device including: a wearable sensing device; a wearable sensing device; Transmitting the allocated identifier and a data transmission period to the wearable sensing device; Receiving a set of biometric signal data from the wearable sensing device every data transmission period; Receiving warning signal data from the wearable sensing device; And decompresses the received set of biometric signal data, converts the biometric signal data into an identifier, positional information, and biometric signal of the wearer, decompresses the warning signal data, and converts the biometric signal data into a wearer's positional warning signal, A biometric data management method and an emergency situation detection method using a wearable sensing device and a management server including a step are disclosed.

The wearable sensing device and the biometric data management and emergency situation detection method using the wearable sensing device according to the present invention can quickly determine the presence or absence of health anomalies and emergencies of protected persons in a nursing care / Further, the wearable sensing device according to the present invention uses a material that is easy to be washed and maintained, and improves the arrangement of the substrate and the fabric, thereby minimizing the pressure of the wearable sensing device when worn and reducing the thickness of the wearable sensing device The feeling of foreign body can be reduced, and the feeling of wearing can be improved at the time of wearing.

FIG. 1 illustrates a system for implementing biometric data management and an emergency situation detection method using a wearable sensing device and a management server according to an embodiment of the present invention.
2 shows a functional block diagram of a wearable sensing device according to an embodiment of the present invention.
3 shows a flowchart of a method for managing biometric data and detecting an emergency situation according to an embodiment of the present invention.
FIG. 4 illustrates an exemplary screen of a management server according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a wearable sensing device according to an embodiment of the present invention, a biometric data management method using the same and an emergency situation detection method will be described in detail with reference to the accompanying drawings.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, In the text of the detailed description. It is to be understood, however, that the intention is not to limit the invention to the specific forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. In the meantime, the same or similar reference numerals are used for similar components while explaining each drawing.

FIG. 1 illustrates a system for implementing biometric data management and an emergency situation detection method using the wearable sensing device 12 and the management server 13 according to an embodiment of the present invention. As shown in an enlarged part of the wearable sensing device 12 in Fig. 1, the wearable sensing device 12 is in contact with the upper half of the wearer's body. The wearable sensing device 12 includes a wearer's axle, A biosensor sheet 121 that covers a part of the back surface (for example, it may be the front surface of the chest and the back surface corresponding to the heart to the pericardium via left or right pneumothorax), and a biosensor 121 connected to the biosensor sheet 121, And a biosensor controller 122 located at the lower end of the chest back.

The biosensor sheet 121 of the wearable sensing device 12 is an integrated form of an electrocardiogram sensor, a blood pressure sensor, a body temperature sensor, and the like. The biosensor sheet 121 includes at least one of electrocardiogram, heart rate, body temperature, pulse, EMG, blood pressure, Biometric signals can be measured separately. The biosensor control unit 122 of the wearable sensing device 12 may include a wireless communication module, a processor, and an alarm module.

The wireless communication module can first measure the biometric signal (electrocardiogram, heart rate, body temperature, pulse, electromyogram, blood pressure, and breath amount) of the wearer and transmit it to the management server 13 have. The management server (13) which receives the bio-signal from the wearable sensing device (12) first allocates an identifier unique to the wearable sensing device (12), and transmits the data transmission cycle corresponding to the identifier and the identifier To the wireless communication module of the sensing device (12). In addition, the wireless communication module can receive the positional information of the user wearing the wearable sensing device 12 from the GPS satellite 11 (or access point) in real time upon receiving the identifier for the wearable sensing device 12. [

Then, the processor of the biosensor control unit 122 transmits the identifier, the positional information, and the measured bio-signal to the living body so that the wireless communication module can be transmitted to the management server 13 according to the received data transmission period It can be compressed and converted into a set of signal data. The set of converted biometric signal data is transmitted by the wireless communication module to the management server 13 at a data transmission period.

If the wearer of the wearable sensing device 12 is close to a predetermined dangerous area, the alarm module of the biosensor controller 122 may display a warning message Signal and position warning signals. The processor of the biosensor controller 122 further compresses and converts the positional warning signal, the identifier and the position signal into the warning signal data, and transmits a warning signal to the biosensor controller 122, The communication module can transmit the warning signal data to the management server. On the other hand, the warning indication signal may be triggered to alert the wearer of the wearable sensing device 12. For example, the warning indication signal may trigger the output of a pre-established voice message (e.g., "Hazardous area!") On the wearable sensing device 12.

In the meantime, although the management server 103 is shown in the form of a desktop in FIG. 1, the management server 103 is an exemplary one, and the management server 103 may be connected to the wearable sensing device 102, May be implemented by a communicatable user equipment (UE).

2 shows a functional block diagram of a wearable sensing device 12 according to an embodiment of the present invention. The wearable sensing device 12 includes a biosensor sheet 210 and a biosensor controller 220 for measuring at least one of biological signals of an electrocardiogram, heart rate, body temperature, pulse, EMG, blood pressure, .

The processor 221 of the biosensor control unit 220 functions to optimize data transmission from the wearable sensing device 102 to the management server. That is, the processor 221 compresses and converts the bio-signal measured in the biosensor sheet into a set of biosignal data along with the identifier and position information assigned to the wearable sensing device 12 according to the data transmission period. For example, if the data transmission period transmitted from the management server is 3 minutes, the wireless communication module 222 of the biosensor control unit 220 may transmit the data to the management server 222 at intervals of 3 minutes, The processor 221 compresses and converts the identifier, the position information, and the bio-signal.

The wireless communication module 222 of the biosensor control unit 220 performs a communication function between the wearable sensing device and the GPS satellite and the management server. Specifically, when the user wears the wearable sensing device for the first time and the biosensor sheet 210 first measures the biosignal, the first measured biosignal is transmitted to the management server. This is because the identifier for the wearable sensing device To receive a data transmission period. In addition, the wireless communication module 222 receives position information of wearer sensing device wearer from a GPS satellite or an access point. Further, the wireless communication module 222 transmits the set of biometric signal data converted by the processor 221 to the management server at a data transmission period.

The wireless communication module 222 may be a Wi-Fi, an ultra wideband (UWB), a Zigbee, a bluetooth communication module, and preferably a Zigbee communication module. In general, the Zigbee communication module has a lower data rate than the Bluetooth communication module, but it can be implemented with low power because of high node scalability, wide coverage, and the like. Therefore, the wearable sensing device to which the Zigbee communication module is applied can accommodate the number of persons less than the number of nodes that the Zigbee communication module can accommodate, can communicate in the coverage covering the total area of the nursing facility, and can be implemented with low power and low cost And the wireless communication module 222 may be a zigbee communication module.

The alarm module 223 of the biosensor control unit 220 functions to notify the wearer and the server manager of the wearer when the wearer is close to a dangerous area. In the management server, it is possible to set the hazardous area as an area to avoid access to the protected persons (for example, an area where an accident risk of the protected persons is high, an obstacle exists, or temporary repair work). After the danger zone is set, the alarm module 223 generates a warning indication signal and a position warning signal when a specific wearer approaches the danger zone (for example, within 1 m of the danger zone). When the alarm module 223 generates a warning display signal and a position warning signal, the processor 221 of the wearable sensing device further compresses and converts the position warning signal, the identifier and the position signal into warning signal data, Since the communication module 222 can transmit the warning signal data to the management server, the management server receives and decompresses the alarm signal data to determine which user is in an emergency close to the dangerous area, It can be grasped by the server.

3 shows a flowchart of a method for managing biometric data and detecting an emergency situation according to an embodiment of the present invention.

In step 31, when the wearer's biological signal is first received from the wearable sensing device, the management server can assign an identifier to the wearable sensing device. The biomedical signal may be at least one of electrocardiogram, heart rate, body temperature, pulse, electromyogram, blood pressure, and respiration as described in Fig. On the other hand, the management server is linked to the personal information database of the protected subject registered in the nursing home, and can identify the person by the identifier assigned to each wearable sensing device. Since each assigned identifier corresponds to a specific person recorded in the personal information database, the data transmission period can be set differently for each identifier.

In step 32, the management server may transmit to the wearable sensing device an identifier assigned in step 31 and a data transmission period suitable for the person corresponding to the identifier. For example, a person who is a protected subject in a nursing facility may have a longer period of data transmission than a person who is not healthy and has a dementia or cardiovascular disease for a relatively healthy person.

In step 33, the management server can receive a set of biometric signal data from the wearable sensing device every data transmission period.

In step 34, the management server may receive the warning signal data (when the wearable sensing device transmits the warning signal data).

In step 35, the management server decompresses the set of biometric signal data received in step 33 to convert it into an identifier, positional information, and biometric signal of the wearer to which the wearable sensing device is attached. In step 34, The warning signal data can be decompressed and converted into a position warning signal, an identifier, and a position signal of the wearer.

As a result, in step 33, a set of biometric signal data is received, and in step 35, it is converted into a wearer ' s identifier, positional information, and biometric signal, so that it can be output in tabular form through the display of the management server. On the other hand, in step 34, the warning signal data is received, and in step 35, it is converted into an identifier, a position signal, and a position warning signal of the wearer, The server manager of the facility management can notify the person wearing the wearable sensing device that the wearer is close to the dangerous area.

FIG. 4 shows an exemplary screen of a management server according to an embodiment of the present invention. The upper left region 410 on the screen of the management server displays a table according to the correspondence relationship between the identifier (ID) assigned to the wearable sensing device and the personal information database, and the lower region 420 of the region 410 displays The floor plan of the nursing facility is displayed and the area 430 on the right side of the management server screen displays the bio signal (that is, the electrocardiogram measured by the biosensor sheet and transmitted to the management server, the heart rate, the body temperature, , EMG, blood pressure, and respiration) are displayed.

  As shown in 410 of FIG. 4, if the identifier assigned to any wearable sensing device is "AB001 ", and the corresponding abbreviation in the nursing home is a 70 year old man, , Name, age, sex, etc., in the order of (410). In this form, an identifier may be assigned to each protected subject, so that it can be linked to a database of protected persons' personal information in a nursing facility.

Since the floor plan of the nursing home is displayed in the area 420, it is possible to know where each of the abbreviations in the nursing home is located by the location information transmitted from each wearable sensing device. 4 (421) indicates where Kim is located in the nursing home, indicated by the area indicated by 410 in the area. Also, when a dangerous area in the nursing facility is designated in the management server, it is possible to indicate in the area of the area (420) where the dangerous area is located (422).

In the area 430, the tabs 431, 432, 433, ..., and the like are displayed for each abbreviated person to be protected in the nursing home. Since the bio-signal for each identifier is received by the management server in the form of a set of bio-signal data for each data transmission period transmitted to each wearable sensing device, the bio-signal is stored in the identifier tab in the area (430) And may be updated in accordance with the transmission period.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, 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.

11: GPS satellite
12: wearable sensing device
13: Management server
121, 210: Biosensor sheet
122 and 220:

Claims (3)

A wearable sensing device which is brought into close contact with a wearer's upper body skin,
The wearable sensing device includes a biosensor sheet covering a part of a chest front surface and a part of a chest back surface with an axilla as a center and a biosensor control unit connected to the biosensor sheet and positioned at a lower end of the chest back surface,
Wherein the biosensor sheet is configured to measure at least one of biological signals of an electrocardiogram, a heart rate, a body temperature, a pulse, an EMG, a blood pressure, and a volume,
The biosensor control unit includes:
(ID) and a data transmission period from the management server when the biosensor sheet first measures the biomedical signal of the wearer and transmits the bio-signal to the management server, and receives a position of the wearer from the GPS satellite or the access point A wireless communication module that receives information in real time and transmits a set of biometric signal data to the management server at the data transmission period;
A processor for compressing and converting the identifier, the positional information, and the measured bio-signal into a set of bio-signal data so that the wireless communication module can transmit the data according to the data transmission period; And
And an alarm module for generating a warning display signal and a position warning signal when the position information is close to a dangerous area designated by the management server,
Wherein the processor further compresses and converts the position warning signal, the identifier and the position signal into warning signal data when the alarm module generates the warning indication signal and the position warning signal, To the management server,
Wearable sensing device.
The method according to claim 1,
Wherein the wireless communication module is a Zigbee communication module, and the biosensor control unit is a Zigbee communication module that is detachably attachable to the wearable sensing device,
Wearable sensing device.
A method for managing biometric data and detecting an emergency situation using a wearable sensing device and a management server,
Wherein the wearable sensing device includes a biosensor sheet covering a part of a chest front surface and a part of a chest back surface around an axilla and a biosensor control unit connected to the biosensor sheet and positioned at a lower end of the chest back surface, The biosensor sheet is configured to measure at least one of biological signals of an electrocardiogram, heart rate, body temperature, pulse, electromyogram, blood pressure, and respiratory volume,
The method comprises:
Assigning an identifier to the wearable sensing device when the wearable sensing device first receives a wearer's biometric signal from the wearable sensing device;
Transmitting the allocated identifier and a data transmission period to the wearable sensing device;
Receiving a set of biometric signal data from the wearable sensing device every data transmission period;
Receiving warning signal data from the wearable sensing device; And
And decompressing the warning signal data into a position warning signal, an identifier, and a position signal of the wearer, decompressing the received set of biosignal data, converting the biosignal data into a wearer's identifier, positional information, / RTI >
Managing biometric data and detecting an emergency situation.

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