KR20140050355A - Health care system including zero-configuration user perception and user health history management method using the same - Google Patents

Abstract

A heath management system including a zero-configuration user cognitive function, provided by the present invention, has technical characteristics of including: a physical index measuring instrument which transmits a wakeup signal which wakes up the state of a terminal possessed by a user into a wakeup state in the state of sleep, a low frequency (LF) signal for recognizing a direction and a physical distance between the physical index measuring instrument and the terminal possessed by the user, and a measured biological signal of a measured person; and the terminal possessed by the user who receives the biological signal, the wakeup signal, and the low frequency (LF) signal and transmits a received signal strength indication (RSSI) which corresponds to a terminal identification (ID) and the received low frequency (LF) signal through a bidirectional wireless communication with the physical index measuring instrument. [Reference numerals] (110) Physical index measuring instrument; (120a) First user terminal; (120b) Second user terminal; (a10,b10) Transmit a wakeup signal; (a20,b20) Convert into an activated state; (a30,b30) Operate a wireless communication unit; (a40,b40) Transmit a service advertisement message; (a50,b50) Transmit the ID and RSSI of a user terminal; (a60) Select a user terminal; (a70) Transmit measurement data; (a80,b80) Check a response message

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a health management system including a non-setting user recognition function and a user body information history management method using the same. 2. Description of the Related Art [0002]

The present invention relates to a health management system including a non-setting user recognition function and a user body information history management method using the same. More particularly, the present invention relates to a power management method for a user terminal, (RSSI) corresponding to a low frequency (LF) signal of a low frequency band is transmitted to a body index measuring device, so that information such as the physical distance and direction between the body index measuring device and the user terminal can be easily recognized Even if the user does not perform any operation on the user terminal, the bio-signal measured by the body index meter is automatically transmitted to the user terminal or transmitted to the operator server in the form of a packet in which the user ID is added to the measured bio- A non-setting user to manage the health of the user A health management system including a cognitive function, and a user body information history management method using the same.

In recent years, the desire to increase the quality of life has been increasing due to the rapid development of the economy level, and this desire is expressed with great interest in personal health.

On the other hand, as the overall health and medical conditions of medicine and medical devices including medical knowledge are greatly improved, the average life span is prolonged and the level of national health is steadily improving. However, with regard to changes in lifestyle such as industrialization, population aging and urbanization Chronic degenerative diseases such as adult diseases are rapidly increasing.

In recent years, these chronic degenerative diseases have been linked to personal lifestyle, and the best way to maintain personal health is consistent with routine care and routine checkups.

In particular, health-related contents based on information communication infrastructure and information communication technology have been widely spread in recent years, and they are anticipating the era of IT-BT (Information Technology-Bio Technology) convergence technology in earnest.

For example, the service area that has already been provided is gradually expanding, as it possesses a high-performance computing power device such as a smart phone and approaches the ubiquitous era of the network using such devices.

In particular, as the technology development and lifespan increase, the medical service industry has become more and more developed, and many devices have been invented to effectively provide such services.

However, in the conventional technology, most of the medical services fail to take advantage of the high-performance mobile terminal, and most of the users using the medical service are aged, so that there is a difficulty in operating the interface for the mobile terminal.

In addition, when medical services are provided using a communication method such as Wi-Fi, 802.15.4 MAC, or Bluetooth, there is a disadvantage in that the accuracy of position recognition for a mobile terminal is low in a narrow range of 0.1 m to 3 m .

That is, in the related art, complicated calculation is required to accurately measure the position of the mobile terminal. However, there is a limitation in performing the above calculation using a low-power microcontroller (MCU), and thus there are iron walls or obstacles There is a problem in that it is not suitable for application to the medical service provided in the room.

In addition, the prior art has a problem that power consumption becomes very large when a portable personal mobile terminal is provided with a medical service.

In other words, when the position is recognized using the generalized RF signal intensity, it is necessary to transmit / receive a large number of RF signals between the fixed device and the device for position recognition. Since the power consumption increases in proportion to the increase in the frequency of such transmission / reception, Which is much larger than the power consumption.

SUMMARY OF THE INVENTION The present invention provides a method and apparatus for efficiently managing power consumption of a user terminal through a wake up function of a user terminal, (RSSI) is transmitted to the body index measuring device, so that information such as the physical distance and direction between the body index measuring device and the user terminal can be easily recognized, and even if the user does not perform any operation operation on the user terminal, A health management system including a non-setting user recognition function for automatically receiving a bio-signal received by the user terminal or transmitting the measured bio-signal to a user server in the form of a packet with a user ID added thereto to manage the health of the user; To provide a method of managing user's body information using this have.

According to an aspect of the present invention, there is provided a health management system including a non-setting user recognition function, including a wake-up signal for waking up a state of a user terminal from a sleep state to a wake up state, A physical index measuring device for transmitting a low frequency (LF) signal for recognizing the physical distance and direction between the physical index measuring device and the user terminal, and a biological signal of the measured subject; And a controller for receiving the biological signal, the wake-up signal and the LF signal via bidirectional wireless communication with the body index measuring device and comparing the terminal ID and the received LF And a user terminal which transmits a Received Signal Strength Indication (RSSI) corresponding to a Low Frequency (RSSI) signal.

According to another aspect of the present invention, there is provided a method for managing a user's body information, including: waking up a wake-up signal from a sleep state to a wake- A first step of receiving a low frequency (LF) signal for recognizing the position of the terminal from the body index measuring device; A second step of switching an awake terminal from a sleep state to a wake up state by generating an interrupt after detecting the wake up signal; A third step of transmitting a received signal strength indicator (RSSI) and received signal direction information corresponding to the received LF (Low Frequency) signal to a body index measuring device; A fourth step of comparing a received signal strength indicator (RSSI) value with a received signal direction value to select a final user terminal; And a fifth step of transmitting measurement data of the subject to the selected user terminal.

The present invention has a technical effect of efficiently managing power consumption of a user terminal through a wake up function of the user terminal.

In addition, the present invention transmits a received RSSI corresponding to a low frequency (LF) signal of a low frequency band to a body index measuring device, thereby collecting position information such as physical distance and direction between the body index measuring device and the user terminal There is a technical effect that the position is easily recognized.

In addition, since the bio-signal measured by the body index measuring device can be automatically transmitted even if the user does not perform any operation on the user terminal, the user can more easily receive the body index history management There is a technical effect.

FIG. 1 illustrates a health management system including an unconfigured user awareness function according to the present invention.
FIG. 2A shows the configuration of the body index measuring instrument shown in FIG. 1 in detail.
FIG. 2B shows the configuration of the user terminal shown in FIG. 1 in detail.
FIG. 3 is a sequence diagram of a protocol for providing a healthcare service between the physical index measuring device of the present invention and a user terminal.
FIG. 4A shows a state diagram of the sequence diagram of the protocol of FIG. 3 operating in a body index measuring instrument.
FIG. 4B shows a state diagram of the sequence diagram of the protocol of FIG. 3 operating in the user terminal.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 illustrates a health management system including an unconfigured user awareness function according to the present invention.

Referring to FIG. 1, a health management system 100 including an unconfigured user recognition function according to the present invention includes a body index meter 110, a user terminal 120, and an operator server 130 .

The body index measuring device 110 measures a biological signal according to an electrical change, a biochemical change, a physical momentum, and an environment change of the body attached to or close to the body of the subject. At this time, the measured biological signal is transmitted to the user terminal 120 in a zero configuration manner.

Here, a biological signal means a complex medical data such as a blood pressure, a pulse rate, an electrocardiogram, a body temperature, and a weight of a subject.

 The zero configuration means that the measured medical data is automatically transmitted to the user terminal 120 even if the user does not perform any other operation on the user terminal 120.

For example, even if the user does not perform a separate operation on the user terminal 120, the user terminal 120 automatically wakes up in response to the service advertisement message transmitted from the body index meter 110 For example.

If the service is previously set for the corresponding service in the user terminal 120, the physical distance between the physical index measuring device 110 and the user terminal 120 and the directional prediction index are used to determine the user ID Identification and measurement data are interchanged.

The user terminal 120 receives bidirectional communication with the body index measuring device 110 and not only receives a biological signal measured by the body index measuring device 110 but also receives an ID unique to the user terminal 120 (Received Signal Strength Indication), and the like to the physical index measuring device 110. The physical index measuring device 110 measures the physical strength of the physical index.

In this case, the user terminal 120 uses a terminal capable of location-based wireless communication, such as a smart phone, a smart pad, an iPod, a PDA (Personal Digital Assistants) , A clock capable of implementing location-based wireless communication, a pair of glasses, and the like.

The operator server 130 performs bidirectional communication between the body index meter 110 and the user terminal 120 via a network and analyzes the final measurement data transmitted from the body index meter 110, And provides the health information requested to the user when there is a request for health information from the user terminal 120.

Here, the final measurement data refers to data transmitted with a packet structure including information such as a user ID, measurement data (such as blood pressure, blood sugar amount, body weight, etc.), measurement time,

The network used IEEE 802.15.4 MAC, blue tooth communication or Wi-Fi communication protocol for the present invention to build a wireless sensor network, but it is not limited to this, It is natural that the application can be performed.

Hereinafter, the configuration and functions of the body index measuring device 110 and the user terminal 120 constituting the core of the present invention will be described in detail with reference to FIGS. 2A and 2B.

FIG. 2A shows the configuration of the body index measuring instrument shown in FIG. 1 in detail.

2A, the physical index measuring device 110 of the present invention includes an input unit 111, a power source unit 112, a storage unit 113, a wireless communication unit 114, an RF antenna 115, an LF transmitting unit 116, An LF antenna 117 and a main controller 118. [

The input unit 111 is for inputting the medical data of the subject, and may be an input method in the form of a button, a pen input method, a touch input method, or the like.

The power supply unit 112 serves to supply power to the main controller unit 118, the wireless communication unit 114, the RF antenna 115, the LF transmitting unit 116, and the LF antenna 117.

The storage unit 113 stores medical data of the subject including various programs necessary for the operation of the main controller unit 118 and measured biological signals and the like.

The wireless communication unit 114 processes a signal transmitted and received through the RF antenna 115 and transmits the wireless communication signal to the wireless communication unit 114 such as Ethernet, Microwave Access, WiMAX), High Speed Packet Access (HSPA), Code Division Multiple Access (CDMA), and Bluetooth.

The RF antenna 115 transmits / receives a signal to / from an external communication device through radio frequency communication. In this case, the RF antenna 115 transmits an IEEE 802.15.4 MAC, a Bluetooth communication Or a Wi-Fi communication protocol may be used.

The LF transmitting unit 116 transmits data to the external user terminal 120 and includes a wake up signal for waking up the user terminal 120 to implement low power and a wake up signal for waking up the user terminal 120. [ And generates an LF (Low Frequency) signal for position recognition.

The LF antenna 117 transmits and receives signals through an LF (Low Frequency) communication in a low frequency band of 10 kHz to 150 kHz to an external user terminal 120.

The main controller unit (MCU) 118 controls the input unit 111, the power supply unit 112, the storage unit 113, the wireless communication unit 114, the RF antenna 115, the LF transmitting unit 116, and the LF antenna 117 do.

FIG. 2B shows the configuration of the user terminal shown in FIG. 1 in detail.

2B, the user terminal 120 of the present invention includes a charging unit 121, a storage unit 122, a wireless communication unit 124, an RF antenna 125, an LF receiving unit 126, an LF receiver antenna 127 ) And a main controller unit 128. [

The charging unit 121 includes a battery to charge the electric charge so that the user terminal 120 may operate without running out of electric charge.

The storage unit 122 stores various programs required for the operation of the main controller unit 128 and medical data transmitted from the physical index measuring unit 110. [

The wireless communication unit 124 processes a signal transmitted and received through the RF antenna 125 and transmits the signal through an Ethernet, a wireless broadband Internet (WiBro), a Wi-Fi, a WiMAX (World Interoperability for Microwave Access, WiMAX), High Speed Packet Access (HSPA), Code Division Multiple Access (CDMA), and Bluetooth.

The RF antenna 125 transmits and receives signals to and from an external communication device through radio frequency communication. In this case, the RF antenna 125 transmits an IEEE 802.15.4 MAC, a Bluetooth communication Or a Wi-Fi communication protocol may be used.

The LF receiving unit 126 receives a wake up signal for realizing the low power transmitted from the external body index gauge 110 and an LF signal for recognizing the position of the user terminal 120 do.

The LF receiving unit 126 senses an LF signal operated at a very low power of several microamperes and generates a predetermined wake up interrupt corresponding to the sensed LF signal, The main controller unit 128 switches the wireless communication unit 124 which is normally in a sleep state to a wake up state according to the interrupt.

In this case, the LF (Low Frequency) signal is transmitted in the frequency band of 10kHz ~ 150kHz, the distance between the signal transmitter and the receiver is within 1m ~ 10m, (X, y, z) between the user terminal 110 and the user terminal 120.

On the other hand, when the LF receiving unit 126 receives an LF (Low Frequency) signal for three-dimensional position recognition of the user terminal 120 from the physical index measuring unit 110, the LF receiving unit 126 receives the LF RSSI).

On the other hand, the measured RSSI is transmitted to the body index measurer 110 through the wireless communication unit 124 according to a predetermined control of the main controller 128.

The LF receiver antenna 127 transmits and receives a signal through an LF (Low Frequency) communication with an external body index gauge 110.

The main controller unit (MCU) 128 controls the charging unit 121, the storage unit 122, the wireless communication unit 124, the RF antenna 125, the LF receiving unit 126 and the LF receiver antenna 127.

FIG. 3 is a sequence diagram of a protocol for providing a healthcare service between the physical index measuring device of the present invention and a user terminal.

3, a method of providing a healthcare service between the physical index measuring device 110 of the present invention and a plurality of user terminals 120a and 120b will be described.

First, when the first and second user terminals 120a and 120b are turned on and are located adjacent to each other, the physical index measuring device 110 measures the first user terminal 120a and the second user terminal 120b And a step (a10, b10) of transmitting each wake-up signal.

In the next step, the first and second user terminals 120a and 120b sense a wake-up signal through each LF receiver 126, generate a predetermined interrupt, (a20, b20) of switching the respective states from a sleep state to a wake up state.

The steps a30 and b30 of activating each of the wireless communication units 124 constituting the first and second base user terminals 120a and 120b so that the wireless communication unit 124 is activated, .

In the next step, the body index measuring device 110 has a step (a40, b40) of transmitting a corresponding service advertisement message to the first and second user terminal 120a, 120b when a service event occurs .

Here, a service event means a service advertisement message to be provided to a user.

In the next step, the first and second base user terminals 120a and 120b transmit identification information, received signal strength indication (RSSI), and received signal direction information unique to each terminal to the body index measurer 110 (A50, b50).

In the next step, the body index measuring device 110 compares the Received Signal Strength Indication (RSSI) value and the received signal direction value transmitted from the first and second user terminals 120a and 120b, And a physical index between the physical index measuring device and the state of the user terminal, and selecting a user terminal which satisfies the optimal communication state.

For example, if the first RSSI value transmitted from the first user terminal 120a is greater than the second RSSI value transmitted from the second user terminal 120b, If the states are the same, the physical index measuring device 110 selects the first user terminal 120a.

As a next step, the body index measuring instrument 110 has a step (a70) of transmitting measurement data to the selected first user base terminal 120a.

As a final step, the first user terminal 120a has a step (a80) of checking a response message confirming that the measurement data has been transmitted, and the second user terminal 120b has not received the measurement data And a step (b80) of checking a response message for confirming.

Hereinafter, with reference to FIG. 4A and FIG. 4B, the state executed in each step of FIG. 3 will be described in detail with reference to a state of operation in the body mass index meter and the user terminal.

FIG. 4A shows a state diagram of the sequence diagram of the protocol of FIG. 3 operating in a body index measuring instrument.

Referring to FIG. 4A, when the user presses the start switch of the body index measuring instrument 110 to measure the body index of the subject such as blood pressure, weight, etc., the IDLE state is changed from the initial IDLE state to the service use state .

When the service use state is reached, the physical index measuring unit 110 transmits a wake up signal and a service advertisement message to the user terminal 120.

The body index measuring device 110 receives the ID and the RSSI of the terminal from the user terminal 120 and confirms the ID and the location of the user terminal 120.

If a service request signal is received from the user terminal 120, the body index measuring device 110 is changed to a service successful state and transmits the measurement data requested to the user terminal 120.

On the other hand, when communication with the user terminal 120 is not performed, the body index meter 110 is changed to a service failure state, and a service failure message is transmitted to the user terminal 120, (110) is changed to an idle state.

FIG. 4B shows a state diagram of the sequence diagram of the protocol of FIG. 3 operating in the user terminal.

4B, upon receiving a wake-up signal and a low frequency (LF) signal of a low frequency band from the body index measuring device 110, the user terminal 120 senses a wake- A wake up interrupt is generated corresponding to the signal so that the wake up state is normally changed from a sleep state to a wake up state.

Meanwhile, in the wake up state, the user terminal 120 measures the RSSI corresponding to the received LF (Low Frequency) signal to be used for position recognition.

The main controller unit (MCU) 128 awaken in the wake up state checks whether the service is activated and initializes a wake-up interrupt when the service is inactive. To the initial idle state.

On the other hand, when the service is active, the main controller unit (MCU) 128 checks whether or not the service is activated so that the wireless communication unit 124 is activated to receive the service advertisement message from the physical index measuring unit 110 From this time, the user terminal 120 is changed to the service request state.

In the service request state, the user terminal 120 transmits the RSSI corresponding to the LF (Low Frequency) signal and the ID unique to the terminal to the body index measurer 110.

If the response message received from the physical index measuring unit 110 includes measurement data, the user terminal 120 is changed to a service active state to display measurement data.

On the other hand, if the response message received from the physical index measuring unit 110 does not include measurement data or if there is no response for a predetermined time, i.e., time out, the user terminal 120 changes to a service inactive state Initializes a wake-up interrupt, and deactivates the wireless communication unit 124 to return to an initial idle state.

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. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention.

110: body index measuring instrument
111: input unit 112: power supply unit 113:
114: wireless communication unit 115: RF antenna
116: LF transmitting unit 117: LF antenna
118: Main controller unit (MCU)
120: User terminal
121: charging unit 122: storage unit
124: wireless communication unit 125: RF antenna
126: LF receiver 127: LF receiver antenna
128: Main controller unit (MCU)
130: Operator server

Claims (11)

Wake up signal to wake up the state of user's terminal from sleep state to wake up state, Low frequency signal to recognize physical distance and direction between body index meter and user's terminal And a body index measuring instrument for transmitting the measured biological signal of the measured subject; And
Receiving the biological signal, the wake up signal and the low frequency signal through two-way wireless communication with the body index meter,
And a user possessing terminal for transmitting a received signal strength indication (RSSI) corresponding to a terminal identification and the received low frequency signal. Health care system. [2] The apparatus of claim 1,
An input unit for inputting medical data of a subject;
An RF antenna that transmits and receives a signal through radio frequency communication with an external communication device;
A wireless communication unit for processing signals transmitted and received through the RF antenna;
An LF antenna for transmitting and receiving signals through an LF (Low Frequency) communication with an external communication device;
A LF transmitter for transmitting the wake-up signal and the LF signal to the user terminal; And
And a main controller for controlling the input unit, the RF antenna, the wireless communication unit, the LF antenna, and the LF transmission unit. The terminal as claimed in claim 1,
An RF antenna that transmits and receives a signal through radio frequency communication with an external communication device;
A wireless communication unit for processing signals transmitted and received through the RF antenna;
An LF receiver antenna for transmitting and receiving signals through an LF (Low Frequency) communication with an external communication device;
An LF receiving unit receiving the wake up signal and the LF signal from the body index measuring unit; And
And a main controller unit for controlling the RF antenna, the wireless communication unit, the LF receiver antenna, and the LF receiving unit. The apparatus of claim 1, wherein the LF (Low Frequency)
Wherein the signal is transmitted in a frequency band of 10 kHz to 150 kHz and the distance between the signal transmitter and the receiver is within 1 m to 10 m. The wireless communication system according to claim 1,
Wherein the wireless network uses an IEEE 802.15.4 MAC, a Bluetooth wireless communication or a Wi-Fi communication protocol. The method of claim 1,
Managing the health information of the subject by analyzing the final measurement data transmitted from the body index measuring device to the user terminal or the operator server and providing the requested health information to the user when the health information is requested from the user terminal And an operator server. ≪ Desc / Clms Page number 20 > 7. The method of claim 6,
And a packet structure including a user ID, measurement data, a measurement time, and measurement device ID information. Receive a wake up signal for waking up the state of the user terminal from sleep to wake up state and a Low Frequency (LF) signal for recognizing the location of the user terminal. First step;
A second step of generating an interrupt after detecting the wake up signal to switch the user-owned terminal from a sleep state to an active state;
Transmitting a user possession terminal identification (ID), a received signal strength indication (RSSI) corresponding to the received low frequency (LF) signal, and received signal direction information to a body index analyzer;
A fourth step of selecting a terminal having a final user by comparing a received signal strength indication (RSSI) value with a received signal direction value; And
And a fifth step of transmitting the measurement data of the subject to the selected user's mobile terminal. 9. The method according to claim 8,
Further comprising the step of waking up the wireless communication unit constituting the user terminal and receiving a service advertisement message from the body index measuring unit. 9. The method of claim 8,
Wherein the user information is transmitted in a zero configuration mode in which the user is automatically transmitted even if the user does not perform any operation on the user terminal. The method of claim 10,
By the zero configuration method,
The system may automatically wake up the user terminal in response to a service advertisement message transmitted from the body index measuring device or may exchange user identification and measurement data between the body index measuring device and the user terminal. Wherein the user information is stored in the storage unit.

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