KR101332443B1 - Communication module for electrocardiogram data and ecg measuring system using the same - Google Patents

Abstract

The present invention relates to a relay type communication module, and more particularly, in a wireless electrocardiogram measuring system, a relay type communication module for communicating with an electrocardiogram measuring module and a server, comprising: a receiver configured to wirelessly transmit electrocardiogram data from the electrocardiogram measuring module; And a communicator configured to receive the electrocardiogram data by connecting to the receiver, recognize a user identification code, classify the received electrocardiogram data, and transmit the classified electrocardiogram data to the server, wherein the communicator uses Wi-Fi. Including the Wi-Fi module capable of data communication, the configuration of the communication with the server is characterized by its configuration.
In addition, the present invention relates to a wireless electrocardiogram measuring system, and more specifically, an electrocardiogram measuring module capable of measuring the user's electrocardiogram and short-range communication; A relay communication module for receiving electrocardiogram data from the electrocardiogram measurement module; And a server receiving ECG data classified for each user identification code from the relay communication module, wherein the relay communication module includes: a receiver configured to wirelessly transmit ECG data from the ECG measurement module; In connection with the receiving unit receives the ECG data, and recognizes the user identification code to classify the received ECG data, and includes a communication unit for transmitting the classified ECG data, the communication unit using Wi-Fi It is characterized in that the configuration of the communication with the server, including a WiFi module capable of data communication.
According to the relay type communication module and the wireless electrocardiogram measuring system for communicating the electrocardiogram data proposed by the present invention, by including a communication unit for classifying the received electrocardiogram data by recognizing the user identification code and transmitting the electrocardiogram data classified to the server, ECG data storage can be facilitated and data can be utilized efficiently.
Further, according to the present invention, by using a relay type communication module including a communication unit for performing communication with the server, including a Wi-Fi module capable of data communication using Wi-Fi, the recording device or the long-distance communication module is mounted in the ECG module It is not necessary to increase portability, and as a relay type communication module, it is not necessary to use a communication device such as a mobile phone, thereby solving the burden of excessive communication charges caused by this, and simplifying the configuration of the wireless ECG measurement system. can do.

Description

Relay type communication module for communicating electrocardiogram data and wireless electrocardiogram measuring system using same {COMMUNICATION MODULE FOR ELECTROCARDIOGRAM DATA AND ECG MEASURING SYSTEM USING THE SAME}

The present invention relates to a relay type communication module and a wireless electrocardiogram measuring system using the same, and more particularly, to a relay type communication module using a wifi module and a wireless electrocardiogram measuring system using the same.

In the conventional medical environment, the measurement of the biosignals was possible only when the medical personnel were together in the same space at the same time as the patient. It is possible to measure the bio-signals in the unconstrained state, and in recent years, it has been extended to the concept of 'ubiquitous healthcare'. This concept is further developed to allow the patient to measure and transmit signals to medical institutions, etc., while the patient is on the move or in everyday life, to receive appropriate medical services. ',' Independence 'bio-signal measurement is increasing interest.

Representatives include 'health phone' that measures and transmits bio signals such as blood sugar and blood pressure, u-healthcare pilot project using PDA for elderly people living alone in small area, and connect external measuring device to mobile phone for health care. There is one thing. In particular, the implementation of a system based on wearable computing technology in the form of a compact sensor, signal processing device and information device in the patient's clothing will serve as a catalyst for rapidly integrating the future ubiquitous environment into the medical environment. The ripple effect on related industries is also expected to be very large. Life shirts, which look like a vest, automatically collect various biosignal data when they are dressed as clothes, and transmit them to remote medical institutions. In addition, 'half-type health meter' and bio-shirts using functional fiber for chronic diseases are being promoted as a pilot project.

In general, the measurement of ECG signals is performed by an ECG monitor inside a hospital and a Holter ECG outside the hospital. The ECG monitor inside the hospital is transmitted to a central monitor located in the hospital by a local wired or wireless communication network and uses a method of monitoring the central monitor. The Holter electrocardiograph used outside the hospital can be used for 24 hours and 48 hours or longer to measure the cardiogram of the patient and to detect the ECG. It is a device for analyzing abnormal signals.

Meanwhile, with the recent development of communication technology, technologies for transmitting ECG signals wirelessly to a remote site have been developed. The real-time biosignal monitoring system using a conventional wireless communication network directly embeds a public wireless communication device in an ECG measuring device. It is related to the technology of transmitting to the monitoring server, and continuously monitors the biological signal and transmits it to the remote place only when an abnormal signal occurs from it. However, to detect bio signals in real time, the ECG measuring and transmitting device must be small and light enough to be portable, and power consumption must be considered.

Therefore, development of a relay type communication module for communicating an ECG module and a server using wireless is required. Accordingly, the present inventors have simplified the configuration of the system, it is easy for the user to carry the measuring device, and to develop a relay type communication module that does not require additional equipment such as a mobile phone.

The present invention has been proposed to solve the above problems of the conventionally proposed methods, by including a communication unit for classifying the received ECG data by recognizing the user identification code and transmitting the ECG data classified to the server, ECG data It is an object of the present invention to provide a relay type communication module and a wireless electrocardiogram measuring system for communicating electrocardiogram data, which can facilitate storage and efficiently utilize data.

In addition, the present invention, by using a relay type communication module including a communication unit for performing communication with the server, including a Wi-Fi module capable of data communication using Wi-Fi, a recording device or a long distance communication module to be mounted in the ECG module This eliminates the need for high portability, and eliminates the need for a separate communication device, such as a mobile phone, to solve the burden of excessive communication charges and simplify the configuration of a wireless ECG measurement system. Another object is to provide a relay type communication module for communicating electrocardiogram data and a wireless electrocardiogram measuring system.

Relay communication module for communicating electrocardiogram data according to a feature of the present invention for achieving the above object,

In a wireless electrocardiogram measuring system, a relay communication module for communicating with the electrocardiogram measuring module and the server,

A receiver for wirelessly transmitting electrocardiogram data from the electrocardiogram measuring module;

And a communication unit configured to access the electrocardiogram data by connecting to the receiver, recognize a user identification code, classify the received electrocardiogram data, and transmit the classified electrocardiogram data to the server.

Wherein,

Including a Wi-Fi module capable of data communication using Wi-Fi is characterized in that the configuration of the communication with the server.

Preferably, the receiving unit,

UHF band antenna capable of omni-directional reception;

A low noise amplifier for amplifying a signal received through the antenna; And

It may include a surface elastic filter for filtering the amplified signal.

Preferably, the communication unit,

A decoder which extracts only electrocardiogram data from the received signal;

A storage unit which stores user identification information and codes input or received from the outside; And

It may include an encoder for generating a frame conforming to the standard so that the stored user information and the received electrocardiogram data can be transmitted to the server.

Preferably, the communication unit,

A display unit for displaying a device operating state including a network connection state, a connection state with the server, and the ECG data display state;

A serial port for connecting to a personal computer (PC);

A connector for connecting with the receiver; And

It may include a power adapter.

Preferably, the communication unit,

When the program of the server is in operation standby, the server may automatically access the data and transmit the data.

Preferably, the relay communication module,

When transmitting data to the server, it is possible to transmit data giving a number of packets.

More preferably, the packet,

Data including a 7-byte header, 120 bytes of actual data, and 6 bytes of timer data may be sent bundled into one packet.

Wireless ECG measurement system according to a feature of the present invention for achieving the above object,

An electrocardiogram measurement module for measuring an electrocardiogram of a user and performing short-range communication;

A relay communication module for receiving electrocardiogram data from the electrocardiogram measurement module; And

Including a server receiving the ECG data classified for each user identification code from the relay communication module,

The relay communication module,

A receiver for wirelessly transmitting electrocardiogram data from the electrocardiogram measuring module;

And a communication unit connected to the receiving unit to receive the electrocardiogram data, recognize a user identification code, classify the received electrocardiogram data, and transmit the classified electrocardiogram data to the server.

Wherein,

Including a Wi-Fi module capable of data communication using Wi-Fi is characterized in that the configuration of the communication with the server.

Preferably, the ECG measurement module,

The patch may be attached to the skin of the user to measure the electrocardiogram of the user and transmit the measured electrocardiogram signal to the relay communication module in a short range.

Preferably, the ECG measurement module,

Patch pads in contact with the body of the user;

An analog signal processor for amplifying and removing noise of an ECG signal input through the patch pad;

A digital signal processing unit for digitally converting the analog signal output from the analog signal processing unit into electrocardiogram data and processing the electrocardiogram data into data for short-range transmission; And

It may include a UHF transmitter for short-range transmission of the electrocardiogram data processed into the short-range transmission data to the relay communication module.

Preferably, the receiving unit of the relay communication module,

UHF band antenna capable of omni-directional reception;

A low noise amplifier for amplifying a signal received through the antenna; And

It may include a surface elastic filter for filtering the amplified signal.

Preferably, the communication unit of the relay communication module,

A decoder which extracts only electrocardiogram data from the received signal;

A storage unit which stores user identification information and codes input or received from the outside; And

It may include an encoder for generating a frame conforming to the standard so that the stored user information and the received electrocardiogram data can be transmitted to the server.

Preferably, the communication unit of the relay communication module,

A display unit for displaying a device operating state including a network connection state, a connection state with the server, and the ECG data display state;

A serial port for connecting to a personal computer (PC);

A connector for connecting with the receiver; And

It may include a power adapter.

Preferably, the communication unit of the relay communication module,

When the program of the server is in operation standby, the server may automatically access the data and transmit the data.

Preferably, the relay communication module,

When transmitting data to the server, it is possible to transmit data giving a number of packets.

More preferably, the packet,

Data including a 7-byte header, 120 bytes of actual data, and 6 bytes of timer data may be sent bundled into one packet.

Preferably, the server,

The ECG data classified by the user identification code may be received and displayed in real time, the data may be divided and stored by user and time, and the stored ECG data may be called and output in real time.

According to the relay type communication module and the wireless electrocardiogram measuring system for communicating the electrocardiogram data proposed by the present invention, by including a communication unit for classifying the received electrocardiogram data by recognizing the user identification code and transmitting the electrocardiogram data classified to the server, ECG data storage can be facilitated and data can be utilized efficiently.

Further, according to the present invention, by using a relay type communication module including a communication unit for performing communication with the server, including a Wi-Fi module capable of data communication using Wi-Fi, the recording device or the long-distance communication module is mounted in the ECG module It is not necessary to increase portability, and as a relay type communication module, it is not necessary to use a communication device such as a mobile phone, thereby solving the burden of excessive communication charges caused by this, and simplifying the configuration of the wireless ECG measurement system. can do.

1 is a diagram illustrating a relay communication module for communicating electrocardiogram data according to an embodiment of the present invention communicating with a server using Wi-Fi.
2 is a diagram illustrating a receiver in a relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention.
3 is a diagram illustrating a communication unit including a Wi-Fi module capable of data communication using Wi-Fi in the relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention.
4 is a diagram illustrating a communication unit including a Wi-Fi module capable of data communication using Wi-Fi in the relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention.
5 is a view showing the appearance of a relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention.
6 is a diagram illustrating a configuration example of a Wi-Fi module 301 in the relay communication module 300 according to an embodiment of the present invention.
FIG. 7 illustrates a Wi-Fi data packet transmitted from a relay communication module for communicating electrocardiogram data according to an embodiment of the present invention. FIG.
8 is a diagram illustrating a wireless ECG measuring system according to an embodiment of the present invention.
9 is a diagram illustrating a process of processing a measured signal of an electrocardiogram measurement module in an electrocardiogram measurement system according to an embodiment of the present invention.
10 is a diagram illustrating a process of performing an electrocardiogram measuring system according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The same or similar reference numerals are used throughout the drawings for portions having similar functions and functions.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

FIG. 1 is a diagram illustrating a relay communication module for communicating electrocardiogram data according to an embodiment of the present invention communicating with a server using Wi-Fi. As shown in FIG. 1, the relay type communication module 100 for communicating electrocardiogram data according to an embodiment of the present invention includes a receiver 200 and a receiver configured to wirelessly transmit electrocardiogram data from an electrocardiogram measuring apparatus 10. And a communicator 300 to receive electrocardiogram data in connection with the 200, classify the received electrocardiogram data by recognizing a user identification code, and transmit the classified electrocardiogram data to the server 20. The Wi-Fi module 301 may perform communication with the server 20 including a Wi-Fi module 301 capable of data communication using Wi-Fi. Hereinafter, each configuration will be described in detail.

2 is a diagram illustrating a receiver in a relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention. As shown in FIG. 2, in the relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention, the receiver 200 receives the electrocardiogram data wirelessly from the electrocardiogram measurement module 10 and is omnidirectional. A UHF band antenna 210 capable of reception, a low noise amplifier 220 to amplify a signal received through the antenna, and a surface elastic filter 230 to filter the amplified signal may be configured.

The communicator 300 may be connected to the receiver 200 to receive electrocardiogram data, recognize a user identification code, classify the received electrocardiogram data, and transmit the classified electrocardiogram data to the server 20. The server 20 ), Data transmission is possible via Wi-Fi data communication. In the case of the Zigbee communication method, a separate communication device such as a mobile phone is required and excessive communication charges may be generated. However, when using Wi-Fi through the Wi-Fi module according to the present invention, such a problem may be solved.

3 is a diagram illustrating a communication unit including a Wi-Fi module capable of data communication using Wi-Fi in the relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention. As shown in FIG. 3, in the relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention, the communication unit 300 includes a Wi-Fi module 301 and a decoder 302 which extracts only electrocardiogram data from a received signal. ), A storage unit 303 for storing user identification information and codes input or received from the outside, and an encoder for generating a frame conforming to the standard so that the stored user information and the received ECG data can be transmitted to the server 20 ( 304). The decoder 302 preferably uses a u-processor that is convenient to decode signals received by asynchronous communication and can be miniaturized with low power, and can also be equipped with a simple digital signal processing algorithm.

4 is a diagram illustrating a communication unit including a Wi-Fi module capable of data communication using Wi-Fi in the relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention. As shown in FIG. 4, the communication unit 300 includes a display unit 305 for displaying a device operating state including a network connection state, a connection state with the server 20, and an electrocardiogram data display state, and a personal computer (PC). It may further include a serial port 306 to connect, a connection connector 307 and a power adapter 308 for connecting to the receiver 200.

5 is a diagram illustrating an appearance of a relay communication module for communicating electrocardiogram data according to an embodiment of the present invention. As shown in Figure 5, looking at the appearance of the relay type communication module 300 for communicating electrocardiogram data according to an embodiment of the present invention, the display unit 305 may include three LED windows, one A window showing the network connection status. The red light indicates that the connection is established, and when it is turned off, it indicates that the connection is lost. In addition, the second window indicates a connection state with the server 20, and the server and the green light may be turned on or off, and finally, the electrocardiogram (ECG) data display state may be implemented by checking the blinking red light. . In addition, data default and Wi-Fi environment can be set through the switch on the right side, and a serial port 306, a receiver connection connector 307, a power adapter (5v 1A or more), and a battery power switch that can be connected to a computer at the bottom are provided. It may be provided.

Specifically, referring to FIG. 5, an operation example of the relay communication module 300 according to an embodiment of the present invention will be described. When the 5V DC adapter is connected, the display unit displaying the data display plaque blinks, and the Wi-Fi setting is performed. If you need to, set the switch on the left side down and connect it to your PC using a cable on the serial port. When the Wi-Fi setting is completed, if the power is turned on after connecting the receiver 200 to the connection connector, data transmission may be performed. According to an exemplary embodiment, when the program of the server 20 is in operation standby, the server 20 may be automatically connected to the server to transmit data. In addition, when the program of the server is not running, the green light of the middle LED of the device appears to turn off, and when the program of the server 20 is operated again in this state, the server 20 is automatically connected to transmit data Can be.

6 illustrates an example of a configuration of the Wi-Fi module 301 in the relay communication module 300 according to an embodiment of the present invention. The Wi-Fi module 301 may be configured as shown in FIG. 6. However, this is in accordance with an embodiment and is not limited thereto.

7 is a diagram illustrating a Wi-Fi data packet transmitted from a relay type communication module for communicating electrocardiogram data according to an embodiment of the present invention. As shown in FIG. 7, the Wi-Fi data packet transmitted from the relay type communication module 100 for communicating electrocardiogram data according to an embodiment of the present invention includes a header of 7 bytes, actual data of 120 bytes, and 6 bytes. A total of 133 bytes of data, including timer data, can be transmitted in a single packet. The timer value is measured when the order of data is 40, 80, and 120. If the communication between the transceivers is normal, timer1, timer2 , the interval between timer3 should be constant. If the network between the Wi-Fi module and the router is normal, the sequence number of the received header is increased by one. In addition, it is possible to facilitate the processing of data by transmitting data to which a packet number is assigned when transmitting data to a server.

8 is a diagram illustrating a wireless ECG measurement system according to an embodiment of the present invention. As shown in FIG. 8, the wireless electrocardiogram measuring system according to an embodiment of the present invention transmits electrocardiogram data from an electrocardiogram measurement module 10 and an electrocardiogram measurement module 10 capable of measuring a user's electrocardiogram and performing short-range communication. It may be configured to include a server 20 for receiving the ECG data classified by the user identification code from the receiving relay communication module 100 and the relay communication module 100. The relay type communication module 100 is connected to the receiver 200 and the receiver 200 receiving the electrocardiogram data wirelessly from the electrocardiogram measurement module 10, receives the electrocardiogram data, and recognizes the user identification code. It may be configured to include a communication unit 300 for classifying the data, and transmits the ECG data classified to the server (20).

The electrocardiogram measurement module 10 is a patch type and is attached to the skin of the user to measure the electrocardiogram of the user, and transmits the measured electrocardiogram signal to the relay communication module 100 in a short range. According to the embodiment, the patch pad 11 in contact with the user's body, the analog signal processor 12 for performing the amplification and noise removal of the ECG signal input through the patch pad 11, the analog signal processor ( The digital signal processor 13 digitally converts the analog signal outputted by 12) into electrocardiogram data, and processes the electrocardiogram data into data for short-range transmission, and relays the electrocardiogram data processed into short-range transmission data. It may be configured to include a UHF transmitter 14 for transmitting in the near field. The ECG signal in the patch can be measured by attaching an electrode to the chest using Eintoban trigonometry. By configuring the electrocardiogram measurement module 10 in a patch type, the user does not disturb the daily life while actually using the portable, there is an advantage that the user can minimize the inconvenience of measuring the ECG signal. The ECG measurement module 10 is preferably designed with a focus on miniaturization and low power.

8 is a diagram illustrating a process of processing a measured signal of an electrocardiogram measurement module in an electrocardiogram measurement system according to an embodiment of the present invention. As shown in FIG. 8, an electrocardiogram measurement according to an embodiment of the present invention. In the system, the ECG measurement module 10 acquires an ECG signal in an analog form, thereby measuring an instrumentation amplifier, a unit gain amplifier, a high pass filter, and a main amplifier. .), Low pass filter, voltage follower, and A / D converter to amplify and remove noise (channel noise, 60 Hz noise, dynamic noise, etc.) And it can be converted into a digital signal and transmitted to the relay communication module 100.

The relay type communication module 100 may include a receiver 200 and a communicator 300, and the communicator 300 may include a Wi-Fi module 301 capable of data communication using Wi-Fi and a server. Communication may be implemented, which is similar to that described above with respect to the relay type communication module 100, and thus a detailed description thereof will be omitted.

The server 20 calls the display unit 21 for receiving ECG data classified for each user identification code and displays the data in real time, a storage unit 22 for storing data for each user and time, and calling the stored ECG data. It may be configured to include an output unit 23 for output in real time. The server 20 may be stored in a hospital or the like so that the therapist (doctor) may check the state of the user (patient) in real time.

9 is a diagram illustrating a process of performing an electrocardiogram measuring system according to an embodiment of the present invention. As shown in FIG. 9, in an electrocardiogram measurement system according to an embodiment of the present invention, an electrocardiogram measurement module 10 is attached to a heart portion of a user, and the measured electrocardiogram data is transmitted to the relay type communication module 100. The ECG data classified as the server 20 may be transmitted from the relay communication module 100. The relay communication module 100 may be configured to include a communication unit 300 including a receiver 200 and a Wi-Fi module according to an embodiment.

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics of the invention.

10: ECG module 11: patch pad
12: analog signal processing unit 13: digital signal processing unit
14: UHF transmitter 20: server
21: display unit 22: storage unit
23: output unit 100: relay type communication module
200: receiver 210: UHF band antenna
220: low noise amplifier 230: surface elastic filler
300: communication unit 301: Wi-Fi module
302: decoder 303: storage unit
304: encoder 305: display unit
306: serial port 307: connection connector
308: power adapter

Claims (17)

In a wireless electrocardiogram measuring system, a relay communication module for communicating with the electrocardiogram measuring module and the server,
A receiver for wirelessly transmitting electrocardiogram data from the electrocardiogram measuring module;
And a communication unit configured to access the electrocardiogram data by connecting to the receiver, recognize a user identification code, classify the received electrocardiogram data, and transmit the classified electrocardiogram data to the server.
Wherein,
Including a Wi-Fi module capable of data communication using the Wi-Fi to perform communication with the server, and automatically connects to the server and transmits data when the program of the server is in standby,
The relay communication module transmits the data to which the packet number is assigned to the server when the data is transmitted.
And the packet is transmitted in a bundle including one header, actual data, and timer data, and transmitting ECG data.
The method of claim 1, wherein the receiving unit,
UHF band antenna capable of omni-directional reception;
A low noise amplifier for amplifying a signal received through the antenna; And
And a surface elastic filter for filtering the amplified signal.
The method of claim 1, wherein the communication unit,
A decoder which extracts only electrocardiogram data from the received signal;
A storage unit which stores user identification information and codes input or received from the outside; And
And an encoder for generating a frame conforming to a specification so as to transmit the stored user information and the received electrocardiogram data to the server.
The method of claim 1, wherein the communication unit,
A display unit for displaying a device operating state including a network connection state, a connection state with the server, and the ECG data display state;
A serial port for connecting to a personal computer (PC);
A connector for connecting with the receiver; And
A relay type communication module for communicating electrocardiogram data, characterized in that it comprises a power adapter.
delete delete The method of claim 1, wherein the packet,
7. A relay communication module for communicating electrocardiogram data, characterized in that data including a header of 7 bytes, actual data of 120 bytes, and timer data of 6 bytes are bundled and transmitted in one packet.
As a wireless ECG system,
An electrocardiogram measurement module for measuring an electrocardiogram of a user and performing short-range communication;
A relay communication module for receiving electrocardiogram data from the electrocardiogram measurement module; And
Including a server receiving the ECG data classified for each user identification code from the relay communication module,
The relay communication module,
A receiver for wirelessly transmitting electrocardiogram data from the electrocardiogram measuring module;
And a communication unit connected to the receiving unit to receive the electrocardiogram data, recognize a user identification code, classify the received electrocardiogram data, and transmit the classified electrocardiogram data to the server.
Wherein,
Including a Wi-Fi module capable of data communication using the Wi-Fi to perform communication with the server, and automatically connects to the server and transmits data when the program of the server is in standby,
The relay communication module transmits the data to which the packet number is assigned to the server when the data is transmitted.
And the packet is transmitted in a bundle including one header, actual data, and timer data.
The electrocardiogram measuring module according to claim 8,
A patch type, attached to the skin of the user to measure the electrocardiogram of the user, characterized in that for transmitting the measured electrocardiogram signal to the relay communication module, the wireless ECG system.
According to claim 8, The ECG module is,
Patch pads in contact with the body of the user;
An analog signal processor for amplifying and removing noise of an ECG signal input through the patch pad;
A digital signal processing unit for digitally converting the analog signal output from the analog signal processing unit into electrocardiogram data and processing the electrocardiogram data into data for short-range transmission; And
And a UHF transmitter for short-range transmission of electrocardiogram data processed into the short-range transmission data to the relay communication module.
The method of claim 8, wherein the receiving unit of the relay communication module,
UHF band antenna capable of omni-directional reception;
A low noise amplifier for amplifying a signal received through the antenna; And
And a surface elastic filter for filtering the amplified signal.
According to claim 8, Communication unit of the relay communication module,
A decoder which extracts only electrocardiogram data from the received signal;
A storage unit which stores user identification information and codes input or received from the outside; And
And an encoder configured to generate a frame conforming to a specification so that the stored user information and the received electrocardiogram data can be transmitted to the server.
According to claim 8, Communication unit of the relay communication module,
A display unit for displaying a device operating state including a network connection state, a connection state with the server, and the ECG data display state;
A serial port for connecting to a personal computer (PC);
A connector for connecting with the receiver; And
A wireless electrocardiogram measuring system, further comprising a power adapter.
delete delete The method of claim 8, wherein the packet,
And a data comprising 7 bytes of header, 120 bytes of real data, and 6 bytes of timer data are bundled and transmitted in one packet.
9. The server according to claim 8,
Receiving electrocardiogram data classified by the user identification code is displayed in real time, and stores the data by user, separated by time, and stored in real time by calling the stored ECG data, wireless ECG measurement system.

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