KR20090120033A - Multi function car handle having a function of gathering medical essential information - Google Patents

Abstract

PURPOSE: A multifunctional steering wheel with basic health information collecting function by using the steering wheel is provided to collect the basic health information of a driver while driving a car. CONSTITUTION: A multifunctional steering wheel with basic health information collecting function by using the steering wheel includes a channel electrode(305), a blood pressure sensor(213), and an operating/displaying unit. The channel electrode measures ECG(ElectroCardioGram) signal of the operator. The blood pressure sensor measures the pulse of the finger blood vessel of the operator. The operating/displaying unit analyzes the ECG signal detected from the channel electrode. The operating/displaying unit analyzes the blood pressure/pulse of the operator on the blood pressure measurement information detected from the blood pressure sensor.

Description

MULTI FUNCTION CAR HANDLE HAVING A FUNCTION OF GATHERING MEDICAL ESSENTIAL INFORMATION}

The present invention relates to a steering wheel of a vehicle for collecting basic health information, and more particularly, to receive a driver's body signal using the handle of the vehicle, to notify the driver's health state based on the received body signal, and The present invention relates to a multifunctional handle having a basic health information collection function that can notify basic health information to a specific area near the city.

In general, the health status of a person can be indirectly identified through the state of the person's blood pressure, pulse, body temperature, etc., so that a health condition meter that allows each person to examine their own health status is widely used. Examples of such a health condition meter include a blood pressure meter, a pulse meter, a body temperature meter, and the like, and have been widely used as a portable device.

Such a medical examination system has been disclosed in the related art for measuring a driver's health state in a vehicle using a portable terminal of a driver for real time measurement, and transmitting the result to the outside. For example, after connecting or adding a portable measuring device that can detect various bio-information related to the user's health to a mobile terminal (such as a mobile phone or a PDA) and transmitting it to a server through a communication network, the server comprehensively analyzes it and is accurate. It is a health care system that can provide comprehensive health-related information.

Referring to this in detail based on an exemplary drawing, first, as shown in Figure 1, the above-described conventional comprehensive health care service system is largely the service user system 100, the service provider system 200, the operator system 300, cooperation The company server 400 and communication networks 202 and 204 are configured. The user system 100 includes a portable measuring device 110 for detecting or measuring biometric information such as a user's walking number, heart rate, electrocardiogram, drinking amount, smoking amount, blood sugar, oxygen saturation, body temperature, body fat, and the like, and a portable measuring device ( The mobile phone 120, the Internet 204, and the web server 220 for transmitting the biometric information sensed or measured at 110 to the operator server 300 through the wireless network (CDMA) 202 and the WAP server 210. It is composed of a personal computer 130 for accessing the operator server 300 through the use of various services.

The service provider system 200 services health-related services as additional contents of the mobile phone 120, and is responsible for data transmission between the mobile phone 120 and the operator server 300 through the wireless network 202. A server 210 and a web server 220 for providing a web page to users using the personal computer 130 through the normal Internet 204.

The operator system 300 is equipped with a database server 320 that stores the biometric information of the users received through the mobile phone 120 and the management information for the user, and a health-related program 312 is mounted and the database server 320 It is composed of an operator server 310 for comprehensively analyzing the biometric information of the users received through the mobile phone 120 to provide accurate and comprehensive health-related information for each individual.

Cooperation server 400 is linked with the operator server 310, if more professional analysis is required to provide a professional health-related services by analyzing the user's biometric information or additional services using biometric information. When the partner server 400 determines that the user's health is abnormal in the health care program 312 of the operator server 310, the partner server 400 may provide a cardiac card to the specialized hospital server or the user to receive a more specialized and precise diagnosis as necessary. In case of an emergency such as a seizure, it is implemented as a 119 server for urgently transporting a user.

Here, the biometric information measuring means for detecting the user's health is composed of N sensor modules that can measure a variety of bio-signals, each sensor module to measure the pedometer, drinking and smoking amount to count the number of walking Gas sensor, blood glucose sensor for measuring blood glucose level, oxygen saturation sensor for measuring oxygen saturation in blood, temperature sensor for measuring body temperature, body fat sensor for measuring bioelectrical resistance, and the like.

The conventional health examination system configured as described above is a portable measuring device connected to a mobile phone, and after detecting or measuring biometric information such as the number of walking, heart rate, electrocardiogram, drinking amount, smoking amount, blood sugar, oxygen saturation, body temperature, body fat, etc. It sends to the server and performs comprehensive and professional analysis based on biometric data to provide more accurate and comprehensive health related information for each individual.

As a result, as described above, since the conventional health examination system is to provide health information on the current state of the user based on the portable measuring device, the user must always carry the health measuring device. However, in the modern lifestyle of frequent driving, there is a problem that the above-mentioned health measuring device cannot be carried, and when an unpleasant situation occurs while driving, a problem that can be linked to a large accident is caused.

In addition, the above-described health examination system provides a professional analysis result based on the information database digitized using the communication system, and thus there is a problem in that the guidance message in the initial stage before the emergency situation is not provided. That is, although the guidance message in the initial stage is a very important time point for the patient, there is a problem that the analysis result of the expert provided after accessing the communication network may be dangerous in time. As a result, there is an urgent need for a system in which the patient's physical condition, which is provided in real time, can be easily notified to the patient, before being notified of dangerous levels of numerical results.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a driver's health status in real time during the driving process of a vehicle, so that the driver can recognize the health risk condition in advance. It is to provide a multifunction handle having a function.

Another object of the present invention is to provide a driver's safety by measuring a driver's risk situation or by making a network connection to a nearby medical institution or emergency rescue agency in response to a driver's arbitrary request. It is to provide a multifunctional handle having an information collection function.

Still another object of the present invention is to secure a predetermined amount of memory with the system, and to record and manage the driver's health status in real time, so that the driver's health condition can be provided to the medical staff in case of a problem, or in an emergency situation. It is to provide a multi-function handle having a basic health information collection function that can notify the health condition of the driver to a medical institution near the city.

Multifunction handle having a basic health information collection function according to an aspect of the present invention for achieving the above object, the finger vessels of the driver including an electrode for each channel (L, R) for measuring the ECG (ElectroCardioGram) signal of the driver It is equipped with a blood pressure sensor for measuring the pulse of the driver, and analyzes the ECG signal of the driver by analyzing the ECG signal detected from each electrode of each channel, and receives the driver's personal information from the driver, based on the driver's body resistance Analyze the blood pressure / pulse of the driver based on the body fat measurement and the blood pressure measurement information detected from the blood pressure sensor, characterized in that it comprises an operation / display means for performing a display and communication networking corresponding to each analysis result.

According to a preferred embodiment of the present invention, the operation / display means mounted to the handle of the vehicle includes electrode means including the L electrode and the R electrode; An amplifier for amplifying the body current flowing through the electrode means to a predetermined level; An AD converter for converting an output signal provided from the amplifier into a digital signal; An ECG signal analyzer configured to analyze an ECG signal for measuring an electrocardiogram of a driver based on the digital signal output from the AD converter; A blood pressure / pulse measuring unit for measuring / calculating the blood pressure / pulse of the driver based on the blood pressure measurement signal of the driver provided from the blood pressure sensor; The health level of the driver is determined based on the output signal of the ECG signal analyzer, the blood pressure and pulse information of the driver detected by the blood pressure / pulse measuring unit, and the set body information of the driver, and the data of the health status of the driver is digitized. A control unit configured to control the communication networking to a medical institution at a preset place or in a proximate location in response to the set reference value; A communication module for performing communication networking of the controller; A display unit for displaying the driver's health state information output from the controller as numerical information or graphic information; And a data memory for storing and managing the driver's health state information and storing guide message information for a dangerous situation of the driver.

According to the present invention, the basic health information of the driver may be collected in real time in a driving state, so that accurate response according to an emergency situation occurs while driving. In addition, the present invention provides the driver with the current state of health in real time, thereby recognizing the state of health of the driver himself, thereby increasing the efficiency of the precautions. In addition, the present invention by continuously managing the basic health information of the driver, it is possible to provide the health status of the driver to the medical staff in the event of a dangerous situation has the effect of providing the accuracy and promptness of follow-up care.

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

2 is an internal configuration of a vehicle showing a multifunction steering wheel having a basic health information collection function according to the present invention. As shown, the handle 201 according to the present invention includes the electrodes (203, 205) for each channel (L, R) for measuring the driver's ECG (ElectroCardioGram) signal, to measure the pulse of the driver's finger vessels A blood pressure sensor 213 is installed to analyze the ECG signal of the driver by analyzing the ECG signal detected from each electrode of each channel, and after receiving the driver's personal information from the driver, The body fat measurement and blood pressure / pulse of the driver are analyzed based on the blood pressure measurement information detected by the blood pressure sensor 213, and has operation / display means 211 for performing display and communication networking corresponding to each analysis result.

The L electrode 203 and the R electrode 205 are made of a conductive metal material, and are installed in a space partitioned from the center of the handle 201, and the blood pressure sensor 213 is located at a specific position of the handle 201. Is mounted on but is provided in a position where the thumb of the driver is gripped. In addition, a conductive pad 207 for transmitting a driver's body signal to each electrode is adsorbed or bonded onto each electrode. On the other hand, the operation / display means 211 is mounted inside the handle 201 of the vehicle receives the power supply voltage of the vehicle.

The operation / display means 211 displays the driver's electrocardiogram, body fat, body temperature, blood pressure, pulse rate, etc. at one side of the handle 201, but is provided as graphed information or numerical information. The measured ECG information provides heart disease status and status, and performs diagnosis of various arrhythmia and electrolyte abnormalities including coronary artery disease such as angina pectoris and myocardial infarction. The result is stored and managed for each predetermined time unit or driving time zone.

In the present invention, the operation / display means 211 includes an input means for inputting the driver's age, gender, weight, medical history, etc. to provide patient-specific information (driver-specific), based on the input information Current ECG information, body fat information, blood pressure / pulse and body temperature information of the driver are calculated and extracted. This is to determine the level of the dangerous situation corresponding to the driver's input information, it is a means for inducing the initial response to the patient. Accordingly, the operation / display means 211 includes a communication means and a GPS receiving means for notifying a nearby medical institution or emergency rescue organization of the driver's position and examination information (ecg, body fat, blood pressure, pulse rate, body temperature) in an emergency situation. .

3 is a configuration diagram for explaining the main operation of the present invention. As shown in the drawing, the handle 201 has a predetermined level of electrode current including the L electrode 203 and the R electrode 205 and the body current flowing through the electrode means 305. Driver based on the digital signal output from the AD converter 309, the AD converter 309 for converting the output signal provided from the amplifier 307 into a digital signal, and the digital signal output from the AD converter 309. ECG signal analysis unit 303 for analyzing the ECG signal for ECG measurement, and determines the driver's health level based on the output signal of the ECG signal analysis unit 303 and the set driver's body information, the driver's health A control unit 301 for outputting the state information as digitized data, storing and managing the data in predetermined time units, and controlling communication networking to a medical institution at a preset location or a neighboring location in response to a set reference value; Barrel A communication module 321 for performing networking, a display unit 317 for displaying the driver's health status information output from the controller 301 as numerical information or graphic information, and the driver's health status information And a data memory 319 for storing, managing, and storing guide message information on a dangerous situation of a driver.

On the other hand, the control unit 301 includes a GPS receiver 315 for notifying the current location information when a dangerous situation of the driver, RTS (Real Time System: 313) for measuring the current accurate time, and It is linked with the key input unit 311 for selecting and inputting the age, gender, weight, height and medical history. The key input unit 311 is provided with the above-described operation / display means 211, it is possible to input any telephone number corresponding to the preset place including the history of the driver.

In the present invention, the control unit 301 is based on the data of the body current signal provided from the above-described AD converter 309 and the age, gender, height, weight information input from the key input unit 311 of the driver By interlocking with the blood pressure / pulse measurement unit 329 for measuring / calculating the blood pressure / pulse of the driver based on the body fat measurement unit 327 for measuring body fat and the blood pressure measurement signal of the driver provided from the blood pressure sensor 213 In addition, comprehensive basic health information of drivers should be collected. In addition, the present invention is equipped with a temperature sensor (not shown) to the peripheral side of the handle 201, the control unit 301 may be applied to the output signal of the temperature sensor to measure the body temperature of the driver, of course. to be.

Meanwhile, the controller 301 displays the ECG change amount for the driver as numerical or graphic information, displays information such as blood pressure / pulse value of the driver, body temperature and body fat of the driver, and alerts or warnings about dangerous situations. A display operation module for outputting a message, an ECG signal analysis algorithm for processing an output signal of the ECG signal analysis unit 303 in response to a driver's history input from the key input unit 311, and the key input unit ( A communication operation algorithm for performing a communication connection to a predetermined place input from 311), a communication message with a nearby medical institution, a guidance message about a dangerous situation, and transmitting and controlling the driver's body condition information, and the GPS receiver Location information and communication net of the nearest medical institution or emergency rescue agency based on the current location information received at 315 The program memory 323 stores a GPS algorithm for collecting and managing walking information, and a control device 331 for managing and controlling system operation corresponding to each algorithm of the program memory 323.

The GPS algorithm stored in the program memory 323 is for extracting geographic information and communication information about a medical institution or an emergency rescue agency close to a current location, and includes a GIS corresponding to geographic coordinates.

Although the communication module 321 is mounted as an interior of the vehicle, the communication module 321 may communicate with the driver's mobile phone through physical connection or short-range communication means such as ZigBee, Bluetooth, etc. as necessary. After performing, it will be obvious that communication can be made to a medical institution, an emergency rescue agency, or a predetermined place through the driver's mobile phone.

Hereinafter, the operation of the present invention will be described in detail with reference to the accompanying drawings. First, FIGS. 4A and 4B are flowcharts for explaining the main operation of the present invention.

As shown, the process enters S401 and is switched to the initial state. In the initial state, after the vehicle is started, the controller 301 is initialized with a rated power applied to the operation / display means 211. The driver inputs medical history information, for example, age, gender, weight, height, medical history, etc. of the driver using the key input unit 311. This may be input through a plurality of key buttons constituting the key input unit 311, or may input the driver's medical history by selecting the textual information provided through the display unit 317. Thereafter, the vehicle is driven, and the driver grips the L electrode 203 and the R electrode 205 mounted to a predetermined portion of the steering wheel 201 of the vehicle.

The L electrode 203 and the R electrode 205 receive a driver's body signal through the conductive pad 207. The conductive pad 207 needs to be cleaned using a towel in order to increase the signal transfer efficiency. Therefore, it is desirable for the driver to clean the conductive pad 207 before driving.

In step S403, the body signal of the driver flowing through the L electrode and the R electrode, that is, the electrode means 305 is amplified by a signal of a predetermined level by the amplifying unit 307. The digital signal is converted into a digitized signal through the AD converter 309 and provided to the ECG signal analyzing unit 303, the pressure / pulse measuring unit 329, and the body fat measuring unit 327. The ECG signal analyzer 303 detects a small change in potential caused by the activity of the heart, which detects a potential distributed on the surface of the body when weak electricity generated every time the heart beats flows in the body. will be.

Electrocardiogram (ECG) is basically composed of P, Q, R, S, T waves. P waves occur at atrial depolarization, QRS group at ventricular depolarization, and T waves at ventricular repolarization. Depolarization of the atria begins near the isotropic crystal and progresses from right to left across the atrium. Therefore, the first part of the P wave represents the depolarization of the right atrium, and the second part of the P wave represents the depolarization of the left atrium. Normally P waves occur during the diastolic phase of the ventricles.

The QRS group reflects ventricular depolarization. Depolarization of the ventricles begins in the left portion of the interventricular septum near the atrioventricular junction and progresses from left to right across the interventricular septum. Therefore, the Q wave represents the depolarization of the interventricular septum, and the rest of the QRS group shows the depolarization of the left and right ventricles simultaneously. The R wave is defined as the first recorded up wave, the Q wave is defined as the down wave recorded before the R wave, and the S wave is defined as the down wave recorded after the R wave. Abnormal QRS groups may be associated with intraventricular conduction disturbances (eg blockade) and abnormal atrioventricular conduction (early excitement syndrome).

Normal T waves indicate normal repolarization of the ventricles. Normal repolarization begins at the epicardium surface of the ventricle and progresses through the ventricular wall toward the endocardium. T waves occur during ventricular end. The abnormality of the P wave, the QRS group, and the T wave may include a duration of each wave, an interval with a neighboring wave, a segment with a neighboring wave, an amplitude of a wave, and a sharp shape of a wave. This can be checked by determining whether these values are within the normal range.

That is, the most important element of the above elements may be referred to as the size of the wave, and the peak value of the R wave having the largest size may be set as an important element. Using this principle, the present invention determines whether the driver has an abnormal signal by comparing the R wave peak value of the currently measured driver ECG signal with the R wave peak value of the preset standard ECG signal in step S405. Here, the control unit 301 calculates the deviation of the ECG signal level from the standard ECG signal level based on the signal analysis algorithm mounted in the program memory 323.

The signal level deviation determines whether the P wave, the QRS group, and the T wave are abnormal, which is assumed to be a result of a healthy driver. Therefore, the deviation information of the ECG signal level compared and analyzed by the control device 331 is processed by the driver's history information, that is, the driver's history information input from the key input unit 311. To this end, the signal analysis algorithm of the program memory 323, in step S407, adds an added value to the deviation information of the ECG signal level according to the degree of medical history that may affect the ECG.

Here, the added value for the ECG signal level indicates weighting based on an experimental basis, including weights for medical history items proportional to risk. Eventually, a driver with a history may be aware of a dangerous situation even with a small amount of change in the ECG signal.

In step S409, the control device 331 determines whether the driver is in a dangerous situation based on the level of the currently detected ECG signal. This is made based on the processed signal level corresponding to the driver's medical history as described above, and determines the dangerous situation based on the processed signal level. Therefore, when it is determined in step S411 that the currently detected ECG signal level does not cause a dangerous situation of the driver, the control device 331 outputs the current signal level to the display unit 317.

The signal level provided to the display unit 317 is textual information or graphic information and can be easily recognized while driving. If necessary, a predetermined beep may be added so as not to disturb the driver's attention. In operation S413, the control device 331 stores the information according to the current driver's physical condition in the data memory 319. This is applied as a means for the medical staff to recognize the timing of the initial symptoms when the driver's dangerous situation occurs.

To this end, the control device 331 can add accurate time information by using the RTC 313, and also adds the location information received from the GPS receiver 315 to be used as important information for post-processing. Do it.

On the other hand, when the current ECG signal level exceeds the reference signal level as a result of the determination in step S409, the control device 331 starts the communication operation algorithm mounted in the program memory 323 in step S415. do. As described in step S417, the control device 331 extracts contact information of a specific person, which is input based on a communication operation algorithm, and notifies a dangerous situation through the communication module 321.

Then, the current location information input from the GPS receiver 315 is extracted, and the nearest medical institution or (and) emergency rescue organization is searched based on the current location information. This works in conjunction with the GIS, and searches for the medical institution or emergency rescue agency having the closest coordinates from the coordinates of the current location, and extracts the contact information corresponding to the medical institution or emergency rescue agency. The control device 331 performs a communication connection with a corresponding institution by using the communication module 321, and transmits a preset guide message, that is, a message notifying that a dangerous situation.

If necessary, the ECG measurement data of the driver stored in the data memory 319 and the phone number of the driver's mobile phone may be transmitted together with the guide message. As such, when the driver's emergency occurs, the control device 331 notifies the current danger situation to a nearby medical institution, including a specific place, based on a communication operation algorithm, so that the emergency situation can be dealt with.

The step S413 is a step of storing and managing the ECG signal according to the change in the physical condition of the driver, and managing the current time information, the current location information, and the like. This is information stored in the data memory 319 and may be provided to the outside through a predetermined output port or may be provided through the display unit 317.

On the other hand, the control unit 301 patches the body information of the driver in step S419. That is, the controller 301 reads age, gender, height, and weight information from the key input unit 311 to the driver and provides the same to the body fat measurement unit 327. Thereafter, as in step S421, the body fat measuring unit 327 is provided with a current amount measurement result flowing to the body of the current driver. To this end, the body fat measuring unit 327 measures a current amount flowing to the driver's body by applying a small current amount set to one end of the electrode means 305, and detects a resistance value for the driver's body.

In operation S423, the body fat measuring unit 327 measures the body fat of the driver based on the age, gender, height, and weight information of the driver and the body resistance value currently measured. The body fat measurement method uses a conventional method that has already been used and verified, and the present invention uses any one of BIA (Bioelectrical Impedance Analysis), a multi-frequency measurement method, and a site-specific analysis method for measuring and analyzing the electrical resistance of a human body. , A detailed description thereof will be omitted.

In step S425, the body fat measuring unit 327 provides the current body fat measurement result of the driver to the control unit 301, and the control unit 301 displays the driver's body together with the current time information. The body fat measurement result is displayed. In addition, the controller 301 controls the body fat information of the driver to be stored in the data memory 319.

Thereafter, in step S427, the control unit 301 instructs to start the blood pressure / pulse measuring unit 329 to measure the blood pressure and pulse of the driver. The blood pressure / pulse measuring unit 329 enters step S429 and detects the current blood pressure state of the driver from the blood pressure sensor 213 mounted as one side of the handle 201.

The blood pressure sensor 213 is a blood pressure monitor using a finger and measures blood pressure by vibration of a pulse. This is to apply the commonly used oscillometric method, if the need may be applied to the method of listening to the vascular sound rather than the oscillometric method. When a blood pressure monitor of a blood vessel type is used, the blood pressure sensor 213 will be assumed to be a microphone.

The blood pressure / pulse measurement unit 329 detects a subtle change in the cuff pressure generated when the blood vessel pulsates through the blood pressure sensor 213, and the detected result is provided to the controller 301. The control unit 301 determines whether the normal value is based on the blood pressure and pulse information of the driver currently detected in step S431, and transmits the result to the display unit 317 together with the determination result. Accordingly, the driver recognizes the current driver's blood pressure and pulse state by looking at the operation / display means 211 provided on the handle 201.

Therefore, as determined in step S433, the control unit 301, if the driver's blood pressure and pulse state is out of the reference value, or enters the risk level set according to the medical history input from the key input unit 311, S437 In step S439, the communication operation algorithm is activated according to the risk situation, and the medical institutions and emergency rescue agencies in the vicinity are notified of the current situation. On the other hand, if it is determined in step S433 that the driver's pulse / blood pressure state is included in the set normal value, enters to step S435 and the controller 301 stores and manages the current driver blood pressure and pulse information to the data memory 319. In this case, as described above, the controller 301 stores and manages current time information and current location information detected by the RTC 313 and the GPS receiver 315, thereby continuously and specifically managing the body change of the driver. You can do it.

As described above, the multi-function handle having the basic health information collection function according to the present invention not only prevents discontinuity due to continuous patient examination during driving of a patient who needs to monitor health status in real time. In addition, it is expected to contribute to the development of the medical industry by providing health status information about patients in the patient's dangerous state, thereby improving the completion of the medical system.

1 is a block diagram showing a conventional portable screening system.

Figure 2 is an installation state diagram showing a health examination system for a vehicle according to the present invention.

3 is a configuration diagram illustrating the main functions of FIG. 2.

4A and 4B are flowcharts for explaining the main operation of the present invention.

<Explanation of symbols for main drawings>

201: handle 203: L electrode

205 R electrode 207 conductive pad

211: operation / display means 213: blood pressure sensor

301 control unit 303 ECG signal analysis unit

305: electrode means 307: amplification unit

309: AD converter 311: key input unit

313: RTC 315: GPS receiver

317: display unit 319: data memory

321: communication module 323: program memory

327: body fat measurement unit 329: blood pressure / pulse measurement unit

331: control device

Claims (14)

In the steering wheel structure of the vehicle capable of detecting the state of health in real time, The steering wheel of the vehicle includes an electrode for each channel (L, R) for measuring the driver's ECG (ElectroCardioGram) signal, and is equipped with a blood pressure sensor for measuring the pulse of a blood vessel of the driver's finger. After analyzing the detected ECG signal, the driver's electrocardiogram is measured, and the driver's body information is input from the driver, and the driver's body fat is measured based on the body's body resistance, and the blood pressure measurement information detected by the blood pressure sensor is used. A multifunction handle having basic health information collection function, comprising: an operation / indication means for analyzing blood pressure / pulse and performing display and communication networking corresponding to each analysis result. The method of claim 1, The L electrode and the R electrode are made of a conductive metal material, and are installed in a space partitioned from the center of the handle, and a conductive pad for transmitting a body signal of the driver to each electrode is adsorbed or bonded onto each electrode. Multifunctional handle having a basic health information collection function, characterized in that. The method of claim 1, The blood pressure sensor is a multifunction handle having a basic health information collection function, characterized in that provided in a specific position of the handle that the thumb of the driver can be gripped. The method according to claim 1 or 3, The operation / display means displays the driver's electrocardiogram, and is provided as graphed information or numerical information. The electrocardiogram information may be any one of diagnosis of coronary artery disease such as heart disease, angina pectoris and myocardial infarction, arrhythmia or electrolyte abnormality. Multifunctional handle having a basic health information collection function, characterized in that the single examination information. The method of claim 4, wherein The operation / display means is a multi-function handle having a basic health information collection function, characterized in that it comprises input means for inputting the driver's age, gender, height, medical history, etc. to provide driver-specific information. The method of claim 4, wherein The operation / display means is a multi-function handle having a basic health information collection function, characterized in that it comprises a communication means and GPS receiving means for notifying the position of the driver and the ECG measurement results to the nearest medical or emergency rescue agency in an emergency. The method of claim 1, The operation / display means may include electrode means including the L electrode and the R electrode; An amplifier for amplifying the body current flowing through the electrode means to a predetermined level; An AD converter for converting an output signal provided from the amplifier into a digital signal; An ECG signal analyzer configured to analyze an ECG signal for measuring an electrocardiogram of a driver based on the digital signal output from the AD converter; A blood pressure / pulse measuring unit for measuring / calculating the blood pressure / pulse of the driver based on the blood pressure measurement signal of the driver provided from the blood pressure sensor; The health level of the driver is determined based on the output signal of the ECG signal analyzer, the blood pressure and pulse information of the driver detected by the blood pressure / pulse measuring unit, and the set body information of the driver, and the data of the health status of the driver is digitized. A control unit configured to control the communication networking to a medical institution at a preset place or in a proximate location in response to the set reference value; A communication module for performing communication networking of the controller; A display unit for displaying the driver's health state information output from the controller as numerical information or graphic information; And And a data memory for storing and managing the driver's health state information and storing guide message information for a dangerous situation of the driver. The method of claim 7, wherein The operation / display means further includes a body fat measuring unit for measuring the body fat of the driver based on data on the body current signal provided from the AD converter and age, gender, height, and weight information input from the key input unit, The control unit has a multi-function handle having a basic health information collection function, characterized in that for providing the body fat information of the driver detected through the body fat measurement unit to the display. The method according to claim 1 or 7, The temperature sensor is mounted to a predetermined position of the handle that can hold the driver's palm, and the operation / display means further includes a body temperature measuring unit capable of measuring the body temperature of the driver by receiving an output signal of the temperature sensor. The controller is a multi-function handle having a basic health information collection function, characterized in that for providing the body temperature information of the driver detected through the temperature measuring unit to the display. The method of claim 7, wherein The control unit has a multi-function handle having a basic health information collection function, characterized in that the link with the GPS receiver for notifying the current location information when a dangerous situation of the driver occurs. The method of claim 7, wherein The control unit is a multi-function having a basic health information collection function, in conjunction with a real time system (RTS) for measuring the current accurate time and a key input unit for selecting and inputting the driver's age, gender and medical history handle. The method of claim 11, The control unit is a multi-function handle having a basic health information collection function characterized in that it receives an arbitrary telephone number corresponding to a predetermined place from the key input unit to notify that the emergency number to the telephone number in case of an emergency. The method according to claim 11 or 12, The controller may display the ECG change amount for the driver as numerical or graphic information, and output a warning sound or a warning message for a dangerous situation, and the ECG in response to the driver's history input from the key input unit. To perform a signal analysis algorithm for processing the output signal of the signal analysis unit, a communication connection to a predetermined place input from the key input unit, or to operate a communication connection with a nearby medical institution and guide message information about a dangerous situation A program memory storing a communication algorithm and a GPS algorithm for collecting and managing location information and communication networking information of an adjacent medical institution or emergency rescue organization based on the current location information received by the GPS receiver; And A multifunction handle having a basic health information collection function, characterized in that it comprises a control device for managing and controlling system operation corresponding to each algorithm of the program memory. The method of claim 13, The GPS algorithm stored in the program memory is for extracting geographic information and communication information about a medical institution or an emergency rescue agency close to a current location, and includes basic GIS geographic information corresponding to geographic coordinates. Multifunction handle.

Images