KR100591239B1 - Apparatus for measuring health conditions of a mobile phone and a method for controlling informations of the same - Google Patents

Abstract

The present invention relates to a health state measuring device for a mobile communication terminal and an information management method thereof, and in particular, to detect body fat, oxygen saturation, pulse and body temperature by the user's finger contact, and to detect the amount of exercise by the user's post-action activity Health condition measuring device for mobile communication terminal and information management method that user can easily check his / her health condition regardless of time and place by installing health condition measuring module to measure the condition in place of mobile communication terminal It is about.

The health state measuring device for a mobile communication terminal of the present invention is installed in a place of the mobile communication terminal, and detects body fat, oxygen saturation, pulse, and body temperature by the user's finger contact, and detects the amount of exercise by the user's post-action activity. Health state measuring means for measuring a health state; And display means for visually displaying to the user a result value of the health state measured by the health state measuring means.

Mobile terminal, health status, body fat, bioresistance, oxygen saturation, body temperature, pulse rate, exercise amount, health measurement module, finger

Description

Apparatus for measuring health conditions of a mobile phone and a method for controlling informations of the same}

1 is a front view showing a mobile communication terminal equipped with a health state measuring module according to an embodiment of the present invention;

2 is a side view showing a mobile communication terminal equipped with a health state measurement module according to an embodiment of the present invention;

Figure 3 is a front view showing a health state measurement module applied to the present invention,

Figure 4 is a side cross-sectional view showing a health state measurement module applied to the present invention,

Figure 5 is a block diagram for schematically illustrating a health state measuring device for a mobile communication terminal according to an embodiment of the present invention,

6 is a state diagram used to explain a state of use of the health state measuring device for a mobile communication terminal according to an embodiment of the present invention;

FIG. 7 is a diagram schematically illustrating an information management method of a health state measuring apparatus for a mobile communication terminal according to an embodiment of the present invention.

*** Explanation of symbols on main parts of drawing ***

100: mobile communication terminal, 150: battery,

200: health status measurement module, 210: body fat measurement unit,

211: constant current driver, 212a to 212d: first to fourth body fat measuring electrodes,

213: differential amplifier, 214, 225, 233, 243: filter,

220: oxygen saturation measuring unit, 221: light emission control unit,

222: current amplifier, 223: optical sensor,

223a: first light emitting unit, 223b: second light emitting unit,

223c: light receiver, 224,232, 242: amplifier,

230: body temperature measuring unit, 231: temperature sensor,

240: momentum measuring unit, 241: acceleration sensor,

250: key input unit, 260: display unit,

270: input and output interface unit, 280: memory unit,

290: control unit, 291: housing,

292: printed circuit board, 300: right hand index finger,

310: capillary, 400: left hand,

410: left hand thumb, 420: left hand index finger,

500: wireless communication, 510,610: computer terminal,

520: email, 530, 620: healthcare software,

600: wired communication

The present invention relates to a health state measuring device for a mobile communication terminal and an information management method thereof, and in particular, to detect body fat, oxygen saturation, pulse and body temperature by the user's finger contact, and to detect the amount of exercise by the user's post-action activity Health condition measuring device for mobile communication terminal and information management method that user can easily check his / her health condition regardless of time and place by installing health condition measuring module to measure the condition in place of mobile communication terminal It is about.

In general, in order to measure an individual's state of health, ie, body temperature, body fat, pulse rate, and oxygen saturation, a medical examination has been performed in a hospital or a household medical device has been purchased and used.

In addition, when using a hospital had to bear the time investment and examination costs, there was a problem that the home medical equipment has to pay for expensive money.

Therefore, as interest in health of general users increases, the desire to check their health status anytime, anywhere increases, and thus, a necessity for a user to easily measure a health state using a device possessed by an individual is required.

The present invention has been made to solve the above problems, an object of the present invention is to detect the body fat, oxygen saturation, pulse, body temperature by the user's finger contact and to detect the amount of exercise by the user's post-activity activities to check the health state By providing a health state measurement module for measurement in place of the mobile communication terminal, to provide a health state measurement device for a mobile communication terminal that the user can easily check his or her health state irrespective of time and place.

Another object of the present invention is installed in the right place of the mobile communication terminal, the body fat, oxygen saturation, pulse, body temperature by detecting the user's finger touch and the amount of exercise by the user's post-action activities to measure the health status By storing various health state information data measured by the state measuring device in the memory of the mobile communication terminal, and managing the various health state information data stored in the memory through the health management software installed in the mobile communication terminal, the user can conveniently An object of the present invention is to provide an information management method of a health state measuring device for a mobile communication terminal capable of managing a health state.

Another object of the present invention is installed in the place of the mobile communication terminal, by detecting the body fat, oxygen saturation, pulse, body temperature by the user's finger contact and by measuring the amount of exercise by the user's post-action activities to measure the health state Various health state information data measured from the health state measuring device is stored in the memory of the mobile communication terminal, and various health state information data stored in the memory are transmitted to a computer terminal or e-mail through wired / wireless communication, and the various health By managing the status information data by the health management software installed in the computer terminal, users can conveniently check and manage their own health status as well as send them to a specialist for advice when necessary. The present invention provides a method for managing information of a health state measuring device.

In order to achieve the above object, an aspect of the present invention is installed in place of the mobile communication terminal, by detecting the body fat, oxygen saturation, pulse, body temperature by the user's finger touch and the amount of exercise by the user's post-action activities Health state measuring means for sensing and measuring a health state; And display means for visually displaying to the user a result value of the health state measured by the health state measuring means.

Here, the health state measuring means, body fat measuring unit for outputting the body fat bio-signal by measuring the bio-resistance through a plurality of measuring electrodes provided to be in contact with the user's finger; An oxygen saturation measuring unit for outputting an oxygen saturation biometric signal by measuring transmitted light of a pulsating component through an optical sensor that emits and receives light having a wavelength of a specific region to the contacted finger of the user; A body temperature measuring unit configured to output a body temperature biosignal by measuring a finger temperature of the contacted user; An exercise amount measuring unit measuring an acceleration according to a user's movement and outputting an exercise quantity biosignal; And receiving the oxygen saturation bio signal and calculating an oxygen saturation value and a pulse value, and receiving the body fat bio signal, the body temperature bio signal and the momentum bio signal, respectively, and calculating the body fat value, body temperature value and exercise amount to display the display means. It is preferable to include a control unit for controlling to output to.

Another aspect of the present invention is installed in a location of the mobile communication terminal, and detects the body fat, oxygen saturation, pulse, body temperature by the user's finger touch and the health by measuring the amount of exercise by the user's post-action activity health A method of managing various health state information data measured from a state measuring device, the method comprising: (a) storing various health state information data measured from the health state measuring device in a memory of a mobile communication terminal; And (b) managing the stored various health state information data through health management software pre-installed in the mobile communication terminal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. This embodiment is not intended to limit the scope of the invention, but is presented by way of example only.

1 is a front view showing a mobile communication terminal equipped with a health state measurement module according to an embodiment of the present invention, Figure 2 is a side view showing a mobile communication terminal equipped with a health state measurement module according to an embodiment of the present invention to be.

1 and 2, the health state measuring device for a mobile communication terminal according to an embodiment of the present invention, the body fat by the user's finger contact to the place of the mobile communication terminal 100, that is, the front side , Health saturation measurement module 200 for detecting the oxygen saturation, pulse, body temperature and the amount of exercise by the user's post-holding activity to measure the state of health is installed.

In addition, the front side of the mobile communication terminal 100 is provided with a display unit 260 for visually displaying the result value of the health state measured by the health state measurement module 200 to the user. In this case, the display unit 260 preferably uses an external window provided by itself in the mobile communication terminal 100, but is not limited thereto and may be provided separately from the external window of the mobile communication terminal 100.

The first and second body fat measuring electrodes for detecting body fat biosignals are electrically connected to a printed circuit board 292, which will be described later, on one side of the mobile communication terminal 100, and are provided to be in contact with a part of a user's finger skin. 212a and 212b are formed separately from each other.

On the other side of the upper portion of the mobile communication terminal 100, a key input unit 250 for generating a measurement start signal for starting a health state measurement is formed by a user's operation. In this case, the key input unit 250 may be implemented as a normal push button, and may use any one of various key buttons provided in the mobile communication terminal 100.

Figure 3 is a front view showing a health state measurement module applied to the present invention, Figure 4 is a side cross-sectional view showing a health state measurement module applied to the present invention.

As shown in Figures 3 and 4, the health state measurement module 200 applied to the present invention, the housing 291 constituting the body, the housing 291 is built in, the user's body fat, oxygen saturation, pulse, The printed circuit board 292 and the printed circuit board 292 are equipped with various circuits for sensing the body temperature and exercise, and the health state of the housing 291 so as to be in contact with the user's finger. And a third and fourth body fat measurement electrodes 212c and 212d, an optical sensor 223, and a temperature sensor 231, which are separately installed on the front surface.

The housing 291 is installed so that the front surface of the mobile communication terminal 100 is exposed, that is, the one side of the front surface, the front surface of the third and fourth body fat measurement electrodes 212c and 212d when the finger touches it. It is easily in close contact with the optical sensor 223 and the temperature sensor 231 to prevent separation and to prevent penetration of light (for example, visible light, etc.) from the outside, so as to prevent the malfunction of the optical sensor 223 to be recessed inward. In other words, it is formed concave.

The optical sensor 223 and the temperature sensor 231 are separately installed to the inside of the third and fourth body fat measurement electrodes 212c and 212d installed on the front of the housing 291 so that a part of the user's finger skin comes into contact with each other. desirable.

The optical sensor 223 is electrically connected to the printed circuit board 292, and is used to measure oxygen saturation and pulse of the user, and includes red light (eg, 660 nm) and infrared light (eg, 940 nm) having a wavelength of a specific region. The first light emitting unit 223a and the second light emitting unit 223b and the emitted red light and infrared light are respectively transmitted through the capillaries 310 of the right hand index finger 300, respectively. It is comprised by the light receiving part 223c for receiving light.

Here, the first light emitting unit 223a, the second light emitting unit 223b, and the light receiving unit 223c may be implemented as a red LED, an IR LED, and a photodiode, respectively.

The temperature sensor 223 is electrically connected to the printed circuit board 292, and serves to sense a user's body temperature.

Various circuits for measuring the health state by sensing the body fat, oxygen saturation, pulse, body temperature and exercise amount of the user mounted on the printed circuit board 292 is preferably integrated in the form of a System on Chip (SoC).

In addition, one side of the printed circuit board 292 is preferably mounted with an acceleration sensor 241 for measuring the amount of exercise by detecting the acceleration according to the user's movement.

5 is a block diagram for schematically illustrating a health state measuring device for a mobile communication terminal according to an embodiment of the present invention.

As shown in FIG. 5, the health state measurement module 200 installed in place of the mobile communication terminal 100 includes a body fat measurement unit 210, an oxygen saturation measurement unit 220, a body temperature measurement unit 230, The exercise amount measuring unit 240, the key input unit 250, the display unit 260, the input / output interface unit 270, the memory unit 280, and the control unit 290 are included.

In the above-described configuration, the body fat measuring unit 210 measures body resistance through a plurality of measuring electrodes provided to be in contact with a user's finger and outputs a body fat bio signal.

The body fat measuring unit 210 may be a constant current driver 211 and a constant current driver 211 for outputting a predetermined constant current (eg, 800 mA to 50 mA) for measuring bioresistance according to a driving control signal of the controller 290. The user is caused by the constant current applied through the first and third body fat measurement electrodes 212a and 212c and the first and third body fat measurement electrodes 212a and 212c to apply a predetermined constant current output from the user's finger skin. A differential amplifier for amplifying the bioresist signal measured from the second and fourth body fat measurement electrodes 212b and 212d and the second and fourth body fat measurement electrodes 212b and 212d. 213 and a filter unit 214 for outputting a body fat bio-signal by removing various noises from the signal amplified by the differential amplifier 213.

The measurement principle of the body fat measured by the body fat measurement unit 210 is a conventional bioelectrical impedance analysis (Bioelectrical Impedance Analysis), the first and second body fat measurement electrodes (212a, 212b), for example, the left hand 400 6, the thumb 410 (see FIG. 6), and the third and fourth body fat measuring electrodes 212c and 212d, for example, touch the skin of the index finger 300 (see FIG. 6) of the right hand. Let's do it.

At this time, a predetermined constant current flows through the 1,3 body fat measurement electrodes 212a and 212c to measure the voltage between the 2 and 4 body fat measurement electrodes 212b and 212d and convert the voltage into bioresistance.

That is, in the bioelectrical resistance analysis method, an impedance obtained by passing a minute current through the human body and passing a highly conductive tissue and a low-conductive tissue under the assumption that the body is a cylinder having electrical resistance and the body composition distribution and body tissue properties are the same. Analyze body fat by measuring

However, since the human body is curved and there are many distributions of body components or individual differences in tissues according to gender or age, factors affecting body composition may calculate body fat by receiving a key input of the mobile communication terminal 100. Typically the height and weight of the body to determine the size of the body, body tissue distribution and properties affecting factors can be corrected by age and gender.

Meanwhile, in the present invention, it is preferable to use four first to fourth body fat measurement electrodes 212a to 212d to effectively measure the body fat biosignal of the user, but the present invention is not limited thereto, and at least two body fat measurement electrodes may be used. have.

In addition, the first to fourth body fat measurement electrodes 212a to 212d are formed of a dry electrode using a metal having good conductivity (for example, titanium or platinum), and the respective measurement electrodes 212a to 212d are in contact with each other. It is desirable to be surrounded by an insulator in order to effectively prevent it.

The oxygen saturation measuring unit 220 serves to output the oxygen saturation bio signal by measuring the transmitted light of the pulsating component through the optical sensor 223 for emitting and receiving light having a wavelength of a specific region on the user's finger. .

The oxygen saturation measuring unit 220 according to the driving control signals of the first and second light emitting units 223a and 223b for emitting red light and infrared light having a wavelength of a specific region, and the control unit 290, respectively. First and second light emitting parts according to control signals of the light emitting controller 221 and the light emitting controller 221 for controlling the red light and the infrared light emitted from the second light emitting parts 223a and 223b to periodically cross flash. The current amplifier 222 for supplying a certain amount of current required for the operation of the (223a) and 223b, and the red light and the infrared light emitted from the first and second light emitting parts 223a and 223b respectively, the finger 300 A light receiving unit 223c for receiving the light reflected through the capillary blood vessel 310 of the light source, an amplifying unit 224 for amplifying the optical signal received from the light receiving unit 223c, and amplification through the amplifying unit 224. And a filter unit 225 for outputting an oxygen saturation biosignal by removing various noises from the signal. Achieved.

The measuring principle of the oxygen saturation measuring unit 220 is as follows. In other words, the human body typically transmits visible light and infrared light to an opaque body through which light does not pass or a part with a very soft tissue such as an ear or a hand. At this time, the passing light is distinctly red because light is selectively absorbed by the blood in the tissue.

Light passing through the skin is attenuated by skin tissue, and this attenuation may be assumed to be constant. However, the light passing through the blood vessels attenuates depending on what is in the blood. In other words, the more blood, the more attenuation occurs.

The optical sensor 223 uses an extinction coefficient of light absorbed in the tissue according to the wavelength, and hemoglobin present in human blood is largely oxyhemoglobin (HbO ₂ ), reduced hemoglobin (Hb), and methemoglobin (MetHb). And carboxyhemoglobin (HbCO). Among these four types of hemoglobin, HbO ₂ and Hb occupy a large amount. These two types of hemoglobin show a large difference in absorption rate depending on the wavelength, which is 660 nm of red light and 940 nm of infrared light. This difference in absorbance makes it possible to eliminate the difference in the optical path for each subject by the Beer's law.

The UV light of 940 nm does not have a large difference in attenuation coefficients between HbO ₂ and Hb, and thus may be regarded as due to other structures or components. On the other hand, 660nm red light has the largest difference between HbO ₂ and Hb in the attenuation coefficient graph. That is, when 660 nm and 940 nm light are irradiated at the same point, since the concentration of the medium and the optical path length are the same, the same amount of light should be measured unless there is a difference in the attenuation coefficient, but in the red light of 660 nm, HbO _Since the attenuation coefficient of ₂ and Hb is large, the light transmitted through the medium is obtained with a value related to the amount of HbO ₂ and Hb.

The optical sensor 223 flashes red light and infrared light alternately and amplifies the intensity of the scattered light reaching the light receiving portion 223c through the capillary blood vessel 310 at the tip of the finger 300 to be reflected to amplify the flow of blood. The transmitted light of the pulsating component shown by is obtained.

On the other hand, the driving of the optical sensor 223, first, the first light emitting unit 223a is turned on (ON) for about 125 kHz, the light reflected for about 375 kHz is obtained from the light receiving unit 223c. Then, the first light emitter 223a is turned off for about 500 mW, and the second light emitter 223b is turned on for about 125 mW to reflect the reflected light for about 375 mW. Next, the second light emitting unit 223b is turned off for about 500 ms again. The data thus obtained is transmitted to the control unit 290 via the amplifying unit 224 and the filter unit 225. The control unit 290 calculates the oxygen saturation using the transmitted light of the pulsating component obtained after the normalization process, and the pulse is calculated using a normal peak detector (not shown).

The body temperature measurer 230 measures a user's finger temperature and outputs a body temperature biosignal. A temperature sensor 231 for detecting a temperature by contacting a part of a user's finger skin and a temperature sensor ( An amplifier 232 for amplifying the temperature detection signal output from the 231, and a filter unit 233 for outputting the body temperature bio-signal by removing various noises from the signal amplified by the amplifier 232; It is composed. At this time, the temperature sensor 231 preferably uses a sensor having a resolution of at least 0.2 ℃.

The exercise amount measuring unit 240 measures an acceleration according to a user's movement and outputs an exercise quantity biosignal, an acceleration sensor 241 for detecting an acceleration according to a user's movement, and an acceleration sensor 241. Amplification unit 242 for amplifying the acceleration detection signal outputted from the (), and a filter unit 243 for outputting the momentum bio-signal by removing various noises from the signal amplified by the amplification unit 242 do. In this case, the acceleration sensor 241 is carried by the mobile communication terminal 100 to measure the amount of walking during movement to calculate the amount of exercise, using a sensor that can measure a range of about 2g (gravity) or less desirable.

The input / output interface unit 270 is for data communication with the mobile communication terminal 100 and is electrically connected to the printed circuit board 292. The input / output interface unit 270 is connected to the health state measuring module 200 through the input / output interface unit 270. The measured various measured data values (eg, body fat, oxygen saturation, pulse, body temperature, exercise amount, etc.) may be respectively stored in its own memory (not shown) of the mobile communication terminal 100, and various measured data stored in the memory. The values may be transmitted to a computer terminal or an e-mail by wired / wireless communication of the mobile communication terminal 100, and may be transmitted and received to a remote place for diagnosis by a specialist if necessary.

The memory unit 280 may individually store measurement data values of various health states measured by the health state measurement module 200.

The control unit 290 is responsible for the overall control of the health state measurement module 200, receiving the oxygen saturation degree bio-signal output from the oxygen saturation measurement unit 220, the conventional A / D conversion unit ( Oxygen saturation value and pulse value are calculated using the converted digital signal value, and the body fat biosignal and body temperature output from the body fat measuring unit 210, the body temperature measuring unit 230, and the exercise amount measuring unit 240. A biosignal and an exercise amount are respectively received to calculate a body fat value, a body temperature value, and an exercise amount by using the digital signal value converted through the A / D converter to control the output to the display unit 260.

In addition, the control unit 290 is interlocked with the central control unit (not shown) of the mobile communication terminal 100 through the input and output interface unit 270 and the various measurement data values measured by the health state measurement module 200 mobile communication terminal It is desirable to control so that it can be stored in its own memory (100).

Meanwhile, the power supply of the health state measurement module 200 preferably uses a battery 150 of the mobile communication terminal 100.

FIG. 6 is a state diagram illustrating a state of use of the health state measuring device for a mobile communication terminal according to an embodiment of the present invention, and will be described with reference to a right-handed user for convenience.

As shown in Figure 6, in order to measure their own health status using the health status measuring device for a mobile communication terminal according to an embodiment of the present invention, first, the thumb 410 skin bottom surface of the left hand 400 The first and second body fat measurement electrodes 212a and 212b of the health state measurement module 200 are brought into full contact with each other, and the front surface of the mobile communication terminal 100 enters the user's field of view. Grip to the bottom.

In this case, the index finger 420 of the left hand 400 is positioned near the key input unit 250, and the remaining fingers are positioned to support the side surface of the mobile communication terminal 100 so as not to move.

Subsequently, the right hand index finger 300 is completely attached to the third and fourth body fat measuring electrodes 212c and 212d, the optical sensor 223, and the temperature sensor 231 provided in the health state measuring module 200 to prepare for measurement. Then, press the key input unit 250 using the index finger 420 of the left hand 400, the control unit 290, body fat, oxygen saturation, pulse, Body temperature is detected to measure your health.

That is, the control unit 290 receives the oxygen saturation biosignal output from the oxygen saturation measuring unit 220 and calculates the oxygen saturation value and pulse value based on the digital signal value converted through the A / D converter, and measures body fat. A body fat bio signal, a body temperature bio signal, and an exercise body bio signal output from the unit 210, the body temperature measuring unit 230, and the exercise amount measuring unit 240 are respectively received by the digital signal values converted through the A / D conversion unit. By calculating the body fat value, body temperature value and exercise amount and outputting them to the display unit 260, the user can see the measured data values of various health conditions in real time.

In addition, the control unit 290 may control to store the measured data value of the health state in its own memory of the mobile communication terminal 100 through the input / output interface 270, and the stored various measured data values are owned by the computer terminal. It can be managed efficiently by the health care software installed in the software.

FIG. 7 is a diagram schematically illustrating a method for managing information of a health state measuring apparatus for a mobile communication terminal according to an embodiment of the present invention, wherein various measurement data values stored in the mobile communication terminal 100 are wirelessly communicated. It can be transmitted to the computer terminal 510 or the e-mail 520 to be managed by the pre-installed healthcare software (S / W) 530.

In addition, various measurement data values stored in the mobile communication terminal 100 may be transmitted to the computer terminal 610 by wired communication 600 and managed by pre-installed health care software (S / W) 620. .

Although a preferred embodiment of the above-described health state measuring apparatus for a mobile communication terminal and an information management method thereof according to the present invention has been described, the present invention is not limited thereto, and the claims and the detailed description of the invention and the accompanying drawings are described. It is possible to carry out various modifications within the scope and this also belongs to the present invention.

For example, in one embodiment of the present invention, the health state measurement module 200 is installed in place of the mobile communication terminal 100, but is not limited thereto, and a general notebook computer and a personal information terminal. It can also be installed in portable devices such as Digital Assistants and PDAs.

According to the health state measuring apparatus for mobile communication terminal and the information management method of the present invention as described above, first, body fat, oxygen saturation, pulse, body temperature is detected by user's finger contact, By installing a health state measurement module for detecting the amount of exercise to measure the health state in place of the mobile communication terminal, there is an advantage that the user can easily check his or her health state regardless of time and place.

Secondly, the present invention includes an input / output interface unit for data communication with a mobile communication terminal in a health state measurement module installed at a proper location of a mobile communication terminal, and the various health state measurement data values measured through the health state measurement module are input / output interface units. Each of the health status measurement data values stored in the memory of the mobile communication terminal are managed through the health management software installed in the mobile communication terminal or transmitted to the computer terminal or e-mail by wire / wireless communication. In addition to managing by the management software, if necessary to send and receive remotely through a mobile communication terminal to be diagnosed by a specialist, it is possible to easily check and manage their own health status and to check their health status more objectively There is an advantage.

Third, by concave the front surface of the housing of the health state measurement module according to the present invention, the body fat measuring electrode, the optical sensor and the temperature sensor provided on the front of the housing when the finger is in contact with easily prevents the departure and the outside There is an advantage that can effectively prevent the malfunction of the optical sensor by preventing the transmission of light from the.

Claims (21)

In the device installed in the right place of the mobile communication terminal, the body fat, oxygen saturation, pulse, body temperature by the user's finger touch and the amount of exercise by the user's post-action activities to measure the state of health, A body fat measuring unit configured to output a body fat bio signal by measuring bioresistance through a plurality of measuring electrodes provided to be in contact with a user's finger; An oxygen saturation measuring unit for outputting an oxygen saturation biometric signal by measuring transmitted light of a pulsating component through an optical sensor that emits and receives light having a wavelength of a specific region to the contacted finger of the user; A body temperature measuring unit configured to output a body temperature biosignal by measuring a finger temperature of the contacted user; An exercise amount measuring unit measuring an acceleration according to a user's movement and outputting an exercise quantity biosignal; The oxygen saturation biometric signal is provided to calculate an oxygen saturation value and pulse value, and the body fat biosignal, the body temperature biosignal, and the momentum biosignal are respectively supplied to calculate the body fat value, body temperature value, and the exercise amount to the display means. A control unit for controlling to output; And And a display means for visually displaying a result value of the measured health state to a user. delete The method of claim 1, wherein the body fat measuring unit, A constant current driver for outputting a constant current for measuring bioresistance according to a drive control signal of the controller; At least one first measuring electrode for applying a predetermined constant current output from the constant current driver to the user's finger skin and at least one for detecting the user's bio-resistance signal by a constant current applied through the first measuring electrode A body fat measuring electrode comprising a second measuring electrode; A differential amplifier for amplifying the bioresistance signal measured from the body fat measurement electrode; And And a filter unit for outputting a body fat bio signal by removing various noises from the signal amplified by the differential amplifier. The method of claim 1, wherein the oxygen saturation measuring unit, A light emitting unit for emitting red light and infrared light having a wavelength of a specific region; A light emission control unit for controlling the red light and the infrared light emitted from the light emitting unit to periodically cross-blink according to the driving control signal of the control unit; A current amplifier for supplying a predetermined amount of current required for operation of the light emitting unit according to a control signal of the light emitting control unit; A light receiving unit for receiving the light reflected by the red light and the infrared light emitted from the light emitting part through the capillaries of the finger; An amplifier for amplifying the optical signal received from the light receiver; And And a filter unit for outputting an oxygen saturation biosignal by removing various noises from the signal amplified by the amplification unit. The method of claim 1, wherein the body temperature measuring unit, A temperature sensor for sensing a temperature by contacting a part of a user's finger skin; An amplifier for amplifying the temperature detection signal output from the temperature sensor; And And a filter unit for outputting a body temperature biosignal by removing various noises from the signal amplified by the amplification unit. According to claim 1, wherein the momentum measuring unit, An acceleration sensor for detecting an acceleration according to a user's movement; An amplifier for amplifying the acceleration detection signal output from the acceleration sensor; And And a filter unit for outputting an exercise quantity biosignal by removing various noises from the signal amplified by the amplification unit. The health state measuring apparatus for a mobile communication terminal according to claim 1, wherein the health state measuring means further comprises a memory unit for storing the measured values of the various health states. The method of claim 1, wherein the health state measuring means further comprises a key input unit provided on one side of the mobile communication terminal to generate a measurement start signal by a user's operation. Device. The health state measuring apparatus for a mobile communication terminal according to claim 1, wherein the health state measuring means further comprises an input / output interface unit for data communication with the mobile communication terminal. 10. The method of claim 9, wherein the result values of the various health states measured by the health state measuring means are stored in a memory of the mobile communication terminal through the input / output interface unit, and the result values of the various health states stored in the memory are stored in the mobile communication terminal. Health status measuring device for a mobile communication terminal, characterized in that the transmission to the computer terminal or email by wired / wireless communication. According to claim 1, The health state measuring means, A housing configured to expose one surface of the mobile communication terminal in place and form a body; A printed circuit board embedded in the housing and equipped with various circuits for detecting a user's body fat, oxygen saturation, pulse, body temperature, and exercise amount to measure a health state; And A health state for the mobile communication terminal, which is electrically connected to the printed circuit board and includes a plurality of measuring electrodes respectively provided on one side of the mobile communication terminal and the exposed surface of the housing so that the user's finger is in contact with the printed circuit board. Measuring device. The method of claim 11, wherein the plurality of measuring electrodes, At least one first body fat measurement electrode provided on one side of the mobile communication terminal so that a part of the skin of the at least one finger is contacted by holding the mobile communication terminal with one hand of the user; And And at least one second body fat measuring electrode provided on the exposed surface of the housing such that a portion of the skin of at least one finger of the other hand of the user is in contact with the health condition for the mobile communication terminal. The method of claim 12, wherein the first body fat measuring electrode is a first measuring electrode for applying a constant current to the skin of the user's finger and the first resistance electrode for detecting the bio-resistance signal of the user by a constant current applied through the first measuring electrode; 2 measuring electrodes are made separately, The second body fat measurement electrode includes a third measurement electrode for applying a constant current to the skin of the user's finger and a fourth measurement electrode for detecting the user's bioresistance signal by the constant current applied through the third measurement electrode. Health state measuring device for a mobile communication terminal, characterized in that made. 12. The health state measuring device of claim 11, wherein the plurality of measuring electrodes are dry electrodes formed of any one of titanium and platinum. 12. The health state measuring device of claim 11, wherein the plurality of measuring electrodes are surrounded by an insulator to prevent contact between the measuring electrodes. 12. The health state measurement of claim 11, wherein the exposed surface of the housing is formed concave to prevent detachment of the touched finger and to prevent light from being transmitted from the outside when the finger is in contact. Device. The method of claim 11, wherein the temperature sensor is electrically connected to the printed circuit board, and the optical sensor for measuring the oxygen saturation and pulse of the user is installed on one side of the exposed surface of the housing, respectively. A health state measuring device for a mobile communication terminal, characterized in that. 18. The health of a mobile communication terminal according to claim 17, wherein the temperature sensor and the optical sensor are separately installed so that a part of a user's finger skin contacts inside a plurality of measuring electrodes provided on an exposed surface of the housing. Condition measuring device. delete Installed in the right place of the mobile communication terminal, by measuring the body state, oxygen saturation, pulse, body temperature by the user's finger touch, and measures the health status by detecting the amount of exercise by the user's post-action activities In the method of managing health state information data, (a) storing various health state information data measured from the health state measuring device in a memory of a mobile communication terminal; And and (b) managing the stored various health state information data through health management software pre-installed in the mobile communication terminal. The method of claim 20, wherein after step (b), (c) transmitting the stored various health state information data to a computer terminal or an e-mail through wired / wireless communication; And and (d) managing the transmitted various health state information data by means of pre-installed health management software.

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