KR100482191B1 - Mid-board of computer system for detecting ECG and BIA with one sencing means and method of operating it - Google Patents

Abstract

The present invention relates to an intermediate board member designed to measure a user's body fat and an electrocardiogram using the same device, a method of operating the same, and a computer system for measuring body information using the same.

An intermediate board member according to the present invention includes a control unit for communicating with the computer main unit and controlling itself according to a control signal of the main unit; A current generator for generating a microcurrent to be input to the user's body; An amplifying unit for measuring a minute voltage from a user's body according to a control signal of the control unit, amplifying the amplified voltage, and transmitting the amplified voltage to the control unit; Also an amplification processing unit for measuring a fine voltage from the user's body according to the control signal of the control unit, amplify and process it, and then transmits to the control unit again; It is characterized by including the. The present invention also provides a computer system for measuring body information employing the above-mentioned intermediate board member.

The present invention can be used in combination with a plurality of measurement sensors in one computer system, there is an advantage that can be measured more efficiently the user's body information.

Description

Mid-board of computer system for detecting ECG and BIA with one sencing means and method of operating it}

The present invention employs an intermediate board member designed to measure a user's body fat and an electrocardiogram in the same device, a method of operating the same, and the intermediate board member, so that the user's body fat and electrocardiogram can be measured in a single system in the same device. A computer system for measuring body information.

Many people today want to learn more about their bodies as their standard of living improves. This can be called active self-management of one's body, along with an interest in one's own body. Among such body information, measurement of an electrocardiogram capable of confirming abnormality of the heart and measurement of body fat accumulated in the body can be exemplified. Body information on these items has very different aspects with respect to the function of internal organs, and body information on these items is also measured in different ways.

First, in the measurement of ECG, it is directly related to the pulsation of the heart inside the body. The heart starts beating from the moment humans are separated from their mother's womb. This pulsation occurs in the process of contraction and expansion of the two atria and the two ventricles, and also generates a predetermined electrical signal in the process, the potential generated by the heart is known to appear throughout the body and body surface. In addition, such cardiac electrical activity can be expressed in terms of vector quantity, and its amplitude depends not only on time but also on its location. Therefore, on the basis of this theory, when measuring the action potential of the heart by attaching two electrodes on different equal-potential lines, the potential difference of the active electrode based on the time axis can be represented by a predetermined graph. do. This is an electrocardiogram as a basis for identifying abnormalities in heart disease today.

Typically, the measurement of electrocardiogram is shown in FIG. 1, with reference to the heart, the electrodes on the right arm (RA), left arm (LA) and left leg (LL), respectively, to fully represent the heart's electrical activity. EKG is measured. In this case, the potential difference measurement between the left arm LA and the right arm RA is generally performed in the lead I, the potential difference measurement between the right arm RA and the left leg LL II, the left arm LA and the left leg. The potential difference measurement between (LL) is called Lead III. On the other hand, the electrode attached to the right leg (RL) is usually used as a grounding electrode, unlike these, it is attached to the chest portion to measure the potential difference with a single electrode, which is usually denoted by V1.

In contrast, the measurement of body fat is based on a method completely different from the above-described ECG method. Representative methods thereof include subcutaneous fat measurement, underwater body density, and bioelectrical resistance.

In this case, the subcutaneous fat measurement method is a method of measuring the thickness of the skin in the epidermal layer such as the abdominal thigh and calculating the amount of body fat therefrom under the assumption that about 50% of the body fat is stored under the skin tissue. Silver is a method of calculating the amount of body fat by using the Archimedes principle in water, considering that the density of fat is about 0.9 g / cc and the remaining body components are about 1.1 g / cc.

On the other hand, the bioelectrical resistance analysis (BIA) is because the body fat component of the body has a non-conductive property, when a predetermined current is applied to the body, the current flows through the body's water as a conductor, It is a method using the fact that the body fat component acts as a resistance causing a loss of input voltage. Typically, by inputting a microcurrent of about 1 mA or less into the body and calculating a resistance thereto, the amount of body fat in the body is calculated.

As such, the conventional ECG and body fat measurement methods have different theoretical backgrounds, and thus, only a large number of individual measurement sensors appear on the market, and a system capable of measuring them by a single measurement sensor. The method of enabling this is not much introduced. However, only a few medical devices that are considered to be closest to this are introduced as the contents of the patent application.

Introducing these patent applications, Korean Patent Publication No. 2001-93975 "Computer with Body Composition Analysis, ECG and Pulse Detection Function" and Korean Patent Application Publication No. 2001-93976 "Phone with Body Composition Analysis, ECG and Pulse Detection Function "There is.

By the way, the prior art claims that a keyboard having a function of detecting body composition and pulse is already installed in a computer or inside a telephone, but there is no detail at all. For example, the specification of the patent application describes that by contacting the user's left and right palms and fingers with the electrodes mounted on the main portion of the computer keyboard, it is possible to measure the body fat percentage, body fat amount, body water content, obesity degree, etc., specifically How to measure is silent.

On the other hand, as a medical device that can measure a large number of body information in one system may be mentioned Korean Patent Registration No. 10-346081 "home medical measurement terminal".

However, the medical measurement terminal only allows the body temperature, blood pressure and body fat to be measured by a single device, and specific execution means for performing these are not disclosed at all by expressing each circuit component. Furthermore, no mention is made of what logical order each of these circuit sections are to be controlled and operated in. Moreover, no measurement of electrocardiograms has been described, and there is no finding that body fat measurements and electrocardiogram measurements can be measured by the same electrode.

As described above, in the case of various conventional medical devices, even if one measuring sensor is combined with one measuring device or a plurality of measuring sensors are combined with one measuring device, the measuring sensors are connected to each other. It only functions as a separate device, and between them, they have not been developed as rational and efficient multifunction measuring sensors.

Accordingly, it is an object of the present invention to provide a midboard member for measuring body information that assists in obtaining body fat measurement information and electrocardiogram measurement information of a user (patient) by the same measurement sensor. .

It is also an object of the present invention to provide a method of operating the midboard member for measuring body information.

In addition, another object of the present invention is to provide a computer system for measuring body information that can be efficiently measured by combining the body fat and electrocardiogram of the user into one computer system by employing the above-mentioned midboard member for measuring body information. have.

The middle board member according to the present invention is characterized in that it helps to measure different body information in one medical device using the same measuring sensor.

In addition, the computer system for measuring physical information according to the present invention has the advantage that two body information can be obtained by the same electrode sensor by employing the above-mentioned middle board fan.

The present invention relates to an intermediate board member, an operation method thereof, and a computer system for measuring body information using the intermediate board member, which assist the user's body fat and electrocardiogram to be measured by the same electrode sensor and the same medical equipment.

An intermediate board member according to the present invention includes a control unit for communicating with the computer main unit and controlling itself according to a control signal of the main unit; A current generator for generating a microcurrent to be input to a user's body according to a control signal of the controller; An amplifying unit for measuring a minute voltage from a user's body according to a control signal of the control unit, amplifying the amplified voltage, and transmitting the amplified voltage to the control unit; Also an amplification processing unit for measuring a fine voltage from the user's body according to the control signal of the control unit, amplify and process it, and then transmits to the control unit again; Characterized in that it includes. In the present invention, the term "intermediate board member" refers to an auxiliary circuit board for a computer that is mounted on a motherboard or an expansion slot inside a computer main body and used to measure body information of a user.

In addition, the operation method of the intermediate board member according to the present invention includes a start step of checking whether there is an abnormality of each component in accordance with a control signal transmitted from the computer main body unit and preparing it; A channel selection step of constituting a combination of each electrode sensor according to whether to select one of the body fat measurement channel and the ECG channel according to the control signal of the computer main body and the selection result; A step of measuring body information for inputting a microcurrent to a user's body using a combined electrode sensor or detecting a microvoltage from the user's body and measuring the same; Processing the measured body information and transmitting it back to the computer main body; An iterative trial step of repeatedly performing the above steps according to the control signal of the computer main body or itself; An end step of terminating after obtaining the desired result; It includes.

In addition, the computer system for measuring physical information according to the present invention includes an input unit for inputting information from the outside; A main body which processes various types of inputted information, stores processed information, transmits and receives processed information to the outside, and controls a system therein; An output unit for displaying the processed information to the outside; An input electrode sensor for sending a microcurrent to the user's body to measure the user's body information; A computer system comprising a measuring electrode sensor for detecting a micro voltage from a user's body and transmitting it to the main body. 1). An intermediate board member is further present between the main body portion and the electrode sensor portion, 2). The intermediate board member may include a control unit which communicates with the main body unit and controls itself according to a control signal of the main body unit; A current generator for generating a microcurrent to be input to the user's body; An amplifying unit for measuring a minute voltage from a user's body according to a control signal of the control unit, amplifying the amplified voltage, and transmitting the amplified voltage to the control unit; Also an amplification processing unit for measuring a fine voltage from the user's body according to the control signal of the control unit, amplify and process it, and then transmits to the control unit again; Characterized in that it includes.

In addition, the computer system according to the present invention is characterized in that the electrode sensor is composed of a forceps-type sensor.

In the present invention, the measurement data obtained in the above-mentioned body information measuring step may be stored in the memory unit of the computer system, and more preferably, it may be transmitted to the central control system through a communication means such as the Internet and integratedly managed. .

Hereinafter, with reference to the accompanying drawings, the present invention will be described in more detail. However, the accompanying drawings are to be described in more detail the technical spirit of the present invention, it is provided only to those skilled in the art more easily, it is obvious that the technical spirit of the present invention is not limited thereto. .

2 is a conceptual view schematically showing an intermediate board member 200 according to the present invention. The middle board member 200 is electrically connected to the computer body 110, and may be structurally coupled in the form of an expansion slot or an intermediate board. In addition, the middle board member 200 may be coupled to a plurality of input electrode sensors 180 and a plurality of measuring electrode sensors 190. The intermediate board 200 includes a control unit 210 that communicates with the main body unit 110 and controls itself according to the control signal of the main body unit. In addition, the intermediate board 200 includes a current generating unit 220 for generating a micro current to be input to the user's body according to the control signal of the control unit to send to the input electrode sensor 180. In addition, the intermediate board 200 includes an amplifying unit 230 for amplifying the micro voltage measured from the user's body by the measuring electrode sensor 190 and transmitting the amplified voltage to the control unit 210 again. And; The amplification processing unit 240 also amplifies and processes the micro voltage measured from the user's body by the measuring electrode sensor 190, and then transmits the amplification processing unit 240 to the control unit 210.

3 is a conceptual view showing in more detail the components of the middle board member 200 according to the present invention.

In the present invention, the control unit 210 includes a communication unit 212 in communication with the computer main unit 110. In addition, according to the present invention, the channel selection unit 214 selectively couples the specific input electrode sensor 180 and the specific measurement electrode sensor 190 according to the control signal of the computer main body 110 transmitted through the communication unit. ) Is included. In the present invention, it is preferable that the input electrode sensor 180 is configured in four so as to apply a microcurrent at four places (ie, both cuffs and both ankles) of the body, and the measuring electrode sensor 190 is described above. In the case of it is preferable to configure the four so that it can detect and measure the minute voltage at the same point of the body. The input electrode sensor 180 and the measuring electrode sensor 190 are preferably used in pairs with each other. In addition, in the present invention, the input electrode sensor 180 and the measuring electrode sensor 190 are used to send a fine current to the body intact and to detect and measure the micro voltage more precisely, the body part used. It is formed in the form most suitable for. For example, when used on the wrist and ankle of the body, it is preferable to use a forceps-type electrode that surrounds it. In this case, it is desirable to change the color depending on the portion used. This allows the user to contact the electrode body of the same color on the same body part, and can prevent confusion about the attachment position (Fig. 6B).

The control unit 210 according to the present invention also includes an A / D conversion unit 216 for converting data transmitted from the amplification unit 230 or the amplification processing unit 240 into digital values. The A / D converter 216 is a main function of converting the measured value from the amplification unit 230 or the amplification processing unit 240 to a digital value since it is an analog value. Therefore, it may be converted into a digital value through a predetermined operation. In addition, the control unit 210 according to the present invention includes an MCU 218 that controls itself various components of the middle board member (200).

In the present invention, the current generator 220 is a portion for generating a micro current to flow to the user's body, and includes a sine wave generator 222. The sine wave generator 222 first generates power to be input to the user's body and transfers the generated power to the V-I converter 224. The V-I converter 214 converts the voltage transmitted from the sine wave generator 222 into an AC constant current. Typically, the constant current input to the body is about 1 mA, and in the present invention, the microcurrent refers to a current of 1 mA or less. As a preferred embodiment of the present invention, the microcurrent can be about 500 mA. In the present invention, the current generation unit 220 is a first selection for electrically connecting any one of the plurality of input electrode sensors 180 to the VI conversion unit 224 according to the selection signal of the channel selection unit. It includes a connector 226.

In the present invention, the amplifying unit 230 is a second selection connecting unit 228 for selectively connecting the measurement electrode sensor 190 according to the selection signal of the channel selection unit 214, and the second It includes an amplifier 232 for amplifying the high-voltage heart pulse wave through the selective connection unit 228 to a high voltage. In the present invention, the minute voltage refers to the voltage of the minute pulse current generated according to the heartbeat of the user. The amplification unit 230 is a part for measuring the electrocardiogram required to diagnose the user's heart-related diseases. Therefore, the amplifier 230 includes a separator 234 for separating the measured value amplified by the amplifier 232 into the measured values of Lead I, Lead II, Lead III, and V1, respectively. In the present invention, the V1 measurement value refers to a measurement value when the measurement electrode sensor 190 is attached to the user's chest and used. On the other hand, the separator 234 transmits the separated measured value to the A / D conversion unit 216 of the control unit.

In the present invention, the amplification processing unit 240 also includes a second selection connecting unit 228 for selectively connecting the measurement electrode sensor 190 according to the selection signal of the channel selection unit. That is, in the present invention, the second selective connecting unit 228 is shared by the amplifying unit 230 and the amplifying processing unit 240. The amplification processing unit 240 is a part of processing all or part of the measured data to obtain the body fat measurement data of the user. Accordingly, the amplification processing unit 240 includes a differential amplifier 242 for amplifying the micro voltage detected by the measuring electrode sensor 190 to a high voltage. In addition, the amplification processing unit 240 is a high pass filter 244 for passing the high frequency region at the amplified high voltage and removing noise in the low frequency region, and an AC voltage from which the noise in the low frequency region is removed as a DC voltage. An RMS converter 246 for converting and a low pass filter 248 for passing a low frequency region and removing noise in the high frequency region in the voltage converted into a DC voltage are included. In the present invention, the order of arranging the high pass filter unit 244, the RMS converter unit 246, and the low pass filter unit 248 is one of the most preferred embodiments of the present invention. Based on the experimental results that it can effectively amplify with high efficiency. The current passing through the low pass filter 248 is then transmitted to the A / D converter 216 of the controller.

4 is a block diagram schematically illustrating a method of operating the middle board member 200 according to the present invention in order of flow.

One). Start step:

When the user operates the computer main body to measure body fat and electrocardiogram, it is a step of confirming and preparing an abnormality of each component according to the control signal transmitted from the main body. In this case, the middle board member 200 of the present invention receives a predetermined control signal from the computer main body 110.

2). Metric selection step (S102):

This is a step of determining which item to select from the body fat measurement channel and the electrocardiogram measurement channel of the user according to the control signal of the computer main unit 110, and at the same time to combine the respective electrode sensors accordingly. For example, in order to measure the body fat of the user, since the four input electrode sensors 180 and the four measurement electrode sensors 190 must be combined with each other, a total of six combinations are possible and one of them is selected. It is. (For reference, all six combinations consist of LA-LL, LA-RA, RA-RL, RL-LL, LA-RL, RA-LL.) In contrast, if you want to measure your ECG, By using only the above-described measurement electrode sensor 190, respectively, LA-RA, LA-LL, and RA-LL are configured, and in addition, the chest electrode sensor is selected. In this case, the combination of the remaining electrode sensors that are not selected is sequentially operated under the control of the MCU 218.

3). Body information processing step (S103):

This is the step of measuring the information on the body fat or electrocardiogram by the electrode sensor 180, 190, and processing the measured information. The present invention relates to an operation method for the intermediate board member 200, the method for measuring body fat or electrocardiogram by each electrode sensor 180, 190 is beyond the scope of the present invention, and furthermore, The method of use can be carried out by conventional methods. Therefore, the detailed description of the use and measuring method of each electrode sensor 180, 190 will be omitted, and only the minimum area necessary for the description of the present invention will be described.

First, when the user's body fat measurement is selected in the channel selection step, the micro current is flowed to the user's body by the selected input electrode sensor 180, and the microelectrode is sensed and measured by the measuring electrode sensor 190. The measured fine voltage is amplified by the differential amplifier 242, and the amplified high voltage is removed by the high pass filter 244 to remove noise in the low frequency region, and then the RMS converter 246 is converted into a DC voltage. . Subsequently, the converted DC voltage is removed by the low pass filter unit 248 to remove noise in the high frequency region, and is transmitted to the A / D converter 216.

On the other hand, when the user's ECG measurement is selected in the channel selection step, the input sensor 190 is not operated, but only the measuring electrode sensor 190 is operated. The minute voltage sensed by the measuring sensor 190 is caused by the heartbeat, and is amplified by the amplifier 232, and then separated according to each lead, and then the A / D conversion unit ( 216).

4). Repeated implementation step (S104):

This is a step of repeating the above steps in order to obtain the body information by the combination of the other electrode sensor, once the combination of the selected one electrode sensor is completed through the above process. This overall process may be repeatedly performed according to the control signal of the MCU 210 of the control unit 210.

5). End step (S105):

This is the step when the user has obtained the desired result, has obtained all the information about the metric under the control of the computer system, or if the user no longer wants it. Thus, the operation relationship of the intermediate board member 200 according to the present invention is terminated.

5 is a conceptual diagram illustrating a case where the middle board member 200 according to the present invention is coupled to a computer system 300 for measuring body information. The computer system 300 for measuring physical information according to the present invention may be configured by combining the intermediate board member 200 with a conventional computer system.

The computer system for measuring physical information according to the present invention 300 includes an input unit 120 for inputting information from the outside; A main body unit 110 which processes various types of inputted information, stores processed information, transmits and receives processed information to the outside, and controls a system therein; An output unit 130 for displaying the processed information to the outside; An input electrode sensor 180 for sending a microcurrent to the user's body in order to measure the user's body information; It is preferably configured using a computer system consisting of a measuring electrode sensor 190 for sensing the micro voltage from the user's body and transmitting it to the main body.

In addition, the computer system 300 for measuring body information according to the present invention is provided with the intermediate board member 200 between the main body 110 and the electrode sensor 180, 190. As described in detail in the operation method of the middle board member 200, it is possible to efficiently control the plurality of electrode sensors 180, 190, and thereby the body fat and electrocardiogram of the user using the same electrode sensor This is because it can be measured simultaneously or sequentially. In the present invention, the main body 110 refers to a normal computer main body when the computer system is simply used to measure body fat and electrocardiogram, but to obtain body information other than the above measurement items. The concept includes an additional expansion slot or an additional midboard.

In addition, in the present invention, the middle board member 200 is in communication with the main body 110 as shown in Figure 5 and the control unit 210 to control itself according to the control signal of the main body and ; A current generator 220 generating a microcurrent to be input to the user's body; An amplifying unit 230 for measuring and amplifying a fine voltage from a user's body according to a control signal of the control unit and transmitting the amplified voltage to the control unit; The amplification processing unit 240 for measuring and amplifying and processing fine voltages from the user's body according to the control signal of the control unit, and then transmitting them to the control unit 210 again; It includes. Since the control unit 210, the current generator 220, the amplifier 230, and the amplification processor 240 have already been described in detail, repeated description thereof will be omitted.

Meanwhile, FIG. 6 relates to an actual product in which the computer system for measuring physical information of FIG. 5 is specifically realized. FIG. 6A is a photograph of the front of the actual product, and FIG. 6B is a side view of the actual product. One picture. In addition, in FIG. 6, in addition to the electrode sensors 180 and 190, a plurality of other measurement sensors are further combined.

In addition, Figure 7 is a preferred embodiment of the present invention, both the input electrode sensor 180 and the measuring electrode sensor 190 is formed of a forceps-type electrode sensor, the picture taken for the real. In addition, according to FIG. 6B, both the input electrode sensor 180 and the measuring electrode sensor 190 are used for different colors, and more specifically, green, red, black, and yellow, respectively. It can be seen.

When the computer system for measuring physical information according to the present invention is connected by a communication means such as the Internet, the above-described measured values can be transmitted to the central control system, where it can be integrated and managed.

Although the computer system for measuring physical information according to the present invention has been described in detail above, this is only for describing the most preferred embodiments of the present invention, and the present invention is not limited thereto. Is determined and defined. In addition, anyone of ordinary skill in the art will be able to make various modifications and imitations by the description of the specification of the present invention, but it will be apparent that this is also outside the scope of the present invention.

As such, the present invention employs a separate middle board member between the computer main body and the electrode sensors, so that a plurality of electrode sensors can be efficiently controlled and used.

In addition, the present invention can measure the body fat and the electrocardiogram of the user through the same electrode sensor by the above-mentioned middle board member, there is an advantage that can obtain different body information using the same measuring device.

In addition, since the present invention can obtain different body information using the same measuring device, there is an advantage that can be used in combination with another measuring device more in one computer system.

In addition, the present invention can obtain the measurement data more precisely by forming the shape of the measuring device closer to the body shape of the user, thereby obtaining more accurate body information.

In addition, the present invention can be connected to the central control system through a communication means such as the Internet, through which there is an advantage that can be integrated management.

1 is a schematic conceptual diagram introducing the basic concept for measuring the electrocardiogram of the body,

FIG. 2 is a schematic conceptual view of an intermediate board member that assists body fat and electrocardiogram of a body to be measured by the same measuring device.

3 is a detailed view showing the technical components of the more rescue of Figure 2,

4 is a schematic flowchart showing an operation relationship of the intermediate board member;

5 is a schematic conceptual diagram of a computer system for measuring physical information employing the above-mentioned middle board member;

6 is a photograph taken from the front and side of the actual product of the computer system for measuring physical information of FIG. 5 as a preferred embodiment of the present invention;

7 is a photograph of an actual product as a preferred embodiment of the electrode sensor used in the computer system for measuring physical information of the present invention.

♠ Explanation of symbols for the main parts of the drawings.

110: main body portion, 120: input portion,

130: output unit, 180: input electrode sensor,

190: measuring electrode sensor, 200: middle board member,

210: control unit, 212: communication unit,

214: channel selector, 216: A / D converter,

218: MCU, 220: current generator,

222: sine wave generator, 224: V-I converter,

226: first selective connecting portion, 228: second selective connecting portion,

230: amplifier 232: amplifier,

234: separator, 240: amplification processing unit,

242: differential amplifier, 244: high pass filter,

246: RMS converter, 248: low pass filter

Claims (9)

A control unit communicating with the computer main unit and controlling itself according to a control signal of the main body; A current generator for generating a microcurrent to be input to a user's body according to a control signal of the controller; An amplifying unit for measuring a minute voltage from a user's body according to a control signal of the control unit, amplifying the amplified voltage, and transmitting the amplified voltage to the control unit; Also an amplification processing unit for measuring a fine voltage from the user's body according to the control signal of the control unit, amplify and process it, and then transmits to the control unit again; Complementary circuit board for a computer suitable for a computer system for measuring physical information comprising a. The method of claim 1, The control unit and the communication unit for communicating with the computer main unit; A channel selection unit for selectively applying a current of the current generation unit to a specific electrode sensor according to a control signal of the computer main unit, and allowing the specific electrode sensor to selectively measure the minute voltage detected by the user's body; ; An A / D conversion unit for converting data transmitted from the amplification unit or the amplification processing unit into a digital value; MCU which controls the system of the middle board member by itself; An auxiliary circuit board for a computer suitable for a computer system for measuring physical information, characterized in that consisting of. The apparatus of claim 1, wherein the current generator comprises: a sine wave generator configured to supply a predetermined current to be input to a user's body; A V-I converter converting the voltage transmitted from the sine wave generator into a constant current; A first selection connector electrically connecting the V-I converter to an input electrode sensor according to a selection signal of the channel selector; An auxiliary circuit board for a computer suitable for a computer system for measuring physical information, characterized in that consisting of. The method of claim 1, The amplifying unit comprises: a second selective connecting unit electrically connecting the input electrode sensor and the amplifier according to the selection signal of the channel selecting unit; An amplifier for amplifying the measured microvoltage; A separator for separating the amplified voltage value according to each lead and transmitting the amplified voltage value to the A / D converter; An auxiliary circuit board for a computer suitable for a computer system for measuring physical information, characterized in that consisting of. The method of claim 1, The amplification processing unit includes a second selective connection unit for electrically connecting the measurement electrode sensor and the differential amplifier according to the selection signal of the channel selection unit; A differential amplifier for amplifying the measured microvoltage; A high pass filter for filtering out noise in the low frequency region from the amplified voltage value; An RMS converter for converting an AC current from which noise in a low frequency region is removed into a DC current; A low pass filter unit filtering the noise in the high frequency region of the DC current through the RMS converter and transmitting the noise to the A / D converter; An auxiliary circuit board for a computer suitable for a computer system for measuring physical information, characterized in that consisting of. delete An input unit for inputting information from the outside; A main body which processes various types of inputted information, stores processed information, transmits and receives processed information to the outside, and controls a system therein; An output unit for displaying the processed information to the outside; An input electrode sensor for sending a microcurrent to the user's body to measure the user's body information; In the computer system consisting of a measuring electrode sensor for detecting the fine voltage from the user's body and transmits to the main body portion, One). An auxiliary circuit board for a computer is provided between the main body and the electrode sensor. 2). The auxiliary circuit board for a computer may include a control unit communicating with the main body unit and controlling itself according to a control signal of the main body unit; A current generator for generating a microcurrent to be input to a user's body according to a control signal of the controller; An amplifying unit for measuring a minute voltage from a user's body according to a control signal of the control unit, amplifying the amplified voltage, and transmitting the amplified voltage to the control unit; Also an amplification processing unit for measuring a fine voltage from the user's body according to the control signal of the control unit, amplify and process it, and then transmits to the control unit again; Computer system for measuring body information, characterized in that it comprises a. The method of claim 7, wherein The input electrode sensor and the measuring electrode sensor is a forceps type computer system for measuring physical information, characterized in that. The method of claim 7, wherein The input electrode sensor and the measurement electrode sensor is a computer system for measuring body information, characterized in that formed in different colors according to the attachment position of the body.