JP2016116727A - Biological information management system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a biological information management system in which, by having output means and accumulation means for detected biological information, acquisition of biological information in accordance with detecting environment and conditions as well as efficient acquisition of accumulated biological information are made possible and in which, by analyzing a biological state based on acquired biological information, efficient management of a biological state is made possible.SOLUTION: The system includes: a biological information detector body 10 attachable to an examinee; a placing table 20 for placing the biological information detector body 10; and an analyzer 30 for analyzing biological information. The biological information detector body 10 is provided with a memory 310 for storing detected biological information and with a transmission part for transmitting biological information detected and biological information stored in the memory 310. When the biological information detector body is placed on the placing table for electric charging, the transmission part outputs the biological information stored in the memory to the outside through a communication part provided for the placing table. The analyzer inputs biological information outputted from the transmission part and the communication part to analyze the sleep state and motion state of an examinee.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a biological information management system that incorporates various sensors, wears them on the body, detects long-term biological information, and analyzes the biological state of a subject using the detected biological information. It has a means to process, transmit and store the detected biological information, and it can be used easily for a long time with a simple charging means, has an excellent S / N ratio and is highly waterproof, and is suitable for the environment and conditions to be detected. Provided with a biological information detection device capable of transmitting and storing detected biological information, and analyzing the subject's sleep, exercise, etc. based on the biological information from the biological information detection device The present invention relates to a biological information management system capable of efficiently managing a biological state.

  Biological information such as body temperature and pulse is used to grasp the health condition of the subject and abnormalities of the body. The detection of the biological information of the subject is usually performed by a third person such as the subject himself or a nurse with a sensor (biological information sensor) such as a thermometer in contact with the body of the subject for a certain period of time. . Since this biological information sensor is usually in contact with the body for a few minutes, only temporary biological information can be detected, and infrequent occurrences are not detected. May not be able to grasp. For example, since an arrhythmia or abnormal heart rate does not always appear, there is a possibility that it cannot be grasped by a short-time contact of the biological information sensor. In this case, if the biological information sensor can detect biological information for a long time, this possibility can be reduced.

  Moreover, in order to make an accurate determination in preventive medicine, sports medicine, etc., collection of biological information over a long period of time is very effective, and a biological information sensor that can realize this is required.

  Furthermore, there is a need for a system that effectively utilizes the long-term biological information acquired from such a biological information sensor, analyzes the health and exercise state of the subject, and efficiently manages the biological state of the subject. It has been.

  Therefore, in order to enable detection of biological information for a long time, a method has been proposed in which a small and light biological information sensor is attached to a subject and data detected by the sensor is transmitted wirelessly.

  For example, in Japanese Patent Application Laid-Open No. 2001-353130 (Patent Document 1), a biological information sensor is disposed in a storage case formed in an ear-hook type or a form that can be inserted into the ear canal or in a pendant shape. The data detected by the biological information sensor is transmitted wirelessly.

  In Patent Document 1, there is one place where the biological information sensor contacts the body of the subject. However, in Japanese Patent No. 3843118 (Patent Document 2) and Japanese Patent No. 4589341 (Patent Document 3), the biological information sensor is not connected. By making contact with multiple locations, it is possible to detect more abnormalities in the body.

  In Patent Document 2, biological information sensors are attached to the right and left half of the body, and abnormality determination of the body is performed based on biological information wirelessly communicated from the biological information sensor. The integrated circuit mounted on the biological information sensor includes a memory, and data detected by the biological information sensor can be stored in the memory.

  In Patent Document 3, biometric information sensors are attached to at least one set of a plurality of locations on the upper and lower bodies of the body, upper and lower limbs, abdominal and lower limbs, relatively above and below the body, or on the front and back of a part of the body. The abnormality of the body is determined based on the biological information wirelessly communicated from the biological information sensor. In addition, at least one of the plurality of biological information sensors includes a memory and can store the detected biological information.

  There has been proposed a system for analyzing sleep and movement of a subject using such a biological information sensor attached to the subject.

  For example, in Japanese Patent Application Laid-Open No. 2012-55464 (Patent Document 4), an attitude sensor that is transmitted by wired communication or wireless communication from an acceleration sensor attached to a body portion of a subject and a photoelectric sensor attached to a finger or the like, and The information on the pulse rate is used to evaluate the sleep quality of the subject.

  In Japanese Patent Application Laid-Open No. 2007-143959 (Patent Document 5), a sensor unit including an electrocardiogram sensor, an acceleration sensor, a temperature sensor, and the like is adhered and pasted to a subject's chest and the like, and a signal from the sensor unit is sent to the subject's chest. By transmitting to the center device via a wireless repeater worn on the shoulder of clothes, etc., the center device determines the state of the subject exercising on the ground or the like.

JP 2001-353130 A Japanese Patent No. 3843118 Japanese Patent No. 4589341 JP2012-55464A JP 2007-143959 A Japanese Patent No. 3946108

  However, in Patent Document 1, the biometric information sensor is small and light, and it is possible to detect biometric information for a long time. However, since data output from the biometric information sensor is performed by wireless communication, There is a possibility that biometric information cannot be acquired in an environment where it is difficult to perform wireless communication, or in an environment where it is difficult to install a device that receives wireless communication such as in a crowded train.

  Even in Patent Documents 4 and 5, since data from the biological information sensor is transmitted by wireless communication, it can be used when sleeping or exercising on the ground, but cannot be applied to the above environment. . In addition, when acquiring and analyzing biological information in daily life in the time zone before and after sleep and exercise together to obtain more useful analysis results, the systems of Patent Documents 4 and 5 do Biometric information cannot be acquired.

  In Patent Documents 2 and 3, the biometric information detected by the biometric information sensor can be stored in a memory equipped in the biometric information sensor in addition to transmission to the outside through wireless communication. Even in the time zone, biometric information can be acquired by using the memory. However, in this case, it is necessary to separately take out the biological information stored in the memory.

  The present invention has been made under the circumstances as described above, and an object of the present invention is a means for processing, transmitting, and storing long-term biological information detected by various built-in sensors attached to the body. In addition, it can be used easily for a long time with simple charging means, has an excellent S / N ratio, is highly waterproof, and can acquire biological information according to the environment and conditions to be detected. A biological information management system comprising a biological information detection device capable of transmitting and storing, and capable of analyzing a subject's sleep, exercise, etc. based on biological information from the biological information detection device and efficiently managing the biological state Is to provide.

  The present invention relates to a biological information management system including a biological information detection device that is mounted on a subject and measures biological information, and an analysis device that analyzes the biological information. The object of the present invention is to detect the biological information. The apparatus includes a biological information detection device body that can be attached to a subject and a mounting table on which the biological information detection device body is placed, and the biological information detection device body detects biological information of the subject. A biological information detection unit, a memory for storing biological information detected by the biological information detection unit, a biological information detected by the biological information detection unit, and a biological information stored in the memory are output by wireless transmission And a charging input unit that generates power necessary for the body of the biological information detection device, and the mounting table is output from the charging output unit that generates power in the charging input unit and the transmitting unit. Receive biometric information And a communication unit that outputs the received biological information to the outside, wherein the transmission unit can select whether or not to output the biological information detected by the biological information detection unit. When the charging input unit is generating power, the biometric information stored in the memory is output from the transmission unit, the output biometric information is received by the communication unit, and the received biometric information is The information is output from the communication unit to the outside, and the analysis device is achieved by inputting the biological information output from the transmission unit and the communication unit and analyzing the sleep state of the subject from the biological information.

  In addition, the object of the present invention is to provide the biological information detection device, comprising: a biological information detection device main body that can be attached to a subject; and a mounting table on which the biological information detection device main body is mounted; The apparatus main body includes a biological information detection unit that detects biological information of the subject, a memory that stores biological information detected by the biological information detection unit, biological information detected by the biological information detection unit, and A transmitter that wirelessly transmits the biological information stored in the memory; and a charging input unit that generates electric power necessary for the biological information detection apparatus body, wherein the mounting table supplies electric power to the charging input unit. A living body detected by the biometric information detection unit, the charging output unit to be generated; and a communication unit that receives the biometric information output from the transmission unit and outputs the received biometric information to the outside. Whether to output information The biometric information stored in the memory is output from the transmitter when the charge input unit generates power by the charge output unit, and the biometric information output is output to the communication unit And the received biological information is output from the communication unit to the outside, and the analysis device inputs the biological information output from the transmitting unit and the communication unit, and exercises the subject from the biological information. This is achieved by analyzing the state.

  Further, the object of the present invention is to detect the biological information at least before and after sleeping in addition to the biological information during sleep of the subject. By analyzing the sleep state of the subject using at least one of the biological information before and after sleeping in addition to the biological information during sleep, or the biological information detection unit In addition to biological information during exercise, at least any biological information before and after exercise is detected, and the analysis apparatus adds at least either before or after exercise to the biological information during exercise. By analyzing the motion state of the subject using the biological information, or the analysis device includes a display unit that displays the analysis result, or the analysis device analyzes Accumulation of results Or the biological information detection unit includes at least a body temperature sensor that detects a body temperature of the subject, an acceleration sensor that detects the posture of the subject, and an electrocardiographic signal of the subject. This is achieved more effectively by including an electrocardiographic signal sensor for detection.

  The biological information management system according to the present invention includes means for outputting the biological information detected by the sensor attached to the body to the outside at the time of detection, and means for storing the biological information in the memory. It is possible to acquire biological information in accordance with the environment and conditions to be detected. In addition, since a means for reading out the biometric information stored in the memory at the time of charging and outputting it to the outside is provided, it is possible to simultaneously perform charging and acquisition of the biometric information stored in the memory. And since biological information can be acquired efficiently in this way, analysis in various states and analysis over a long time can be performed in analysis of a subject's sleep, exercise, etc.

It is a block diagram which shows the structural example (1st Embodiment) of this invention. In the structural example (1st Embodiment) of this invention, it is a block diagram which shows the structural example of a biometric information detection apparatus. FIG. 3 is a block diagram illustrating a configuration example of a control unit in a configuration example (first embodiment) of the present invention. 5 is a flowchart illustrating an operation example of a control unit in a configuration example (first embodiment) of the present invention. It is an image figure which shows the example of an electrocardiogram waveform. It is an image figure which shows the example of the basic waveform of the electrocardiogram waveform for one night of a heartbeat, and an abnormal waveform. It is a graph which shows the example of the time change of the variation | change_quantity of RR interval. It is a table | surface which shows the METs value with respect to the activity content of a body. It is a graph which shows the example which plotted the activity of the autonomic nerve (sympathetic nerve, parasympathetic nerve) during sleep. It is a figure which shows the example of a display of analysis data in the structural example (1st Embodiment) of this invention. It is a block diagram which shows the structural example (2nd Embodiment) of this invention. In the structural example (2nd Embodiment) of this invention, it is an image figure which shows the example which displayed the analysis data as a locus | trajectory of a motion. It is a block diagram which shows the structural example (3rd Embodiment) of this invention. It is a block diagram which shows the structural example (4th Embodiment) of this invention. In this invention, it is an image figure which shows the example which mounts | wears with the biological information detection apparatus main body in the multiple places of a subject's body.

  The biological information management system according to the present invention includes a biological information detection device that measures biological information of a subject and an analysis device that analyzes biological information, and the biological information detection device includes a biological information detection device main body and a mounting table. ing. Each of the sensors constituting the biological information detection unit in the biological information detection device main body detects biological information at a predetermined interval, and the biological information detection device main body includes a transmission unit that wirelessly transmits the detected biological information and a memory that stores the memory. Yes. And when biometric information is detected, it can be selected whether or not the biometric information is wirelessly transmitted. Therefore, the detected biometric information is stored in the memory and wirelessly transmitted at the same time. You can also. The transmission unit can also wirelessly transmit the biological information stored in the memory.

  The biological information detection device main body is charged by being placed on the placement table. Charging is performed by a non-contact charging method that can be performed without using a metal contact or a connector. The mounting table includes a communication unit that receives biological information wirelessly transmitted from a transmission unit in the biological information detection device body, and the biological information stored in the memory when the biological information detection device body is charged. The information is wirelessly transmitted by the transmission unit, and the biological information is received by the communication unit. The received biological information is output to the outside from the communication unit.

  Thereby, it is possible to acquire biometric information in accordance with the environment and conditions for detecting biometric information, and it is possible to simultaneously perform charging of the main body of the biometric information detection device and acquisition of biometric information stored in the memory.

  It is also possible to select whether or not to output biometric information to the outside when the biometric information detection apparatus main body is charged. Thus, when charging is performed frequently and wireless transmission is performed only when a certain amount of biometric information is accumulated, only charging can be performed.

  The analysis device inputs the biological information output from the biological information detection device, and analyzes the biological state of the subject using the biological information.

  Embodiments of the present invention will be described below in detail with reference to the drawings.

  FIG. 1 is a block diagram illustrating a configuration example (first embodiment) of the present invention, which is a configuration example of a system for managing a sleep state of a subject, and includes a biological information detection device 1 and an analysis device 30. ing.

  First, the configuration and operation of the biological information detection apparatus 1 will be described.

  FIG. 2 is a block diagram illustrating a configuration example of the biological information detection apparatus 1.

  The biological information detection device 1 includes a biological information detection device main body 10 and a mounting table 20. The biological information detecting device main body 10 is attached to the chest of the subject. The biological information detection apparatus main body 10 includes a biological information detection unit 100, and the biological information detection unit 100 includes a body temperature sensor 110, an acceleration sensor 120, and an electrocardiogram signal sensor 130. The body temperature sensor 110 measures the epidermis temperature of the subject and outputs body temperature data T at predetermined intervals. The acceleration sensor 120 detects a three-dimensional movement of the subject and outputs acceleration data α = (αx, αy, αz) in the X direction, the Y direction, and the Z direction at predetermined intervals. Here, αx is the acceleration in the X direction, αy is the acceleration in the Y direction, and αz is the acceleration in the Z direction. The electrocardiogram signal sensor 130 has two electrodes, and in order to detect a subject's electrocardiogram signal, each electrode is brought into contact with the subject's body, and a potential (potential signal) is measured. The difference between the two measured potentials is output as ECG signal data E at a predetermined interval. Note that three or more electrodes may be used, and in that case, a plurality of potential differences are calculated. The potential signal to be measured is weak and is amplified by an amplifier or the like inside the electrocardiogram signal sensor 130, so that it is easily affected by noise. Therefore, in order to reduce the influence of noise and improve the S / N ratio, electrodes, amplifiers, and the like are arranged close to each other. Note that the interval at which the body temperature data T is output, the interval at which the acceleration data α is output, and the interval at which the electrocardiogram signal data E is output may be the same or different. For example, since the skin temperature normally has a small fluctuation, the interval at which the body temperature data T is output may be set longer than the others. Thereby, the amount of data to be acquired can be reduced. Further, the interval at which the body temperature data T is output, the interval at which the acceleration data α is output, and the interval at which the electrocardiogram signal data E is output may be changed instead of a fixed value. When it is assumed that there is a large change in value immediately after exercise or the like, it is possible to obtain appropriate biological information that matches the physical condition by making adjustments such as shortening the output interval.

  Body temperature data T, acceleration data α, and electrocardiogram signal data E (collectively referred to as biological information data BD) output from the biological information detection unit 100 are input to the control unit 140. The control unit 140 stores the input body temperature data T, acceleration data α, and electrocardiogram signal data E in respective areas in the memory 150 set in advance for each data. The method of storing the biometric information data BD in the memory 150 is not limited to the method of storing the biometric information data BD in an area set in advance for each data, and an identifier for distinguishing each data is set without specifying the area. Alternatively, the acceleration data α and the electrocardiogram signal data E may be added to the memory 150 together with their identifiers.

  When the biometric information is set to be transmitted to the outside when detecting the biometric information (hereinafter referred to as simultaneous transmission setting), the control unit 140 outputs the biometric information data BD to the transmission unit 160. The transmission unit 160 converts the input biometric information data BD into a format that can be received by the analysis device 30 and wirelessly transmits the biometric information signal BS1. As a wireless transmission method, a Wi-Fi method, a Bluetooth (registered trademark) method, or the like is used.

  Note that the time for which the biological information detection unit 100 measures biological information may be changed for each of the body temperature sensor 110, the acceleration sensor 120, and the electrocardiogram signal sensor 130. As a result, it is possible to take a flexible measure such as shortening the measurement time of biological information that requires a large amount of power for detection, or increasing the measurement time when the physical condition is not good.

  Here, the operation | movement at the time of charging the biometric information detection apparatus main body 10 is demonstrated.

  As shown in FIG. 2, the biological information detection apparatus main body 10 has a charge input unit 170, and the mounting table 20 has a charge output unit 200. When the biological information detecting device main body 10 is placed on the mounting table 20 and the charging input unit 170 and the charging output unit 200 are brought close to each other, the electric power required by the biological information detecting device main body 10 uses electromagnetic induction (electromagnetic induction). System). That is, the charging input unit 170 and the charging output unit 200 each have a coil. When a current flows through the coil of the charging output unit 200, a magnetic flux is generated, and is induced by the magnetic flux. Current flows and charging takes place. Note that as a non-contact charging method, a resonance method or the like may be used instead of the electromagnetic induction method. As a power source to be charged, a secondary battery such as a nickel cadmium battery or a lithium ion battery, a super capacitor (electric double layer capacitor), or the like is used.

  The mounting table 20 also includes a communication unit 210 that receives a biological information signal wirelessly transmitted from the transmission unit 160 of the biological information detection device body 10 and wirelessly transmits the signal to the outside, and the biological information detection device body 10 is charged. At the same time, a biological information signal is received from the transmitter 160 and wirelessly transmitted to the outside. That is, when charging is started by electromagnetic induction, the charging input unit 170 outputs a charging start signal CS to the control unit 140, and when the charging unit CS inputs the charging start signal CS, the biological information stored in the memory 150 is stored. The data BD is output to the transmission unit 160, and the transmission unit 160 converts the input biometric information data BD into a format that can be received by the communication unit 210, and wirelessly transmits the biometric information signal BS2. The communication unit 210 receives the biological information signal BS2, converts it into a format that can be received by the analysis device 30, and wirelessly transmits the biological information signal BS3. At this time, as a wireless transmission method used by the transmission unit 160 and the communication unit 210, the Wi-Fi method, the Bluetooth (registered trademark) method, or the like is used, and the biometric information signal BS2 is converted. The method used for the method may be the same as or different from the method used to convert the biological information signal BS1 or BS3. However, when the biological information signal BS2 is wirelessly transmitted, the transmission unit 160 and the communication unit 210 are close to each other, so that power consumption can be suppressed by using the short-range communication method.

  As described above, charging is performed by a non-contact charging method, and transmission / reception of biometric information during charging is performed wirelessly, so that an input / output terminal for external connection is unnecessary, and waterproofness can be increased.

  FIG. 3 is a block diagram illustrating a configuration example of the control unit 140, and FIG. 4 is a flowchart illustrating an operation example of the control unit 140.

  As shown in FIG. 3, the control unit 140 includes a data processing unit 141, a mode setting unit 142, a switching unit 143, and a data reading unit 144. The data processing unit 141 reads the biometric information data BD (body temperature data T, acceleration data α, and electrocardiographic signal data E) output from the biometric information detection unit 100 and outputs it to the memory 150 and the switching unit 143. The mode setting unit 142 inputs a charging start signal CS output from the charging input unit 170 when charging of the biological information detecting apparatus body 10 is started. And the mode setting part 142 determines the output mode of biometric information data BD based on the presence or absence of the input of the charge start signal CS, and the information of ON / OFF of simultaneous transmission setting, and outputs it as the mode signal MS. That is, when the charging start signal CS is input, the “memory data output mode” is set. When the charging start signal CS is not input and the simultaneous transmission setting is ON, the “simultaneous transmission mode” is set, and the charging start signal CS is not input. When the simultaneous transmission setting is OFF, set to “no output mode”. The mode signal MS is input to the switching unit 143. The data reading unit 144 also receives the charging start signal CS, and when the charging start signal CS is input, the biometric information data BD stored in the memory 150 is read and output to the switching unit 143.

  An example of the operation of the control unit 140 will be described with reference to the flowchart of FIG.

  The data processing unit 141 reads the biological information data BD output from the biological information detecting unit 100 (step S1). The read biometric information data BD is stored in the memory 150 (step S2) and simultaneously input to the contact 143a of the switching unit 143.

  If the mode signal MS output from the mode setting unit 142 is “simultaneous transmission mode”, the switching unit 143 is connected to the contact 143a, and the biological information data BD is output to the transmission unit 160 (step S3). If the mode signal MS is “non-output mode”, the switching unit 143 is not connected to either contact, and the biological information data BD is not output. If the mode signal MS is “memory data output mode”, the switching unit 143 is connected to the contact 143b. At this time, when the charging start signal CS is input to the data reading unit 144, the data reading unit 144 reads the biometric information data BD stored in the memory 150 (step S4), and outputs it to the contact 143b of the switching unit 143. The biometric information data BD stored in the memory 150 is output to the transmission unit 160 (step S5).

  Next, the configuration and operation of the analysis device 30 will be described.

  As shown in FIG. 1, the analysis device 30 includes a biological information input unit 300, a memory 310, a sleep state analysis unit 320, and a display unit 330.

  The biological information input unit 300 receives the biological information signal BS1 transmitted from the transmission unit 160 of the biological information detection apparatus body 10 and the biological information signal BS3 transmitted from the communication unit 210 of the mounting table 20, and receives the biological information data BD. The format is restored and stored in the memory 310. Similar to the storage method in the memory 150, the storage method in the memory 310 also distinguishes each data by a method in which the body temperature data T, the acceleration data α, and the electrocardiogram signal data E are stored in a preset region. A method of adding an identifier to each data and storing it together with the identifier may be used.

  When the measurement of the biological information of the subject by the biological information detecting device 1 is completed and all the acquired biological information data BD is stored in the memory 310, the sleep state analyzing unit 320 stores the biological information data stored in the memory 310. The BD is read and the analysis data AS relating to the sleep state of the subject is calculated using them. Information calculated as analysis data AS includes abnormal waveform information, heart rate, instantaneous heart rate, arrhythmia information, sympathetic nerve information, parasympathetic nerve information, REM sleep / non-REM sleep information, apnea syndrome determination, momentum, posture information, roll over Frequency, sleep / wake estimation information, energy consumption and body temperature. Hereinafter, each information will be described.

  The electrocardiographic signal data E in the biological information data BD read from the memory 310 forms an electrocardiographic waveform as shown in FIG. With regard to this electrocardiogram waveform, the basic waveform for one night of heartbeat is a waveform as shown in FIG. 6A, and the peak and valley portions of the waveform are shown in FIG. They are called waves, Q waves, R waves, S waves, and T waves. In the electrocardiogram waveform formed from the electrocardiogram signal data E, if a location whose shape is greatly different from this basic waveform is found, the judgment result that there is an abnormal waveform is displayed along with the information (time etc.) of the found location. Use abnormal waveform information. If there is no portion that is largely different from the basic waveform, the determination result that there is no abnormal waveform is used as abnormal waveform information. As a waveform that is largely different from the basic waveform, for example, as shown in FIG. 6B, the T wave overlaps with the R wave and disappears. Such a waveform can be found by extracting a P wave, a Q wave, an R wave, an S wave, and a T wave from the electrocardiogram waveform and by the presence or absence of the T wave.

  R waves are extracted from the electrocardiogram waveform, and the number of R waves extracted every minute and the interval between two adjacent R waves (RR interval) are calculated. Of these, the number of R waves extracted every minute is the heart rate, and the reciprocal of the RR interval is the instantaneous heart rate. When the movement of the autonomic nerve instantaneously changes, the instantaneous heart rate immediately changes correspondingly. Therefore, the movement of the autonomic nerve can be analyzed by calculating the instantaneous heart rate. The heart rate and the instantaneous heart rate are time-series information (information in which data calculated at regular time intervals is arranged).

  The rate of change of the RR interval is calculated, and when there is a portion where the rate of change is greater than a predetermined value, that point is determined as arrhythmia. The variation rate is a value obtained by dividing a difference ΔRR (= RR2−RR1) between two RR intervals RR1 and RR2 that are temporally continuous by RR1. The predetermined value is set based on empirical knowledge. The maximum number of times determined as arrhythmia and the number of times determined as arrhythmia per minute is used as arrhythmia information.

  Sympathetic information and parasympathetic information are also calculated using the RR interval. Usually, the RR interval fluctuates periodically, and there is a knowledge that this fluctuation pattern is related to the function of the autonomic nerve (sympathetic nerve, parasympathetic nerve). Therefore, by analyzing the fluctuation of the RR interval Information on autonomic nerves can be obtained. When the difference RR in the RR interval is plotted with the time as the horizontal axis, a waveform such as that shown in FIG. 7 is obtained. By analyzing the frequency of this waveform and calculating the frequency components of the low frequency component and the high frequency component, the autonomic nerve The sympathetic nerve information and the parasympathetic nerve information, which are information regarding For example, 0.04 to 0.15 second is a low frequency component, and 0.15 to 0.4 second is a high frequency component, and the frequency component of each band is calculated. The low frequency component is sympathetic nerve information, the low frequency component and the high frequency component. The ratio of components is used as parasympathetic information. This is a calculation based on the fact that it is generally said that the sympathetic nerve promotes the pulsation of the heart and the parasympathetic nerve suppresses the pulsation of the heart. Sympathetic information and parasympathetic information are time-series information.

  The REM sleep / non-REM sleep information is calculated from sympathetic nerve information and parasympathetic nerve information. Since there is knowledge that sympathetic nerve activity is reduced and parasympathetic activity is dominant in REM sleep, and sympathetic nerve activity is dominant in REM sleep, the ratio of sympathetic nerve information and parasympathetic nerve information is obtained, A threshold is set in advance, and it is determined whether it is REM sleep or non-REM sleep by comparison with the threshold. The REM sleep / non-REM sleep information is time-series information of the determination result. The discrimination between the REM sleep and the non-REM sleep is performed while the posture information (described below) is determined as the supine position (the supine position, the prone position, the right side supine position, or the left side supine position).

  Apnea syndrome determination is calculated from the respiratory frequency calculated using the RR interval. Apnea Syndrome (Sleep Apnea Syndrome) is an illness that causes apnea when sleeping. Apneas that have stopped breathing for 10 seconds or more are 30 or more times in 7 hours or 5 times per hour. If it is above, it is diagnosed as apnea syndrome. Therefore, if the respiratory frequency is calculated by the method described in, for example, Japanese Patent No. 3946108 (Patent Document 6) using the RR interval and this diagnostic condition is satisfied, there is no possibility of apnea syndrome. Possible to determine respiratory syndrome. If not, there is no possibility.

  The momentum and posture information is obtained by integrating the acceleration data α = (αx, αy, αz) in the biological information data BD read from the memory 310 and the acceleration data α, and velocity data V = (Vx, Vy). , Vz). Here, Vx is a velocity in the X direction, Vy is a velocity in the Y direction, and Vz is a velocity in the Z direction, which are calculated by integrating αx, αy, and αz, respectively.

  The amount of exercise is calculated by multiplying the speed data V by the weight of the subject. However, since the speed data V is three-dimensional data, a value obtained by multiplying the magnitude of the speed data | V |

Posture information indicates that the subject's posture is standing (standing, sitting), supine (upward), prone (down), right-sided (right-side down), and left-sided (down left) As a result of discriminating which state of the posture), the velocity data V and the acceleration data α are discriminated. That is, if the height direction of the body in the supine position (sleeping state) is the X direction and the height direction of the body in the standing position (standing position) is the Z direction, the acceleration in the Z direction increases and a certain amount of time Detects changes from standing to prone position or prone position to standing position due to the occurrence of speed, and whether there is an increase in acceleration in the Y direction and Z direction and the speed generation time in the supine position, supine position, prone position, right-side position Alternatively, a change to the left lateral position is detected. The posture information is time-series information.

  The number of turnovers is calculated from the posture information. That is, the number of times that the prone position has changed in the time determined to be sleeping from the sleep / wake estimation information (described below) is set as the number of times of turning over.

  Sleep / wake estimation information is calculated from posture information, sympathetic nerve information, and parasympathetic nerve information. Based on the knowledge that it is in a supine position during sleep, and first becomes a non-REM sleep state after falling asleep, posture information changes from a standing position to a supine position (a supine position, a prone position, a right-sided position or a left-sided position). It is determined that the user has fallen asleep when entering the non-REM sleep state, the user is determined to have been awake when the posture information is in a standing position, and the period from sleep to awake is assumed to be sleeping. The sleep / wake estimation information is time-series information.

  Energy consumption (calorie consumption) is calculated using a unit called METs. METs (Metabolic equivalents) are values that represent the exercise intensity (oxygen intake) of a specific exercise, with rest being 1, and as shown in FIG. 8, numerical values are defined for each exercise (activity) content. ing. The energy consumption (calorie consumption) is calculated by the following formula 2 using the numerical value of METs.

Although not shown in FIG. 8, since the value of METs during sleep is defined as 0.9, by calculating the time during which sleep / wake estimation information is sleeping, consumption during sleep Calculate energy.

  As for the body temperature, the body temperature data T in the biological information data BD read from the memory 310 is used as it is.

  As the information calculated as the analysis data AS, a part of the information described above or information other than the above may be added, and the calculation of each information may be performed by a method other than the above.

  The calculated analysis data AS is output to the display unit 330. The display unit 330 displays the input analysis data AS on a display or the like. Time-series information such as heart rate in the analysis data AS is displayed in a two-dimensional graph with time as the horizontal axis. Sympathetic nerve information and parasympathetic nerve information are also displayed as a two-dimensional graph with time as the horizontal axis. Furthermore, the vertical axis represents sympathetic nerve information and the horizontal axis represents parasympathetic nerve information, and both values at each time point are plotted. A two-dimensional graph is also displayed. A subject or a third party can determine whether the sleep is good or bad by viewing the latter graph. In general, sleep with strong parasympathetic nerve is said to be good quality and sleep with strong sympathetic nerve is said to be poor. Therefore, when the shape of the graph is as shown in FIG. When it becomes like (C), it can be determined that sleep is bad, and when it becomes like FIG. 9B, it can be determined as normal sleep. A display example by the display unit 330 is shown in FIG.

  As a display method of the analysis data AS by the display unit 330, only the information obtained by thinning out the data or the minimum necessary information is displayed on the first display screen, and the location where the problem has occurred, for example, the electrocardiogram waveform is determined to be an abnormal waveform. For example, a more detailed information may be displayed for the location.

  The biological information detection device main body 10 is not worn only during sleep, but may be worn for 24 hours, for example, to detect biological information in daily life before and after sleep, and use them to analyze the sleep state. . Thereby, for example, abnormalities in the heart rate by comparing the heart rate during the day with the heart rate during sleep, changes in the quality of sleep due to the amount of energy consumed during the day, and the like can be examined.

  FIG. 11 is a block diagram showing another configuration example (second embodiment) of the present invention, which is a configuration example of a system for managing the exercise state of a subject. In the second embodiment, the same components as those in the first embodiment shown in FIG. 1 are denoted by the same reference numerals, and the second embodiment is the first embodiment except for the motion state analysis unit 420 and the display unit 430. Since the form and configuration are the same, description of the same configuration is omitted.

  When the measurement of the biological information of the subject by the biological information detection apparatus 1 is completed and all the acquired biological information data BD is stored in the memory 310, the exercise state analysis unit 420 stores the biological information data stored in the memory 310. The BD is read, and the analysis data AE relating to the exercise state of the subject is calculated using them. Information calculated as the analysis data AE is instantaneous force, moving speed, moving distance, moving position, momentum, energy consumption, heart rate, sympathetic nerve information, and parasympathetic nerve information. Hereinafter, each information will be described. The amount of exercise, energy consumption, heart rate, sympathetic nerve information, and parasympathetic nerve information are the same as the information calculated by the sleep state analysis unit 320 in the first embodiment, and thus description thereof is omitted.

  Acceleration data α = (αx, αy, αz) in the biological information data BD read from the memory 310 is instantaneous force data. Then, speed data V = (Vx, Vy, Vz) calculated by integrating the acceleration data α is data on the moving speed. Further, the distance data S = (Sx, Sy, Sz) calculated by integrating the speed data V is the moving distance. Here, Sx is a distance in the X direction, Sy is a distance in the Y direction, and Sz is a distance in the Z direction, which are calculated by integrating Vx, Vy, and Vz, respectively.

  The movement position is calculated using the movement distance. In calculating the movement position, first, the position P0 = (x0, y0, z0) of the subject at the time of starting measurement is set. Values to be set are input from the outside, or 0 is set in advance for all relative position calculations. After P0 is set, the movement position is calculated by adding movement distance data as time series information in time order.

  In addition, as information calculated as analysis data AE, the information other than the above may be added in part of the above, and each information may be calculated by a method other than the above.

  The display unit 430 receives the analysis data AE calculated and output by the exercise state analysis unit 420 and displays it on a display or the like. The displayed content varies depending on the content of the exercise to be measured. For example, when a soccer player's motion during a game is a measurement target, a movement trajectory or the like as shown in FIG. 12 using information on the movement position in the analysis data AE is displayed.

  In addition, by attaching the biological information detection apparatus main body 10 not only during exercise but also before and after exercise, a more detailed analysis of the exercise state becomes possible. For example, by calculating the heart rate and energy consumption before exercise, it becomes possible to examine the influence of these on the biological state during exercise. In addition, the biological information detection apparatus is shared with the system of the first embodiment, and the sleep state analysis on the day before and after exercise is performed on the system of the first embodiment, thereby examining the influence of sleep quality on exercise. be able to.

  In the first embodiment and the second embodiment, by accumulating the analysis data calculated by the analysis device, it is possible to investigate the secular change of the biological state.

  FIG. 13 is a block diagram illustrating a configuration example (third embodiment) in which a storage unit is added to the analysis apparatus with respect to the first embodiment illustrated in FIG. 1. Note that in the third embodiment, identical symbols are assigned to configurations identical to those in the first embodiment and descriptions thereof are omitted.

  The accumulation unit 500 receives the analysis data AS output from the sleep state analysis unit 320 and stores the analysis data AS together with information (for example, date) regarding the time when the biological information data BD is acquired. For example, the biological information detection device 1 adds the time information to the biological information data BD, and the sleep state analysis unit extracts the information from the analysis data AS, or is input from the outside when the analysis data AS is stored. It is set by doing. Display unit 530 displays analysis data AS corresponding to the designated time.

  FIG. 14 is a block diagram illustrating a configuration example (fourth embodiment) in which a storage unit is added to the analysis apparatus with respect to the second embodiment illustrated in FIG. 11. In the fourth embodiment, the second embodiment is illustrated in FIG. The same components as those in FIG.

  Since the operations of the storage unit 600 and the display unit 630 in the fourth embodiment are the same as the operations of the storage unit 500 and the display unit 530 in the third embodiment, description thereof will be omitted.

  The storage units 500 and 600 may store the biological information data BD stored in the memory 310. Accordingly, when a new analysis function is added to the sleep state analysis unit 320 or the exercise state analysis unit 420, the past biological state analysis is also performed by using the biological information data BD stored in the memory 310. it can. Further, the storage unit may not be added to the analysis device but may be prepared separately from the analysis device. As a result, a large amount of data can be stored.

  In the above-described embodiments (first embodiment to fourth embodiment), three sensors of the body temperature sensor, the acceleration sensor, and the electrocardiogram signal sensor are used, but other sensors may be used in addition. . For example, an oxygen saturation sensor for measuring arterial blood oxygen saturation may be added and used to analyze the biological state of the subject.

  Further, a part of the analysis data calculated by the sleep state analysis unit 320 and the exercise state analysis unit 420, for example, the speed (movement speed), the amount of exercise, and the like may be calculated by the biological information detection apparatus main body. As a result, more detailed biological information can be acquired from the biological information detection apparatus main body alone.

  Furthermore, the number of biological information detection apparatus main bodies to be attached to the subject is not limited to one, but may be plural as shown in FIG. By acquiring biological information from multiple locations on the subject's body, it becomes possible to detect symptoms that are difficult to detect with only biological information from one location (for example, early detection of cerebral infarction or myocardial infarction, etc.) It becomes possible to grasp the health condition of the subject and physical abnormality more precisely. When using a plurality of biological information detection device main bodies, for example, a unique number is assigned to the biological information detection device main body so that it can be determined from which biological information detection device main body the acquired biological information is obtained. The unique number is added to the biological information signal transmitted by the biological information detecting device.

DESCRIPTION OF SYMBOLS 1 Biological information detection apparatus 10 Biological information detection apparatus main body 20 Mounting base 30,40,50,60 Analysis apparatus 100 Biological information detection part 110 Body temperature sensor 120 Acceleration sensor 130 Electrocardiogram signal sensor 140 Control part 141 Data processing part 142 Mode setting part 143 Switching unit 144 Data reading unit 150, 310 Memory 160 Transmission unit 170 Charging input unit 200 Charging output unit 210 Communication unit 300 Biological information input unit 320 Sleep state analysis unit 330, 430, 530, 630 Display unit 420 Exercise state analysis unit 500 600 storage unit

Claims (7)

In a biological information management system comprising a biological information detection device that is mounted on a subject and measures biological information, and an analysis device that analyzes the biological information,
The biological information detection device includes a biological information detection device body that can be attached to a subject, and a mounting table on which the biological information detection device body is placed,
The biological information detection apparatus main body includes a biological information detection unit that detects biological information of a subject, a memory that stores biological information detected by the biological information detection unit, and a biological body detected by the biological information detection unit. A transmission unit that wirelessly transmits information and biological information stored in the memory, and a charging input unit that generates power necessary for the biological information detection device body,
The mounting table includes a charge output unit that generates power in the charge input unit, and a communication unit that receives the biological information output from the transmission unit and outputs the received biological information to the outside.
It is possible to select whether or not the transmission unit outputs the biological information detected by the biological information detection unit,
When the charging input unit generates power by the charging output unit, the biometric information stored in the memory is output from the transmitting unit, and the output biometric information is received by the communication unit, and received. Outputting the biometric information from the communication unit to the outside,
The biometric information management system, wherein the analysis device inputs biometric information output from the transmission unit and the communication unit, and analyzes a sleep state of the subject from the biometric information. In a biological information management system comprising a biological information detection device that is mounted on a subject and measures biological information, and an analysis device that analyzes the biological information,
The biological information detection device includes a biological information detection device body that can be attached to a subject, and a mounting table on which the biological information detection device body is placed,
The biological information detection apparatus main body includes a biological information detection unit that detects biological information of a subject, a memory that stores biological information detected by the biological information detection unit, and a biological body detected by the biological information detection unit. A transmission unit that wirelessly transmits information and biological information stored in the memory, and a charging input unit that generates power necessary for the biological information detection device body,
The mounting table includes a charge output unit that generates power in the charge input unit, and a communication unit that receives the biological information output from the transmission unit and outputs the received biological information to the outside.
It is possible to select whether or not the transmission unit outputs the biological information detected by the biological information detection unit,
When the charging input unit generates power by the charging output unit, the biometric information stored in the memory is output from the transmitting unit, and the output biometric information is received by the communication unit, and received. Outputting the biometric information from the communication unit to the outside,
The biometric information management system, wherein the analysis device inputs biometric information output from the transmission unit and the communication unit, and analyzes an exercise state of the subject from the biometric information. In addition to the biological information during sleep of the subject, the biological information detection unit also detects at least any biological information before and after sleeping,
The biological information management system according to claim 1, wherein the analysis device analyzes the sleep state of the subject using at least one of the biological information before and after the sleep in addition to the biological information during sleep. . In addition to the biological information during the exercise of the subject, the biological information detection unit also detects at least any biological information before and after the exercise,
The biological information management system according to claim 2, wherein the analysis device analyzes the exercise state of the subject using at least one of the biological information before and after the exercise in addition to the biological information during the exercise. . The biological information management system according to claim 1, wherein the analysis device includes a display unit that displays the analysis result. The biological information management system according to claim 1, wherein the analysis device includes a storage unit that stores the analysis result. The biological information detection unit includes at least a body temperature sensor that detects a body temperature of the subject, an acceleration sensor that detects a posture of the subject, and an electrocardiogram signal sensor that detects an electrocardiogram signal of the subject. Item 7. The biological information management system according to any one of Items 1 to 6.