WO2019008978A1 - 情報提供方法、情報処理システム、情報端末、及び情報処理方法 - Google Patents
情報提供方法、情報処理システム、情報端末、及び情報処理方法 Download PDFInfo
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- WO2019008978A1 WO2019008978A1 PCT/JP2018/021452 JP2018021452W WO2019008978A1 WO 2019008978 A1 WO2019008978 A1 WO 2019008978A1 JP 2018021452 W JP2018021452 W JP 2018021452W WO 2019008978 A1 WO2019008978 A1 WO 2019008978A1
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- Prior art keywords
- information
- user
- benzyl alcohol
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- stress
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Definitions
- the present disclosure relates to an information providing method and the like.
- Patent Document 1 discloses a watch-type conversation assistance device attached with a perspiration sensor, a pulse sensor, and a blood flow sensor.
- This wristwatch-type conversation assistance device measures the emotion of the user wearing the wristwatch-type conversation assistance device using a perspiration sensor, a pulse sensor, and a blood flow sensor, and the result of information processing based on the measurement result is indicated by characters indicate. For example, when the user is angry as a result of measurement by the perspiration sensor, the pulse sensor, and the blood flow sensor, the wristwatch-type conversation assistance device displays “angerous”. In addition, for example, when the user is angry, a message of “slow conversation” is displayed.
- Patent Document 1 discloses a system for displaying a measurement result by a perspiration sensor and a blood flow sensor, which are attached to the inside of a shoe, with characters and the like on a wristwatch-type acquisition display device. Similarly to the above, when the user is angry as a result of the measurement by the perspiration sensor and the blood flow sensor, it is displayed as "angerous".
- Patent Document 1 discloses a wristwatch-type conversation assistance device attached with a blood sensor having one or more painless needles. The blood is collected to measure the substance in the blood, and the change in emotion of the user is measured. Then, the same process as described above is performed.
- Patent Document 1 discloses a glasses-type conversation assistance device in which a small camera and an eye camera are embedded.
- the miniature camera measures blinks and facial expressions.
- the eye camera also measures eye movement and blinks.
- the glasses-type conversation assistance device includes the results of information processing based on the measurement of blinks and facial expressions by the small camera and the measurement of eye movement and blinks by the eye camera. Display on the transmissive display inside the lens as text.
- An aspect of the invention according to the present disclosure is an information providing method in an information processing system,
- the biogas information indicating the concentration of benzyl alcohol of the user acquired by the sensor for detecting benzyl alcohol (Benzyl alcohol) released from the skin surface of the user is dealt with each timing of the plurality of timings at a plurality of timings.
- Embodiment 1 of this indication it is a block diagram which shows an example of a structure of the sensor which measures biometric data. It is a figure which illustrates operation
- FIG. 1 It is a figure which shows an example of a data structure of the table which memory memorize
- the present inventors are studying a method for objectively grasping an invisible stress.
- Depression is divided into three categories according to the cause: (1) “physically,” (2) “intrinsic,” and (3) “psychological.”
- Physical depression is depression that is attributed to the nature or drug of the brain or a body organ.
- An “endogenous” depression is a depression that is attributable to the genetic level, or a depression that is caused to cause a mental disorder in the brain.
- Psychogenic depression is depression caused by experiencing psychological stress. It is said that it is difficult to divide these three strictly, and there is a high possibility that the three interact with each other (the Japanese government's Cabinet Office “White Paper on National Life 2008 Edition” Chapter 1, Section 3, "2. Stress society and modern pathology "http: // www5. cao. go.
- the present inventors have developed a tool for objectively grasping the degree of human stress accumulation before onset of a psychiatric disorder such as depression, and researched on preventing the psychiatric disorder such as depression. doing.
- Cortisol is a hormone whose secretion is increased when it is subjected to excessive stress. Therefore, by examining the concentration of cortisol, the amount of stress at the time of examination can be grasped.
- the concentration of cortisol can be measured by saliva collection, blood collection or urinalysis. For example, by accumulating urine for 24 hours, it is possible to measure the cumulative secretion of cortisol per day, and it is also possible to evaluate the amount of stress per day.
- the concentration of cortisol is effective in evaluating stress, it is not realistic to continuously collect saliva, collect blood or perform a urine test, so grasp the time change of the concentration of cortisol. It is difficult. For this reason, it is also difficult to grasp the time change of the subject's stress.
- the present inventors hypothesized that there is a biogas released from the skin surface of a person when physical and mental stress is applied as an index for evaluating stress instead of the above-mentioned cortisol.
- the present inventors conducted an experiment to identify a biogas that is correlated with stress.
- the present inventors cause each of the 30 subjects to execute a task for feeling stress, and in a certain period before and after executing the task, the saliva from each subject at predetermined time intervals. Were collected and biogas was collected from the sides and hands of each subject. Then, the present inventors graphed temporal change of cortisol concentration from saliva collected above, and identified a subject in which temporal change of cortisol concentration was significantly observed. The subject identified here was identified as feeling stress in the above task.
- the present inventors selected a plurality of biogases likely to be correlated with stress by analyzing about 300 types of biogases collected from the armpits of a subject who felt stress in the above experiment.
- the selected biogas it is confirmed that benzyl alcohol is released from the skin when stress is felt by examining the amount of biogas released during and after performing the task.
- the procedure of the experiment to identify the above benzyl alcohol is described in detail below.
- This psychology laboratory has an isolated narrow room inside. This isolated room has only a glazed window where the inside can be viewed from the outside. Also, this isolated room is designed to apply psychological stress to the subject when performing a stress task.
- the present inventors guided 30 Japanese women in their 20s and 40s one by one into the above-mentioned psychology laboratory. Then, the subject's saliva was collected in the psychological laboratory. Ten minutes after the subject's saliva was collected, the subject worked on computational tasks and stress tasks such as speech for 20 minutes. Immediately after the end of the stress task, the subject's saliva was collected for a total of 4 times, once every 10 minutes, for 30 minutes. With respect to the saliva collected here, the concentration of cortisol in each saliva was measured using a saliva cortisol assay kit (Salimetrics).
- biological gas is collected from the subject's hand and armpit at 20 minutes during the stress task and 20 minutes after 10-30 minutes after completing the stress task.
- the Collection of the biogas from the hand was performed by covering the gas sampling bag with the hand of the subject, fixing the wrist with a rubber band, and injecting an adsorbent that adsorbs the biogas into the bag. .
- Collection of biogas from the underarm was performed by sandwiching the adsorbent in the subject's armpit. The adsorbent placed under the armpit was wrapped in cotton, and was fixed with a wrapping so that the position of the adsorbent did not shift under the armpit.
- the reason for using the hand and the side where the biogas is collected is because the sweat glands are concentrated on the hand and the side.
- the site for collecting the biological gas is not limited to the hand and the side described above, and may be any site on the surface of the skin.
- the subject's saliva and biological gas were each treated in the same procedure as the day on which the stress task was performed except that the relaxation task was performed instead of the stress task on the day different from the day on which the stress task was performed. It was collected.
- the relaxation task here was a task for the subject to just watch the natural scenery DVD.
- FIG. 1 is a graph showing temporal changes in concentrations of cortisol in the saliva of the above-mentioned subject before, after and after a stress task.
- the vertical axis shows the concentration of cortisol ( ⁇ g / dL), and the horizontal axis shows the time (minutes) since the start of the stress task or relaxation task.
- the upper side of the vertical axis in FIG. 1 indicates that the concentration of cortisol is higher, and as described above, the higher the concentration of cortisol indicates that the subject feels stress.
- the shaded portion (0 to 20 minutes on the horizontal axis) in the graph of FIG. 1 is a period during which a stress task or a relaxation task is performed. As a known fact, it is known that the concentration of cortisol in saliva increases in about 15 minutes after the subject feels stress.
- the present inventors examined the respective biogas released from the side of each subject (subject No. 1 to 20) during and after the stress task and during and after the relaxation task.
- the peak area of mass spectrum is calculated, the peak area of each biological gas is compared between during and after the stress task and during and after the relaxation task, and more than 300 biological gas components are selected as candidates related to stress. Materials were selected.
- benzyl alcohol has a clear correlation with stress.
- the chemical formula of benzyl alcohol is as follows.
- FIG. 4 shows that the biogas released from the side of each subject (subject No. 1 to 20) was analyzed by GC / MS during the stress task, after the stress task, during the relaxation task and after the relaxation task It is a list of peak areas of benzyl alcohol in the mass spectrum obtained from time to time. The larger the value of the peak area in the mass spectrum shown in FIG. 4, the larger the amount of benzyl alcohol released from the armpit.
- FIG. 5 is a bar graph showing the mean value and the error range of the peak area of benzyl alcohol obtained from the list of FIG. 4.
- benzyl alcohol can be an index for objectively evaluating the amount of stress in a subject.
- the present inventors must measure the biological gas derived from stress and make it possible to grasp stress objectively, which should lead to the prevention of mental diseases such as depression, which is the final purpose.
- Each aspect of the invention according to the present disclosure relates to that.
- One embodiment of the present invention according to the present disclosure is An information providing method in an information processing system
- the biogas information indicating the concentration of benzyl alcohol of the user acquired by the sensor for detecting benzyl alcohol (Benzyl alcohol) released from the skin surface of the user is dealt with each timing of the plurality of timings at a plurality of timings.
- Patent Document 1 uses information such as sweating, pulse, blood flow, blinks and facial expressions. However, the values indicated by these pieces of information change when people climb stairs. Therefore, these pieces of information are not unrelated to stress, but are also changed by factors unrelated to stress. Therefore, it is not always sufficient as a judgment material for judging the amount of stress objectively, and there is a possibility of an erroneous judgment.
- the amount of stress is objectively determined using a biogas whose relationship with the stress of benzyl alcohol is estimated. Therefore, it is possible to objectively grasp the cumulative degree of stress regardless of the subjective sense of the person.
- a time zone in which the concentration of benzyl alcohol of the user exceeds the upper limit of the normal range is determined, and information indicating the determined time zone is output to the information terminal of the user.
- the person can objectively recognize the condition of the person's own stress, so it can be expected to prevent mental diseases such as depression.
- the upper limit of the normal range of the concentration of the benzyl alcohol per unit period is The information may be set as individual information for the user based on the biological gas information acquired in a pre-set period.
- the user's own data is used as a reference value.
- the amount of release of benzyl alcohol, which is a biogas, is affected by age, food, weight, etc., and there are individual differences, so it is preferable to use the user's own data to make an accurate judgment.
- Patent Document 1 does not disclose at all how to have reference information.
- the degree of stress is determined using the user's own data as a reference value. Therefore, it is possible to make judgments suitable for each person.
- the upper limit of the normal range of the concentration of the benzyl alcohol per unit period is The information may be previously stored in the memory as information commonly used by a plurality of users including the user.
- the reference value is commonly used by a plurality of users, it is not necessary to generate and manage the reference value for each user.
- the time zone indicated by the information in the information terminal is: It may be superimposed and displayed on the schedule information of the user.
- the user can easily confirm the causal relationship between stress and his / her behavior by collating the schedule information with the time zone in which stress is high.
- the senor for detecting the benzyl alcohol is It may be incorporated in the device worn by the user.
- the sensor for detecting benzyl alcohol since the sensor for detecting benzyl alcohol is built in the device worn by the user, for example, an object worn by the user in daily life can have the function of the sensor. As a result, it is possible to reduce the burden on the user of mounting the sensor.
- the time information corresponding to each time of the plurality of timings may correspond to each time when the biological gas is acquired by the sensor.
- “corresponding to each time when the biological gas is acquired” may indicate a time when the sensor measures biological gas information, or a processing device such as a server may be a sensor via a network. It may indicate the time when the biological gas information was acquired from
- An information processing system including a server device and an information terminal,
- the server device is The biogas information indicating the concentration of benzyl alcohol of the user acquired by the sensor for detecting benzyl alcohol (Benzyl alcohol) released from the skin surface of the user is dealt with each timing of the plurality of timings at a plurality of timings.
- an information terminal may be used in the above-described information processing system.
- An information processing method is an information processing method using a computer, Acquiring biogas information indicating the concentration of benzyl alcohol of the user acquired by a sensor that detects benzyl alcohol (Benzyl alcohol) released from the skin surface of the user; Reading out information representing the upper limit of the normal range from a memory storing information representing the upper limit of the normal range of the benzyl alcohol per unit period; Based on the acquired biogas information, when it is determined that the concentration of benzyl alcohol of the user exceeds the upper limit of the normal range, information on the effect that the stress of the user exceeds the normal range is displayed on the display Output to When it is determined that the concentration of benzyl alcohol of the user is below the upper limit of the normal range based on the acquired biological gas information, information indicating that the stress of the user is within the normal range is displayed on the display Output for
- the concentration of benzyl alcohol exceeds the upper limit of the normal range
- information that the stress of the user exceeds the normal range is displayed on the display.
- the concentration of benzyl alcohol is below the upper limit of the normal range
- information indicating that the stress of the user is within the normal range is displayed on the display. Therefore, it is possible to inform the user of an objective judgment result as to whether or not the user is currently under stress.
- Embodiment 1 (Expected data) 6A and 6B are graphs showing predicted data of biological data handled in the first embodiment of the present disclosure.
- the vertical axis indicates biogas concentration (an example of biogas information), and the horizontal axis indicates time.
- the predicted data does not indicate the measured value of the actually measured biological data, but is data obtained by predicting the biological data.
- the biological data is biological data measured by a sensor attached to the user as described later.
- the biological data indicates the measurement value of the concentration (biological gas concentration) of the biological gas to be measured among the biological gas released from the skin surface of the user.
- the biological gas to be measured is benzyl alcohol.
- the unit of biogas concentration is, for example, ⁇ g / dL.
- FIG. 6A shows temporal transition of biometric data of the user when there is no stress
- FIG. 6B shows temporal transition of biometric data of the user when there is stress.
- the biological data in the absence of stress has a biogas concentration within the normal range.
- the frequency at which the biological gas concentration exceeds the upper limit DH of the normal range is high.
- the present disclosure aims to prevent mental diseases such as depression and the like by determining a time zone in which the concentration of biological gas exceeds the upper limit DH and notifying the user of information indicating the determined time zone.
- FIG. 7 is a block diagram showing an example of the configuration of the sensor 3 that measures biological data in the first embodiment of the present disclosure.
- the senor 3 for example, a sensor utilizing the technology of field asymmetric ion mobility spectrometry (FAIMS) is adopted.
- Field asymmetric ion mobility spectrometers are used to selectively separate at least one substance from a mixture containing two or more substances.
- the sensor 3 includes a detection unit 33, a control unit 31, and a communication unit 34.
- the detection unit 33 includes an ionization device 301, a filter 302, a detector 303, a power supply 304, and a high frequency amplifier 305.
- arrow lines indicate the flow of electrical signals
- lines connecting the ionization device 301, the filter 302, and the detector 303 indicate the flow of biological gas.
- a power supply 304 and a high frequency amplifier 305 are used to drive the ionization device 301 and the filter 302, respectively.
- the desired biogas benzyl alcohol in the present disclosure
- the filter 302 the amount of ions passed through the filter 302 is detected by the detector 303.
- the acquired information is output via the communication unit 34.
- the drive of the sensor 3 is controlled by the controller 31.
- FIG. 8 is a diagram for explaining the operation of the sensor 3 shown in FIG. 7 in more detail.
- the mixture supplied to the ionization device 301 is biogas released from the skin surface of the user.
- the ionization device 301 may include an inlet port for taking in the biogas released from the skin surface of the user.
- an adsorbent that adsorbs a biological gas may be provided at the inlet.
- a heater may be provided to desorb the biological gas adsorbed to the adsorbent from the adsorbent.
- the mixture is assumed to contain three types of gases 202-204.
- the gases 202-204 are ionized using the ionization device 301.
- the ionization device 301 includes a corona discharge source, a radiation source, and the like to ionize the gases 202 to 204.
- the ionized gases 202-204 are supplied to a filter 302 located adjacent to the ionization device 301.
- the corona discharge source and the radiation source which constitute the ionization device 301 are driven by the voltage supplied from the power supply 304.
- the filter 302 includes a flat first electrode 201a and a flat second electrode 201b disposed in parallel to each other.
- the first electrode 201a is grounded.
- the second electrode 201 b is connected to the high frequency amplifier 305.
- the high frequency amplifier 305 includes an AC voltage source 205a that generates an asymmetric AC voltage, and a variable voltage source 205b that generates a compensation voltage CV that is a DC voltage.
- the alternating voltage source 205a generates an asymmetrical alternating voltage and applies it to the second electrode 201b.
- One end of the variable voltage source 205b is connected to the second electrode 201b, and the other end is grounded.
- the asymmetrical AC voltage generated by the AC voltage source 205a is superimposed on the compensation voltage CV and supplied to the second electrode 201b.
- Three types of ionized gases 202 to 204 are supplied between the first electrode 201a and the second electrode 201b.
- the three gases 202 to 204 are affected by the electric field generated between the first electrode 201a and the second electrode 201b.
- FIG. 9 is a graph showing the relationship between the strength of an electric field and the ratio of ion mobility, in which the vertical axis shows the ratio of ion mobility, and the horizontal axis shows the strength of the electric field (V / cm).
- ⁇ is a coefficient determined by the type of ion.
- the ratio of ion mobility indicates the ratio of mobility in high electric field to mobility in the low electric field limit.
- the ionized gas with coefficient ⁇ > 0 moves more actively as the strength of the electric field increases. Ions having a mass-to-charge ratio of less than 300 exhibit this behavior.
- the ionized gas with coefficient ⁇ of approximately 0 moves more actively as the strength of the electric field increases, but the mobility decreases as the strength of the electric field is further increased.
- the ionized gas with a negative coefficient ⁇ decreases in mobility as the strength of the electric field increases. Ions having a mass-to-charge ratio of 300 or more exhibit this behavior.
- the filter 302 Due to such differences in mobility characteristics, three types of gases 202-204 travel inside the filter 302 in different directions, as shown in FIG. In the example of FIG. 8, only the gas 203 is exhausted from the filter 302, while the gas 202 is trapped on the surface of the first electrode 201a, and the gas 204 is trapped on the surface of the second electrode 201b. In this way, only the gas 203 is selectively separated from the three gases 202-204 and exhausted from the filter 302. That is, the sensor 3 can discharge the desired gas from the filter 302 by appropriately setting the strength of the electric field. The strength of the electric field is determined by the voltage value of the compensation voltage CV and the waveform of the asymmetric alternating voltage generated by the alternating voltage source 205a.
- the sensor 3 sets the voltage value of the compensation voltage CV and the waveform of the asymmetrical AC voltage to voltage values and waveforms determined in advance according to the type of biological gas to be measured (the present disclosure is benzyl alcohol).
- the biological gas to be measured can be discharged from the filter 302.
- Detector 303 is positioned adjacent to filter 302. That is, the filter 302 is disposed between the ionization device 301 and the detector 303.
- the detector 303 includes an electrode 310 and an ammeter 311, and detects the gas 203 which has passed through the filter 302.
- the gas 203 reaching the detector 303 transfers the charge to the electrode 310.
- the value of the current flowing in proportion to the amount of charge transferred is measured by the ammeter 311. From the value of the current measured by the ammeter 311, the concentration of the gas 203 is measured.
- FIG. 10 is a diagram illustrating an example of a network configuration of the information processing system according to the first embodiment of the present disclosure.
- the information processing system provides a care service that cares for the stress of the user U1.
- This care service is provided by, for example, an insurance company or the like to which the user U1 subscribes.
- the actual operation of the care service may be performed by, for example, a manufacturer that manufactures the sensor 3 commissioned by an insurance company.
- this care service may be provided by a service provider different from the insurance company that provides the care service itself.
- the insurance company provides the user U1 with insurance services such as life insurance and medical insurance, for example. Then, for example, the insurance company lends the sensor 3 to the user U1, acquires the biometric data of the user U1, and manages the stress state of the user U1, thereby preventing the illness based on the mental disease of the user U1. In this way, the insurer will save on insurance payments. Since this care service forces the user U1 to wear the sensor 3, there is also the user U1 who feels a burden. Therefore, the insurance company can also provide an insurance plan in which the premium paid by the user U1 is discounted in return for this care service.
- insurance services such as life insurance and medical insurance, for example.
- the insurance company lends the sensor 3 to the user U1, acquires the biometric data of the user U1, and manages the stress state of the user U1, thereby preventing the illness based on the mental disease of the user U1. In this way, the insurer will save on insurance payments. Since this care service forces the user U1 to wear the sensor 3, there is also the user U1 who feels
- the information processing system includes a server 1 (an example of a server device), a user terminal 2 (an example of an information terminal), and a sensor 3.
- the server 1 and the user terminal 2 are communicably connected to each other via the network NT.
- the network NT is configured of a network including an Internet communication network, a mobile telephone communication network, and a public telephone network.
- the sensor 3 and the user terminal 2 are communicably connected via, for example, a wireless LAN of IEEE802.11b or a short distance wireless communication such as Bluetooth (registered trademark: IEEE802.15.1).
- the server 1 is configured of, for example, a cloud server including one or more computers.
- the server 1 includes a processor such as a CPU and an FPGA and a memory.
- the server 1 acquires the biological data of the user U1 measured by the sensor 3 via the user terminal 2 and the network NT, and determines whether the biological gas concentration is within the normal range.
- the user terminal 2 is configured of, for example, a portable information processing apparatus such as a smartphone and a tablet terminal.
- the user terminal 2 may be configured of a stationary computer.
- the user terminal 2 is possessed by the user U1.
- the sensor 3 is attached to, for example, an arm of the user U1, and detects the concentration of biological gas emitted from the side of the user U1.
- the sensor 3 includes, for example, a mounting belt, and the user winds the mounting belt around an arm near the side to attach the sensor 3 near the arm. Thereby, the sensor 3 can detect the biogas discharged from the side.
- the position of the arm near the side for example, the position of the arm on the elbow side from the base of the arm and the torso can be adopted.
- the sensor 3 should just be attached so that the intake port which acquires biological gas may be located in the back side of an arm in consideration of many biological gas being discharged
- the position of the arm near the side is adopted as the mounting position of the sensor 3 because it is difficult to attach the sensor 3 to the side itself.
- the sensor 3 may be attached to the side of the shirt worn by the user U1.
- the sensor 3 faces the side, so that the biological gas can be acquired more reliably.
- the shirt is an example of a device worn by the user.
- FIG. 11 is a block diagram showing an example of a detailed configuration of the information processing system shown in FIG.
- the server 1 includes a control unit 11, a memory 12, and a communication unit 13.
- the control unit 11 is configured of a processor and includes a data analysis unit 111.
- the data analysis unit 111 is realized, for example, by executing a program that causes a computer to execute the information providing method of the present disclosure stored in the memory 12 by the processor.
- a program that causes a computer to execute the information providing method of the present disclosure may be provided by downloading through a network, or may be provided by storing the information in a non-transitory computer readable medium.
- the data analysis unit 111 acquires the biological data from the communication unit 13. Then, the data analysis unit 111 reads out information indicating the upper limit DH of the normal range of the biogas concentration from the memory 12, and determines a time zone in which the biogas concentration indicated by the biodata exceeds the upper limit DH. Then, the data analysis unit 111 registers the biometric data in the biometric data table T4 (FIG. 12) stored in the memory 12 in association with the determination result.
- time zone information Information indicating the time zone (hereinafter referred to as “time zone information”) is transmitted to the user terminal 2 via the communication unit 13.
- the memory 12 stores information indicating a normal range of the biogas concentration.
- memory 1 2 stores a normal range data table T2 and a biometric data table T4 as shown in FIG.
- FIG. 12 is a view showing an example of the data configuration of a table stored in the memory 12.
- the normal range data table T2 is a table for storing the normal range of stress of the biogas concentration of one or more users who receive the care service.
- one record is assigned to one user, and the "user ID”, the "measurement date and time”, and the "normal range” are associated and stored.
- the "user ID” field stores an identifier for uniquely identifying the user who receives the care service.
- the time zone of the measurement date and time of the biometric data used to calculate the normal range is stored.
- the normal range a normal range calculated using biological data stored in the “measurement date and time” field is stored.
- the lower limit DL and the upper limit DH of the normal range are stored.
- the normal range of the user having the user ID “S00001” is calculated using the biometric data measured in the time zone from 20 o'clock to 21 o'clock on January 20, 2017.
- the normal range for each user is calculated, the stress of each user can be determined using the normal range suitable for each user, and the determination accuracy can be enhanced.
- the normal range for each user is calculated, but this is an example, and the average value of the normal range calculated for some of all users is applied as the normal range for all users. It is also good. Alternatively, the average value of the normal range of all users may be applied as the normal range of all users. In these cases, it is not necessary to store and calculate the normal range for each user, so memory consumption can be saved and processing steps can be reduced.
- the biometric data table T4 is a table for storing the biometric data acquired by the sensor 3.
- the biometric data table T4 has one record assigned to one piece of biometric data, and stores "user ID”, "day”, “time”, “concentration”, and “determination result” in association with each other. .
- the same user ID as that stored in the normal range data table T2 is stored.
- the date of measurement of the biological data is stored in the "day” field.
- a time zone in which biological data was measured is stored.
- the biological gas concentration indicated by the biological data is stored.
- the judgment result as to whether or not the biogas concentration is within the normal range is stored.
- zone which the server 1 acquired biometric data may be memorize
- the biological gas concentration "OO" measured in the time period from 10 o'clock to 11 o'clock on February 15, 2017 of the user having the user ID "S00001".
- the biometric data of are stored. Further, since the biological gas concentration was within the normal range in the first line record, “normal” is stored in the “determination result” field. On the other hand, in the second line of the record, the biological gas concentration is out of the normal range, so “abnormal” is stored in the "judgment result” field.
- biometric data table T4 biometric data of only the user with the user ID "S00001" is shown, but this is an example, and biometric data of all users who receive care services are stored in the biometric data table T4. It is done.
- the communication unit 13 includes, for example, a communication circuit that connects the server 1 to the network NT, and receives biological data measured by the sensor 3 or transmits time zone information to the user terminal 2.
- the user terminal 2 includes a control unit 21, a memory 22, a display unit 23 (an example of a display), and a communication unit 24.
- the control unit 21 is configured by a processor such as a CPU and controls the entire control of the user terminal 2.
- the memory 22 stores various data. In the present disclosure, the memory 22 stores, among other things, an application that is executed on the user terminal 2 to get the user U1 to receive the care service.
- the memory 22 also stores a user ID transmitted in association with biometric data.
- the display unit 23 is configured of, for example, a display including a touch panel, and displays various information. In the present disclosure, the display unit 23 particularly displays time zone information.
- the communication unit 24 includes a communication circuit for connecting the user terminal 2 to the network NT and causing the user terminal 2 to communicate with the sensor 3. In the present disclosure, the communication unit 24 particularly receives the biometric data transmitted from the sensor 3 and transmits the received biometric data to the server 1 in association with the user ID stored in the memory 22. Further, in the present disclosure, the communication unit 24 particularly receives time zone information transmitted from the server 1.
- the display unit 23 may not be configured by a touch panel. In this case, the user terminal 2 may include an operation unit that receives an operation from the user.
- the sensor 3 includes a control unit 31, a memory 32, a detection unit 33, and a communication unit 34.
- the control unit 31 is configured by a processor such as a CPU or a DSP, and controls the entire control of the sensor 3.
- the memory 32 temporarily stores, for example, biological data measured by the detection unit 33.
- the memory 32 stores data (for example, frequency, plus side amplitude, and minus side amplitude) required for the alternating voltage source 205a to generate an asymmetrical alternating voltage.
- the memory 32 also stores the voltage value of the compensation voltage CV.
- the communication unit 34 is configured by a communication circuit such as a wireless LAN or Bluetooth (registered trademark), and transmits biological data measured by the detection unit 33 to the user terminal 2.
- the biometric data is received by the communication unit 24 of the user terminal 2 and transmitted to the server 1 via the network NT.
- FIG. 13 is a sequence diagram showing an example of processing of the biometric information system shown in FIG. This sequence diagram is divided into an initial phase from S101 to S106 and a normal phase after S201.
- the initial phase is a phase for calculating the normal range of the user and is performed immediately after the introduction of the care service.
- the normal phase is a phase of monitoring the stress state of the user using the normal range calculated in the initial phase.
- the initial phase is executed, for example, when the user starts the application for the user terminal 2 for receiving the care service at the user terminal 2 for the first time.
- the display unit 23 of the user terminal 2 receives an input of user information (S101).
- the display unit 23 may cause the user to input the user information by displaying a registration screen for causing the user to input user information such as the user ID, the telephone number, the e-mail address, and the SNS account.
- user information such as the user ID, the telephone number, the e-mail address, and the SNS account.
- the user ID issued when the user signed an insurance contract with an insurance company may be adopted.
- the user ID may be issued to the user terminal 2 when the server 1 receives the user information in S102 described later, and issues the user ID. In this case, the user does not have to enter the user ID on the registration screen.
- control unit 21 of the user terminal 2 transmits the input user information to the server 1 using the communication unit 24 (S102).
- the transmitted user information is stored by the control unit 41 of the server 1 in a user information table (not shown) that manages user information of one or more users who receive the care service.
- the detection unit 33 of the sensor 3 measures the initial biometric data of the user (S103).
- the control unit 31 of the sensor 3 transmits the measured initial biological data to the user terminal 2 using the communication unit 34 (S104).
- the control unit 21 transmits the initial biometric data to the server 1 in association with the user ID (S105).
- the data analysis unit 111 of the server 1 sets a normal range (S106).
- the set normal range is stored in the normal range data table T2 by the data analysis unit 111 of the server 1 in association with the user ID.
- the detection unit 33 measures biological data (S201), and the control unit 31 transmits the biological data to the user terminal 2 using the communication unit 34 (S202).
- the control unit 21 associates the biometric data with the user ID and transmits it to the server 1 using the communication unit 24 (S203).
- the data analysis unit 111 compares the biological data with the normal range, and accumulates the determination result (S204).
- the determination result is accumulated in the "determination result" field of the record of the corresponding user in the normal range data table T2 using the user ID as a key.
- the data analysis unit 111 transmits time zone information in which the biological gas concentration exceeds the upper limit of the normal range to the user terminal 2 using the communication unit 13 when the defined period has elapsed (see FIG. S205).
- the control unit 21 displays the time zone information on the display unit 23 (S206).
- FIG. 14 is a flowchart showing details of the process of the initial phase according to the first embodiment of the present disclosure. This flowchart is performed by the server 1.
- the communication unit 13 receives the user information transmitted from the user terminal 2 (S301).
- the communication unit 13 receives the initial biometric data transmitted from the user terminal 2 (S30) 2).
- the data analysis unit 111 returns the process to S302.
- the data analysis unit 111 advances the process to S304.
- the number of received initial biometric data reaches a predetermined number sufficient to calculate a normal range, or the data analysis unit 111 starts measuring the initial biometric data, a predetermined measurement period has elapsed. Acquisition of initial biometric data may be completed when it has elapsed.
- one hour, two hours, three hours,..., One day, two days, three days, etc. are adopted as the measurement period of the initial phase, although it depends on the measurement interval of biological data. .
- the measurement interval of the biological data is short, many initial biological data can be obtained in a short time, so the measurement period of the initial biological data is shortened accordingly.
- one hour is used as a measurement interval of biometric data
- half day, one day, two days, three days, etc. are adopted as a measurement period of initial biometric data, for example.
- one minute or one second is adopted, for example, ten minutes, twenty minutes, one hour, two hours, three hours or the like can be adopted as the measurement period of the initial biological data.
- these figures are only examples and may be changed as appropriate.
- the measurement period of the initial biometric data corresponds to an example of the pre-set period.
- the data analysis unit 111 sets a normal range using the acquired initial biometric data (S304). For example, it is assumed that initial biometric data as shown in FIG. 6A is obtained. In this case, the data analysis unit 111 analyzes the obtained initial biological data, and extracts the upper limit peak and the lower limit peak of the biological gas concentration. Then, the data analysis unit 111 may calculate a value obtained by adding a predetermined margin to the upper limit peak as the upper limit DH, and calculate a value obtained by subtracting the predetermined margin from the lower limit peak as the lower limit DL.
- the data analysis unit 111 calculates a value obtained by adding a predetermined margin to the average value of the upper peaks as the upper limit DH, and calculates a value obtained by subtracting the predetermined margin from the average value of the lower peaks as the lower limit DL. May be Thus, the normal range for each user is set.
- FIG. 15 is a flowchart showing the details of the process of the normal phase according to the first embodiment of the present disclosure.
- the flowchart of FIG. 15 is periodically executed in the server 1 at intervals of measurement of biological data by the sensor 3.
- the communication unit 13 receives biometric data from the user terminal 2 (S401).
- the data analysis unit 111 compares the biological gas concentration indicated by the biological data with the normal range of the corresponding user to judge whether the stress state is normal or abnormal, and the judgment result is the biological data table T4. (S402).
- the data analysis unit 111 may store the determination result in the biological data table T4 in association with the user ID, the measurement date and time, and the biological gas concentration.
- the biometric data table T4 of FIG. 12 is referred to. In the first line of the record, "2017.2.15" is described in the "day” field, and "10: 00-11: 00" is described in the "time” field. This is because the measurement interval of the biometric data is set to one hour, and this biometric data is measured at around 10 o'clock on February 15, 2017.
- benzyl alcohol is adopted as a biological gas to be measured. Benzyl alcohol is positively correlated with the level of stress. Therefore, the data analysis unit 111 may determine that the stress state is abnormal if the biogas concentration is larger than the upper limit DH of the normal range, and determine that the stress state is normal if the biogas concentration is less than or equal to the upper limit DH.
- the data analysis unit 111 determines YES in S403 when it becomes “0:00”, and the living body for one day acquired on the previous day is obtained. Data may be handled as biometric data to be processed.
- the data analysis unit 111 transmits time zone information to the user terminal 2 using the communication unit 13 (S404).
- the data analysis unit 111 may transmit the data indicating the temporal transition of the biological gas concentration acquired in the defined period and the time zone out of the normal range in the time zone information.
- a predetermined time for example, seven o'clock
- the process returns to S401.
- FIG. 16 is a diagram showing an example of the display screen G1 displayed on the user terminal 2 as time zone information.
- the display screen G1 includes a graph G11 and a message display field G12.
- the graph G11 shows temporal transition of the degree of stress in biological data acquired in a prescribed period (here, on the 1st of February 19).
- the vertical axis indicates the degree of stress
- the horizontal axis indicates time.
- the degree of stress corresponds to the concentration of biogas.
- triangular markers are displayed at locations where the degree of stress exceeds the upper limit of the normal range.
- the user is shown a time zone in which the biogas concentration exceeds the upper limit of the normal range.
- the user can reflect on his / her life in the specified period and can confirm the cause (stressor) of increased stress.
- the message display field G12 displays a message for notifying the user that the triangular marker is a time zone in which the degree of stress is high.
- the schedule information of the corresponding user may be displayed on the display screen G1 shown in FIG.
- the server 1 may be provided with a database for managing the schedule information of the user.
- the database for managing the schedule information stores, for example, information such as "user ID”, "schedule", and "date and time” in association with each other.
- “Plan” is a user's action plan (for example, “meeting” or the like), and is input to the user via the user terminal 2, for example.
- the "date and time” is a scheduled date and time when the action schedule described in "schedule" is performed, and is input by the user via the user terminal 2.
- the server 1 When transmitting the time zone information, the server 1 transmits the time slot information including the schedule information of the corresponding user in the prescribed period to the user terminal 2.
- the user terminal 2 may generate the display screen G1 using this schedule information.
- a display mode of the schedule information a mode can be adopted in which the schedule information of the user is displayed on the graph G11 in association with the time zone.
- a mode may be adopted in which the schedule of the user is displayed in association with the time indicated by the graph G11. This allows the user to easily confirm the causal relationship between stress and his / her behavior.
- the amount of stress is objectively determined using a biogas whose relationship with the stress of benzyl alcohol is estimated. Therefore, it is possible to objectively grasp the cumulative degree of stress regardless of the subjective sense of the person.
- the user by displaying a time zone exceeding the upper limit of the normal range on the user terminal 2, for example, looking back at one day, the user objectively measures how much stress is felt on that day. I can understand. Moreover, in the first embodiment, it is possible to find out the stressor of the user by using as a hint an event that has occurred to the user in a time zone exceeding the upper limit of the normal range.
- FIG. 17 is a sequence diagram showing processing of the information processing system according to the second embodiment of the present disclosure.
- S501, S502, and S503 are the same as S101, S103, and S104 of FIG. S504 is the same as S106 of FIG. 13 except that the processing subject is not the server 1 but the user terminal 2.
- Steps S601 to S604 correspond to the normal phase.
- S601 and S602 are the same as S201 and S202 of FIG.
- S603 is the same as S204 of FIG. 13 except that the processing subject is not the server 1 but the user terminal 2.
- control unit 21 of the user terminal 2 causes the display unit 23 to display information that the stress of the user is out of the normal range.
- the control unit 21 of the user terminal 2 causes the display unit 23 to display information indicating that the stress of the user is within the normal range.
- FIG. 18 is a flowchart showing details of the process of the normal phase according to the second embodiment of the present disclosure. Note that this flowchart is executed by the user terminal 2.
- the communication unit 24 receives biological data from the sensor 3 (S701).
- the control unit 21 compares the biological gas concentration indicated by the biological data with the normal range of the corresponding user to determine whether the stress state is normal or abnormal, and the determination result is stored in the biological data table T4. It accumulates (S702).
- the control unit 21 causes the display unit 23 to display information that the degree of stress (biological gas concentration) has deviated from the normal range (S705).
- the information that the degree of stress has deviated from the normal range for example, a message such as “stress is high” may be adopted.
- the determination result in S703 is not abnormal, that is, if it is normal (NO in S703), information that the stress level (biological gas concentration) is within the normal range is displayed on the display unit 23 (S704).
- a message such as “stress is normal” can be adopted as the information indicating that the information is within the normal range.
- FIG. 19 is a diagram illustrating an example of a sensor 3 according to a modification of the present disclosure.
- a mounting portion 3A to be mounted on a user and a main body portion 3B are separately configured.
- the mounting unit 3A is configured of a mounting band that can be removed from an arm in the vicinity of the user.
- the mounting unit 3A is attached with an adsorbent that adsorbs a biological gas.
- the mounting portion 3A is also configured to be detachable from the main body portion 3B.
- the main unit 3B includes the detection unit 33, the control unit 31, and the communication unit 34 shown in FIG.
- the main body portion 3B desorbs the biological gas from the adsorbent by, for example, heating the adsorbent with a heater, analyzes the biological gas, and measures the biological gas to be measured (here, , Benzyl alcohol), and measure the concentration of biogas. Then, the main unit 3B transmits biological data including the measured biological gas concentration to the user terminal 2.
- the mounting portion 3A is made compact, the burden on the user can be reduced.
- the user terminal 2 may be configured by a computer used by a doctor who examines the user.
- the doctor may attach the sensor 3 to the user, cause the user terminal 2 to acquire biometric data, and cause the user terminal 2 to determine the stress of the user.
- the doctor may cause the user terminal 2 to determine the stress of the user by causing the user terminal 2 to acquire the biological data measured by the sensor 3 in advance for a prescribed period (for example, 1, 2 or 3 days) .
- the user is instructed by the doctor to wear the sensor 3 in advance.
- the sensor 3 stores the biological data measured in the specified period in the memory 32 in association with the measurement time.
- the memory 32 is a memory that can be attached to and detached from the sensor 3.
- the user brings the memory 32 to the hospital at the hospital visit.
- the doctor connects the memory 32 to the user terminal 2 and causes the user terminal 2 to acquire the biometric data acquired within the prescribed period. Then, if the biological gas concentration indicated by the acquired biological data exceeds the upper limit of the normal range, the user terminal 2 causes the display unit 23 to display information indicating that fact. On the other hand, if the biological gas concentration indicated by the acquired biological data is less than or equal to the upper limit of the normal range, the user terminal 2 causes the display unit 23 to display information indicating that fact.
- this modification it is possible to provide the doctor who examines the condition of the visiting patient with useful data for preventing mental illness.
- this modification may be applied to a regular medical checkup.
- the present disclosure since prevention of a mental disease of a user can be expected, the present disclosure is useful in an information processing system that manages stress of the user.
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Abstract
Description
ユーザの皮膚表面から放出されるベンジルアルコール(Benzyl alcohol)を検出するセンサにて取得された前記ユーザのベンジルアルコールの濃度を示す生体ガス情報を複数のタイミングで、前記複数のタイミングの各時刻に対応する時間情報と共にネットワークを介して取得し、
単位期間当たりの前記ベンジルアルコールの正常範囲の上限を表す情報を記憶するメモリから前記正常範囲の上限を表す情報を読み出し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正
常範囲の上限を超える時間帯を判断し、
前記判断された時間帯を示す情報を前記ユーザの情報端末に出力し、
前記情報端末において前記情報が示した時間帯が表示される、ものである。
まず、本開示に係る一態様の着眼点を説明する。
cao.go.jp/seikatsu/whitepaper/h20/10_pdf/01_honpen/pdf/08sh_0103_03.pdf)。妊婦について考えると、上記の(1)~(3)のすべての原因を満たしやすい環境下にあると言える。妊娠期間は、薬が飲めず、運動にも制約があるため、ストレスを解消しにくい。そのため、妊婦は、鬱病などの精神疾患を発症する可能性がある。
ストレスがかかったときに、人の皮膚表面から放出される生体ガスが存在すると仮説を置いた。その仮説を実験によって証明するため、本発明者らはストレスと相関関係がみられる生体ガスを特定する実験を行った。
ールの濃度が高いほど被験者がストレスを感じていることを示す。図1のグラフ中の網掛けを付した部分(横軸の0分~20分)がストレスタスクまたはリラックスタスクが行われた期間である。なお、公知の事実として、被験者がストレスを感じてから15分程度で唾液中のコルチゾールの濃度が高まることが知られている。
Institute of Standards and Technology)データベースと比較することで、ベンジルアルコールが特定された。図2は、生体ガス中のベンジルアルコール(Benzyl alcohol)のマススペクトルデータであり、図3は、NISTデータベースのBenzyl alcoholのマススペクトルデータである。図2および図3におけるマススペクトルを対比すると、ほぼ同一の質量電荷(m/z)において同様のスペクトルピークが観察された。このようにしてベンジルアルコールが生体ガスとして含まれることが特定された。
情報処理システムにおける情報提供方法であって、
ユーザの皮膚表面から放出されるベンジルアルコール(Benzyl alcohol)を検出するセンサにて取得された前記ユーザのベンジルアルコールの濃度を示す生体ガス情報を複数のタイミングで、前記複数のタイミングの各時刻に対応する時間情報と共にネットワークを介して取得し、
単位期間当たりの前記ベンジルアルコールの正常範囲の上限を表す情報を記憶するメモリから前記正常範囲の上限を表す情報を読み出し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正常範囲の上限を超える時間帯を判断し、
前記判断された時間帯を示す情報を前記ユーザの情報端末に出力し、
前記情報端末において前記情報が示した時間帯が表示される、ものである。
事前の設定期間において取得された前記生体ガス情報に基づき前記ユーザに個別の情報として設定されてもよい。
前記ユーザを含む複数のユーザに共通して使用される情報として前記メモリに予め記憶されていてもよい。
前記ユーザのスケジュール情報に重畳されて表示されていてもよい。
前記ユーザに装着されるデバイスに内蔵されていてもよい。
サーバ装置と情報端末とを含む情報処理システムであって、
前記サーバ装置は、
ユーザの皮膚表面から放出されるベンジルアルコール(Benzyl alcohol)を検出するセンサにて取得された前記ユーザのベンジルアルコールの濃度を示す生体ガス情報を複数のタイミングで、前記複数のタイミングの各時刻に対応する時間情報と共にネットワークを介して取得し、
単位期間当たりの前記ベンジルアルコールの正常範囲の上限を表す情報を記憶するメモリから前記正常範囲の上限を表す情報を読み出し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正常範囲の上限を超える時間帯を判断し、
前記判断された時間帯を示す情報を前記情報端末に出力し、
前記情報端末は、
前記判断された時間帯を示す情報を前記情報端末のディスプレイに表示する、ものである。
ユーザの皮膚表面から放出されるベンジルアルコール(Benzyl alcohol)を検出するセンサにて取得された前記ユーザのベンジルアルコールの濃度を示す生体ガス情報を取得し、
単位期間当たりの前記ベンジルアルコールの正常範囲の上限を表す情報を記憶するメモリから前記正常範囲の上限を表す情報を読み出し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正常範囲の上限を超えたと判断した場合、前記ユーザのストレスが前記正常範囲を超えている旨の情報をディスプレイに表示するために出力し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正常範囲の上限以下であると判断した場合、前記ユーザのストレスは前記正常範囲内にある旨の情報を前記ディスプレイに表示するために出力する、ものである。
(予想データ)
図6A、図6Bは、本開示の実施の形態1において取り扱われる生体データの予想データを示すグラフである。図6A、図6Bにおいて、縦軸は生体ガス濃度(生体ガス情報の一例)を示し、横軸は時間を示している。この予想データは実際に測定された生体データの測定値を示すものではなく、あくまで、生体データを予測したデータである。生体データとは、後述するようにユーザに装着されたセンサによって測定された生体データである。生体データは、ユーザの皮膚表面から放出される生体ガスのうち計測対象の生体ガスの濃度(生体ガス濃度)の計測値を示す。本開示では、計測対象となる生体ガスはベンジルアルコールである。生体ガス濃度の単位は例えばμg/dLである。
図7は、本開示の実施の形態1において、生体データを測定するセンサ3の構成の一例
を示すブロック図である。
る係数である。イオン移動度の比は、低電界極限での移動度に対する高電界中での移動度の比を示す。
図10は、本開示の実施の形態1に係る情報処理システムのネットワーク構成の一例を示す図である。情報処理システムは、ユーザU1のストレスをケアするケアサービスを提供する。このケアサービスは、例えば、ユーザU1が加入する保険会社等によって提供される。なお、ケアサービスの実際の運用は、例えば、保険会社から委託を受けたセンサ3を製造するメーカが行ってもよい。また、このケアサービスは、ケアサービス自身を提供する保険会社とは異なるサービスプロバイダによって提供されてもよい。
2は、図12に示すように、正常範囲データテーブルT2及び生体データテーブルT4を記憶する。図12は、メモリ12が記憶するテーブルのデータ構成の一例を示す図である。
図13は、図11に示す生体情報システムの処理の一例を示すシーケンス図である。このシーケンス図は、S101からS106までの初期フェーズと、S201以降の通常フェーズとに分けられる。初期フェーズは、ユーザの正常範囲を算出するためのフェーズであり、ケアサービスの導入直後に行われる。通常フェーズは、初期フェーズで算出された正常範囲を用いてユーザのストレス状態を監視するフェーズである。
2)。次に、データ解析部111は、初期生体データの取得が完了していなければ(S303でNO)、処理をS302に戻す。一方、データ解析部111は、初期生体データの取得が完了すれば(S303でYES)、処理をS304に進める。ここで、データ解析部111は、受信した初期生体データの個数が正常範囲を算出するのに十分な所定個数に到達した場合、或いは、初期生体データの計測を開始してから所定の計測期間が経過したときに初期生体データの取得を完了すればよい。本開示では、初期フェーズの計測期間としては、生体データの計測間隔にもよるが、例えば、1時間、2時間、3時間、・・・、1日、2日、3日等が採用される。例えば、生体データの計測間隔が短ければ、短時間で多くの初期生体データが得られるので、その分、初期生体データの計測期間は短くされる。例えば、生体データの計測間隔として1時間が採用されるのであれば、初期生体データの計測期間は、例えば、半日、1日、2日、3日等が採用され、生体データの計測間隔として、1分や1秒が採用されるのであれば、初期生体データの計測期間は、例えば、10分、20分、1時間、2時間、3時間等が採用できる。但し、これらの数値はほんの一例であり、適宜変更される。
図16は、時間帯情報として、ユーザ端末2に表示される表示画面G1の一例を示す図である。表示画面G1は、グラフG11及びメッセージ表示欄G12を備える。
ここで、図16に示す表示画面G1において、該当するユーザのスケジュール情報が表示されてもよい。この場合、サーバ1は、ユーザのスケジュール情報を管理するデータベースを備えればよい。
実施の形態2は、サーバ1の機能をユーザ端末2に組み込んだものである。なお、実施の形態2において実施の形態1と同一の構成要素には同一の符号を付し、説明を省く。図17は、本開示の実施の形態2に係る情報処理システムの処理を示すシーケンス図である。
2 ユーザ端末
3 センサ
11 制御部
12 メモリ
13 通信部
21 制御部
22 メモリ
23 表示部
24 通信部
31 制御部
32 メモリ
33 検出部
34 通信部
111 データ解析部
NT ネットワーク
T2 正常範囲データテーブル
T4 生体データテーブル
U1 ユーザ
Claims (10)
- 情報処理システムにおける情報提供方法であって、
ユーザの皮膚表面から放出されるベンジルアルコール(Benzyl alcohol)を検出するセンサにて取得された前記ユーザのベンジルアルコールの濃度を示す生体ガス情報を複数のタイミングで、前記複数のタイミングの各時刻に対応する時間情報と共にネットワークを介して取得し、
単位期間当たりの前記ベンジルアルコールの正常範囲の上限を表す情報を記憶するメモリから前記正常範囲の上限を表す情報を読み出し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正常範囲の上限を超える時間帯を判断し、
前記判断された時間帯を示す情報を前記ユーザの情報端末に出力し、
前記情報端末において前記情報が示した時間帯が表示される、
情報提供方法。 - 前記単位期間当たりの前記ベンジルアルコールの濃度の正常範囲の上限は、
事前の設定期間において取得された前記生体ガス情報に基づき前記ユーザに個別の情報として設定される、
請求項1記載の情報提供方法。 - 前記単位期間当たりの前記ベンジルアルコールの濃度の正常範囲の上限は、
前記ユーザを含む複数のユーザに共通して使用される情報として前記メモリに予め記憶されている、
請求項1記載の情報提供方法。 - 前記情報端末において前記情報が示した時間帯は、
前記ユーザのスケジュール情報に重畳されて表示される、
請求項1記載の情報提供方法。 - 前記ベンジルアルコールを検出するセンサは、
前記ユーザに装着されるデバイスに内蔵されている、
請求項1記載の情報提供方法。 - 前記複数のタイミングの各時刻に対応する時間情報は、前記生体ガスを前記センサにて取得した各時刻に対応する、
請求項1記載の情報提供方法。 - サーバ装置と情報端末とを含む情報処理システムであって、
前記サーバ装置は、
ユーザの皮膚表面から放出されるベンジルアルコール(Benzyl alcohol)を検出するセンサにて取得された前記ユーザのベンジルアルコールの濃度を示す生体ガス情報を複数のタイミングで、前記複数のタイミングの各時刻に対応する時間情報と共にネットワークを介して取得し、
単位期間当たりの前記ベンジルアルコールの正常範囲の上限を表す情報を記憶するメモリから前記正常範囲の上限を表す情報を読み出し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正常範囲の上限を超える時間帯を判断し、
前記判断された時間帯を示す情報を前記情報端末に出力し、
前記情報端末は、
前記判断された時間帯を示す情報を前記情報端末のディスプレイに表示する、
情報処理システム。 - 請求項7記載の情報処理システムにおける情報端末。
- コンピュータを用いた情報処理方法であって、
ユーザの皮膚表面から放出されるベンジルアルコール(Benzyl alcohol)を検出するセンサにて取得された前記ユーザのベンジルアルコールの濃度を示す生体ガス情報を取得し、
単位期間当たりの前記ベンジルアルコールの正常範囲の上限を表す情報を記憶するメモリから前記正常範囲の上限を表す情報を読み出し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正常範囲の上限を超えたと判断した場合、前記ユーザのストレスが前記正常範囲を超えている旨の情報をディスプレイに表示するために出力し、
前記取得した生体ガス情報に基づき、前記ユーザのベンジルアルコールの濃度が前記正常範囲の上限以下であると判断した場合、前記ユーザのストレスは前記正常範囲内にある旨の情報を前記ディスプレイに表示するために出力する、
情報処理方法。 - 前記ディスプレイは、前記ユーザの情報端末に設けられている、
請求項9記載の情報処理方法。
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EP18829069.6A EP3650859A4 (en) | 2017-07-07 | 2018-06-05 | INFORMATION PROVIDING METHOD, INFORMATION PROCESSING SYSTEM, INFORMATION TERMINAL, AND INFORMATION PROCESSING METHOD |
CN201880026543.7A CN110537095B (zh) | 2017-07-07 | 2018-06-05 | 信息提供方法、信息处理系统、信息终端及信息处理方法 |
KR1020197032450A KR20200024759A (ko) | 2017-07-07 | 2018-06-05 | 정보 제공 방법, 정보 처리 시스템, 정보 단말, 및 정보 처리 방법 |
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US11114202B2 (en) | 2021-09-07 |
EP3650859A4 (en) | 2020-05-27 |
CN110537095B (zh) | 2022-07-08 |
KR20200024759A (ko) | 2020-03-09 |
CN110537095A (zh) | 2019-12-03 |
US20200013506A1 (en) | 2020-01-09 |
JPWO2019008978A1 (ja) | 2020-05-07 |
JP6970900B2 (ja) | 2021-11-24 |
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