WO2020202627A1

WO2020202627A1 - Life-related information management system and life-related information management device

Info

Publication number: WO2020202627A1
Application number: PCT/JP2019/043875
Authority: WO
Inventors: 徹江口; 掛　晃幸; 築石丸
Original assignee: 株式会社ワコム
Priority date: 2019-04-05
Filing date: 2019-11-08
Publication date: 2020-10-08
Also published as: JPWO2020202627A1

Abstract

The present invention makes it possible to appropriately manage and easily use various types of life-related information that occur along a time axis, without user intervention. A management device (100) is provided with a position detection device unit, which comprises a position detection sensor (107D) and a position detection circuit unit (108). Schedule information corresponding to a specification input that was made by an electronic pen and received via the position detection device unit is recorded in a life data file (104). The schedule information stored in the life data file (104) is transmitted to a watch device via a short-range wireless communication unit (101) and a short-range wireless communication antenna (101A) and is used in the watch device.

Description

Life-related information management system and life-related information management device

The present invention relates to a system and an apparatus for managing life-related information such as schedule information, user's biological information, and diary information.

Patent Document 1, which will be described later, discloses an invention relating to a diary creation system that supports the user to leave the scene of the place and the impression of the user as much as possible without imposing a burden on the user. In the invention disclosed in Patent Document 1, the current date and time and the current position are transmitted from the terminal device to the server, the server receives the question data, and the answer contents to the question data are input to the terminal device. Send to the server. As a result, the server generates diary data from the question data and the answer contents and provides the diary data to the terminal device.

Further, Patent Document 2 described later discloses an invention relating to a health management system or the like capable of continuously managing the health of employees or the like using a wearable device. The invention disclosed in Patent Document 2 measures employee heartbeat data through a wearable device, and transmits the measured heartbeat data and the employee registration ID to a data collection terminal. The data collection terminal sends the received data to the server, and the server calculates the health management data of the employees using the heartbeat data, creates a health management page, and makes it possible to manage each employee.

Japanese Unexamined Patent Publication No. 2012-221471 JP-A-2017-167802

As mentioned above, a diary creation system and a health management system already exist, and it is possible to manage diary information and biometric information individually. Information that occurs daily, such as diary information (past information) and biometric information such as heart rate information, includes schedule information (scheduled information) that will occur for the future. The schedule information becomes past information, that is, diary information after the implementation date (scheduled date).

In this way, diary information, biological information, schedule information, etc. are life-related information that occurs daily on one time axis in a person's life. For this reason, instead of managing diary information, biometric information, schedule information, etc. separately, it is possible to comprehensively manage them collectively and use them as needed without bothering the user as much as possible. Is desirable.

In view of the above, the present invention makes it possible to appropriately manage and easily use various life-related information generated on one time axis without bothering the user. The purpose.

To solve the above problems
A life-related information management system consisting of a life-related information management device and a wearable device.
The life-related information management device is
A position detection device unit consisting of a position detection sensor and a position detection circuit,
A life-related information storage unit that stores schedule information according to an instruction input by an electronic pen received through the position detection device unit, and a life-related information storage unit.
It is provided with a management device-side transmission unit that transmits schedule information stored in the previous life-related information storage unit to the wearable device.
The wearable device is
A wearable device-side receiver that receives the schedule information transmitted from the life-related information management device, and
Provided is a life-related information management system including a schedule information storage unit for storing the schedule information received by the wearable device side receiving unit.

According to this life-related information management system, the life-related information management device includes a position detection device unit composed of a position detection sensor and a position detection circuit. The schedule information corresponding to the instruction input by the electronic pen received through the position detection device unit is recorded in the life-related information storage unit. The schedule information stored in the life-related information storage unit is transmitted to the wearable device through the transmission unit on the management device side. In the wearable device, the schedule information transmitted from the life-related information management device is received through the wearable device side receiving unit, and the received schedule information is stored in the schedule information storage unit.

As a result, the schedule information handwritten by the electronic pen is managed in the life-related information management device, and is also provided to the wearable device so that it can be used through the wearable device without any restrictions on the location. That is, it is possible to easily input schedule information and manage it appropriately without bothering the user. Furthermore, by providing the schedule information entered in the life-related information management device to the wearable device that the user always wears and holding it, it can be checked immediately as needed so that it can be used appropriately. Will be done.

It is a figure for demonstrating the configuration example of the life-related information management system of embodiment. It is a block diagram for demonstrating the configuration example of the watch device which is an example of the wearable device of embodiment. It is a figure for demonstrating an example of the collected data of the watch device of embodiment. It is a block diagram for demonstrating the configuration example of the life-related information management apparatus of embodiment. It is a figure for demonstrating the example of the storage data of the life data file of the life-related information management apparatus of embodiment. It is a figure for demonstrating the example of the storage data of the prediction data file of the life-related information management apparatus of embodiment. It is a figure for demonstrating the example of the input screen of the life-related information management apparatus of embodiment. It is a figure for demonstrating an example of the graph which shows the change of the physical state formed by using the biological information and the like in the life-related information management apparatus of embodiment. It is a flowchart for demonstrating the schedule creation process executed by the life-related information management apparatus of embodiment. It is a flowchart for demonstrating the biometric information acquisition processing executed by the life-related information management apparatus of embodiment.

[Configuration example of life-related information management system]
FIG. 1 is a diagram for explaining a configuration example of the life-related information management system of the embodiment. As shown in FIG. 1, the life-related information management system of this embodiment includes a life-related information management device (hereinafter, abbreviated as a management device) 100, an electronic pen 200, and a smart watch which is an example of a wearable device. It is composed of a watch device 300 called. The management device 100 and the watch device 300 can be wirelessly communicated with each other by, for example, a short-range wireless communication system of the BlueTooth (registered trademark) standard.

As will be described in detail later, the management device 100 includes a display unit 107D, a position detection sensor 107S provided corresponding to the entire display screen of the display unit 107D, and a position detection circuit unit (not shown). A position detection device unit is provided. The display unit 107D is, for example, a display device such as an LCD (Liquid Crystal Display), and is provided with a thin display screen. In the management device 100, handwritten input of characters, symbols, figures, etc. is possible in response to the instruction input by the electronic pen 200 to the position detection sensor 107S.

The management device 100 can be realized as various large ones. For example, it can be realized as a portable size of about a tablet PC (Personal Computer), or can be realized as a size of a Levi receiver having a display screen of about 50 inches. The management device 100 of this embodiment is used by hanging it on a wall of a home or a company, and the size of the display screen of the display unit 107D is, for example, about 50 inches.

As shown in FIG. 1, the management device 100 displays a calendar image on the display unit 107D, accepts a selection input of a target date area (date field) from the user, and inputs information to the date area. Allows input. The management device 100 can receive the input of the schedule information by handwriting using the electronic pen 200 through the position detection sensor 107S, and store and store the schedule information in the selected date area. The management device 100 can display the stored schedule information on the display unit 107D or provide it to the watch device 300 by short-range wireless communication.

The watch device 300 is a wristwatch-type device worn on the user's wrist and is provided with a display unit, a clock circuit, a biosensor, a GPS (Global Positioning System) unit, and the like, which will be described in detail later. As a result, the watch device 300 can store the schedule information from the management device 100 and provide it to the user through the display unit as needed. In addition, the watch device 300 measures (acquires) the biometric information of the user wearing the watch device 300 at predetermined timings, acquires the current time and the current position at the time of measurement, and accumulates these. Can retain memory. Of course, the watch device 300 can also display the current time and provide it to the user.

The user's biological information includes pulse, blood pressure, body temperature, and the like. In addition, pulse and heartbeat may be used as synonyms. However, the watch device 300 is attached to the user's arm, measures the pulse in the user's arm, and utilizes this. Therefore, in this embodiment, the word “pulse” is used instead of the word “heartbeat”.

The watch device 300 can provide the management device 100 with the biological information cumulatively stored and the current time and the current position at the time of measurement of the biological information by the short-range wireless communication function. The management device 100 receives the biometric information of the user wearing the watch device 300 from the watch device 300, stores and manages the biometric information for each date, analyzes the information, and outputs the analysis result. be able to. Further, the management device 100 can receive additional input of information as needed through the position detection device unit and the electronic pen 200 mounted on the management device 100, and can store and hold the additional input of the information.

As described above, in the life-related information management system of this embodiment, diary information composed of schedule information input in advance by the user, biological information measured daily, schedule information that has passed the deadline, and additional information. Etc. are comprehensively managed and made available. That is, the life-related information management system of this embodiment can appropriately manage various life-related information generated on one time axis without bothering the user, and can be appropriately managed as needed. It is also made possible to use it properly.

In the following, first, the watch device 300, which is a device constituting the life-related information management system of this embodiment, is attached to the arm of the user and is always used. After that, the management device 100 installed and used in a home or a company will be described.

[Configuration example of watch device 300]
FIG. 2 is a block diagram for explaining a configuration example of a watch device 300, which is an example of a wearable device used in the life-related information management system of the embodiment. In FIG. 2, the short-range wireless communication antenna 301A and the short-range wireless communication unit 301 realize, for example, the short-range wireless communication function of the BlueTooth (registered trademark) standard in this embodiment. Although not shown, the control unit 302 is a microprocessor in which a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a non-volatile memory, and the like are connected via a bus. The control unit 302 controls each unit of the watch device 300.

The storage device 303 includes a semiconductor memory having a relatively large storage capacity and a driver thereof, and under the control of the control unit 302, data is written, read, changed, and deleted from the memory. In the memory of the storage device 303, for example, schedule information from the management device 100 and information such as the current time, biological information, current position, and picked-up voice message acquired by the own machine as described later are recorded and held. To. The operation unit 304 is a portion including a plurality of operation buttons provided in the housing of the watch device 300. For example, a schedule information display button, a recording start / end button, and the like are provided.

The clock circuit 305 provides the current date, the current day of the week, and the current time. In this embodiment, the biosensor 306 can measure the pulse, blood pressure, and body temperature of the user wearing the watch device 300. That is, the biological sensor 306 includes a pulse sensor, a blood pressure sensor, a body temperature sensor, and the like. Body temperature does not change significantly during the day. Therefore, in this embodiment, the pulse and the blood pressure are mainly used. The 6-axis sensor 307 can detect the moving direction, the moving speed, the moving distance, the number of steps, and the like. The voice processing unit 308 and the microphone 309 can collect the voice message of the user and capture it as digital data.

The display unit 310 is provided with a thin and small display screen such as an LCD or an organic EL display, and can display various information under the control of the control unit 302. For example, it is possible to display the schedule information from the management device 100, or to display the information such as the current time, the biological information, and the current position acquired by the own machine as stated.

The data acquisition control unit 311 realizes a function of acquiring biometric information, the current time, and the current position and recording them in a predetermined area of the storage device 303 under the control of the control unit 302. The GPS unit 312 and the GPS antenna 312A receive signals from a plurality of artificial satellites and determine the current position of the own machine. The data acquisition control unit 311 acquires biometric information from the biosensor 306, the current date and time from the clock circuit 305, and the current time from the GPS unit 312 at predetermined timings, and associates these with the storage device 303. Record in the designated area of.

The data acquisition control unit 311 can acquire data at predetermined timings such as every minute, every three minutes, every five minutes, every ten minutes, every thirty minutes, every one hour, and so on. .. Further, when the current position changes and the data acquisition control unit 311 stays at the changed current position for a predetermined time or more (for example, 3 minutes or more), the data acquisition control unit 311 obtains biometric information and the current time in addition to the current position. You can also get it.

In the former case, it is possible to acquire the biometric information and the current time and store them in association with each other without acquiring the current position. Further, in the latter case, it is possible to acquire the biometric information and the current position and store them in association with each other without acquiring the current time. Further, if the acquisition timing is fixed, for example, every minute, only the biological information can be acquired and recorded in order in a predetermined area of the storage device 303. That is, the data acquisition control unit 311 can acquire one or more of the biological information, the current time, and the current position and cumulatively record them in the storage device 303.

Then, in the case of the watch device 300 of this embodiment, the data acquisition control unit 311 displays the biometric information from the biosensor 306, the current date and time from the clock circuit 305, and the GPS unit 312 at predetermined timings. Supposes to get the current time. Then, the data acquisition control unit 311 associates the acquired data with each other and records the acquired data in a predetermined area of the storage device 303.

FIG. 3 is a diagram for explaining an example of collected data acquired by the data acquisition control unit 311 and stored in the storage device 303 in the watch device 300. In the watch device 300, when it is detected that the watch device 300 is worn on the wrist of the user, the data acquisition control unit 311 starts the data acquisition process to acquire and record the first data.

Here, the determination as to whether or not the watch device 300 is attached to the user's arm is determined when the vibration detected through the 6-axis sensor 307 can be regarded as the vibration after being attached to the user's arm, or 35. When the body temperature above the degree is detected, it can be determined that the body is worn. Of course, when both are detected, it may be determined that the watch device 300 is worn on the user's arm.

After this, the data acquisition control unit 311 monitors the current time provided by the clock circuit 305, and acquires and records data at predetermined time intervals, for example, every 5 minutes. As a result, as shown in FIG. 3, the current position, the current date and time, the blood pressure and the pulse are acquired at substantially the same timing, and this is recorded in a predetermined area of the storage device 303.

If necessary, a voice memo (voice message) from the user captured through the microphone 309 and the voice processing unit 308 is recorded according to the current position, current date and time, blood pressure and pulse. It is designed to be able to. For example, a voice memo can be input and recorded every time the place changes or a special event occurs. Of course, only voice memos can be individually recorded and retained.

In the case of the example shown in FIG. 3, at the position (X1, Y1), it is detected that the watch device 300 is attached to the user's arm at 7:00 (7:00 am) on April 1, 2019. However, the blood pressure of the user at that time is "117/75", and the pulse is shown to be "65". Then, biometric information and the like are acquired and recorded in sequence, and at the position (X2, Y2), at 15:30 (3:30 pm) on April 1, 2019, the blood pressure of the user is ". "129/79" indicates that the pulse is "70". In this case, a voice memo such as "arrival at the dental clinic" is input through the microphone 309 and the voice processing unit 308 at the same position and at the same time, and this is also stored in memory.

As described above, the watch device 300 has a short-range wireless communication function, receives the schedule information from the management device 100, records it in a predetermined area of the storage device 303, and displays it on the display unit 310 as needed. It can be displayed and confirmed. Further, the watch device 300 acquires the current time, biometric information, and the current position, cumulatively records them in a predetermined area of the storage device 303, and provides them to the management device 100 by short-range wireless communication as needed. can do.

[Configuration example of management device 100]
FIG. 4 is a block diagram for explaining a configuration example of the management device 100 used in the life-related information management system of the embodiment. In FIG. 4, the short-range wireless communication antenna 101A and the short-range wireless communication unit 101 realize the short-range wireless communication function of the BlueTooth (registered trademark) standard in this embodiment. Although not shown, the control unit 102 is a microprocessor in which a CPU, ROM, RAM, non-volatile memory, and the like are connected via a bus to control each unit of the management device 100.

The storage device 103 includes a semiconductor memory having a relatively large storage capacity and a driver thereof, and under the control of the control unit 102, data is written, read, changed, and deleted in the memory. The memory of the storage device 103 is also used as a work area. The life data file 104 is formed on a semiconductor memory having a relatively large capacity, and records and holds information such as schedule information, biometric information, and voice memo for each user and for each date.

FIG. 5 is a diagram for explaining an example of stored data in the life data file 104 of the management device 100. As shown in FIG. 5, the stored data of the life data file 104 includes information indicating each of the user ID, name, gender, and date of birth as header information. As a result, when the management device 100 is used at home, schedule information and the like can be managed for each family member, and when used at a company, for each employee.

As shown in FIG. 5, the life-related information (life data) consists of memo information such as date, schedule information, and biological information. The date is so-called calendar information, which is information corresponding to each date of each month of each year. The schedule information is information indicating the schedule input by the user, and as described above, is input by the instruction input by the electronic pen 200 used by the user to the position detection sensor 107S corresponding to each date. Is.

The biological information and the like are the information collected and accumulated in the watch device 300 as described with reference to FIG. 3, and are the information provided by the watch device 300. Since the life-related information is information managed for each date, it has information indicating the date as shown on the left end side of FIG. Therefore, as shown in FIG. 5, the biological information and the like are composed of the current position at the time of acquisition of the biological information, the current time at the time of acquisition of the biological information, the blood pressure, and the pulse.

In FIG. 5, the current position at the time of acquiring the biological information is the information shown as “X1, Y2”, “X2, Y2”, ..., And the current time at the time of acquiring the biological information is “7:00”, It is the information shown as "15:30", ... Further, the blood pressure information is the information shown as "117/75", "129/79", ..., And the pulse information is the information shown as "65", "70", .... As a result, changes in blood pressure and pulse can be viewed in chronological order during the day, and it is also possible to grasp whether or not blood pressure and pulse are changing due to changes in the current position.

As described above, the memo information is additional information corresponding to an instruction input by the electronic pen 200 used by the user for the position detection sensor 107S or voice memo information provided by the watch device 300 corresponding to each date. is there. The life-related information (life data) shown in FIG. 5 is stored in the life data file 104.

The life-related information shown in FIG. 5 belongs to the user whose user ID is "001". On April 1, 2019, the opening ceremony was held from 9:00 am, and at 3:40 pm, the opening ceremony was held. There is a reservation for the dentist's office, and a memo that goes to the clinic for dental caries treatment is also attached. Also, on May 15, 2019, I was planning to meet at school at 7:40 am for a school trip, and as noted, I overslept and missed the bus, but my friend's It is recorded that he was able to ride in his car and arrived at the meeting place without being late.

Also, as you can see from the biometric information on May 15, 2019, it can be seen that blood pressure and pulse are high when oversleeping or missed bus rides occur. Also, if you can get in the car of your friend's house or arrive at the meeting place without being late, you can see that the blood pressure and pulse are low and close to the general normal value. .. From this, it can be seen that the physical condition of the user of the watch device 300 can be grasped based on the blood pressure and the pulse.

The prediction data file 105 is formed on a semiconductor memory having a relatively large capacity, and records and holds prediction data regarding the predicted schedule for each user and for each date based on past schedule information. FIG. 6 is a diagram for explaining an example of stored data in the prediction data file 105 of the management device 100. FIG. 6A shows data extracted for a portion of the life data file 104 consisting of the date and schedule information of the user whose user ID is “001”. Further, in FIG. 6A, information indicating the day of the week is also added for the sake of simplicity.

In the management device 100, the prediction data is generated by the function of the prediction data generation unit 109 described later and stored in the prediction data file 105. As shown in Fig. 6 (A), if there is a plan to go to "○○ Dental Clinic" on April 1, 2019 (Monday) and April 8, 2019 (Monday), 2019 It can be predicted that he will go to "○○ Dental Clinic" on Monday, April 15th. Similarly, as shown in Fig. 6 (A), for example, when there are plans to go to "△△ Preparatory School" on April 2, 2019 (Tuesday) and April 9, 2019 (Tuesday). Can be predicted to go to "△△ Preparatory School" on Tuesday, April 16, 2019.

The forecast data for the schedule predicted in this way is stored in the forecast data file 105. The prediction data also includes information indicating each of the user ID, name, gender, and date of birth as header information. Then, the scheduled date, the scheduled time, and the scheduled content, which are predicted to generate the same schedule, are recorded and retained.

The analysis result file 106 stores information indicating changes in the physical condition of the user, which is obtained by analyzing the stored data of the life data file 104. As will be described in detail later, information indicating how the physical condition of the user has changed in chronological order is stored.

As described above, the display unit 107D is a display device such as an LCD. The display screen of the display unit 107D is provided with the position detection sensor 107S corresponding to the entire surface thereof. The input device 107 is configured by the display unit 107D and the position detection sensor 107S. A position detection circuit unit 108 is connected to the position detection sensor 107S. The position detection circuit unit 108 identifies the indicated position (coordinates) on the display screen by the electronic pen 200 based on the detection output from the position detection sensor 107S, and notifies the control unit 102 of this. Therefore, when the electronic pen 200 is moved while being in contact with the display screen of the display unit 107D, the contact position is sequentially detected and notified to the control unit 102, so that characters, symbols, figures, etc. You can input drawing.

The prediction data generation unit 109 refers to the stored data of the life data file 104, and if the same schedule has occurred multiple times in the past, predicts that the same schedule will occur at the same timing in the future. Generate forecast data. The prediction data generation unit 109 records the generated prediction data in the prediction data file 105. It should be noted that the above-mentioned prediction data generation process using FIG. 6 shows a very simple example. However, the prediction data generation unit 109 can perform more detailed prediction processing. For example, the same place may be visited every other day, or the same schedule may occur repeatedly once a month. Even in such a case, the prediction data generation unit 109 can appropriately make a prediction, generate the prediction data, and record it in the prediction data file 105.

For example, when the user inputs schedule information, the prediction data providing unit 110 displays the predicted data on the display unit 107D when the predicted data exists on the date specified by the user, so that the user can see it. Perform the processing to be provided. FIG. 7 is a diagram for explaining an example of an input screen of the management device 100. It is assumed that the calendar for April 2019 is displayed on the display screen of the display unit 107D of the management device 100. In this case, in order to write (enter) the schedule for April 15th, the user performs an operation of tapping the date area on April 15th with the electronic pen 200 to move the cursor to the date area on April 15th. Try to position CS.

The control unit 102 provides an input window WD for receiving input of schedule information by the electronic pen 200 in the vicinity of the date area on April 15, where the cursor CS of the display unit 107D is positioned. The control unit 102 controls the prediction data providing unit 110, and if the prediction data generated for April 15, 2019 exists, displays the information corresponding to the prediction data in the input window WD. Supports the input of schedule information.

In the case of the example shown in FIG. 7, from 15:40 (3:40 pm), information asking whether or not a reservation has been made at the "○○ Dental Clinic" is displayed, and this predicted schedule is displayed. You will be able to choose whether to additionally record or delete. The user can add the schedule information "15:40 XX Dental Clinic" on April 15, 2019 by tapping the displayed "Add button" with the electronic pen 200. Also, if only the time is different, the time can be corrected. To correct the time, for example, the eraser function may be used to erase the time display, and the correct time may be written using the electronic pen 200.

The eraser function is different from the electronic pen 200 in that, for example, an electronic eraser that transmits signals having different frequencies is prepared, and handwritten information input to a portion designated by the electronic eraser can be erased. is there. That is, the eraser function is a function realized by the electronic eraser and the management device 100 in cooperation with each other. In addition, for example, it is also possible to erase the handwritten information input to the portion where the double line is handwritten by the electronic pen 200.

Also, if the predicted schedule is wrong, or if the predicted schedule does not actually exist, tap the "Delete button" with the electronic pen 200 to predict the predicted data from the input window WD. It is also deleted from the data file 105. If there is an unpredicted schedule, the electronic pen 200 is used to manually input the schedule information into the input window WD. In the case of the example shown in FIG. 7, it is shown that the schedule information "13:30 Meeting 1st Meeting Room" was input by handwriting with the electronic pen 200 on April 15.

In this way, schedule information can be entered on the desired date. After the input of the schedule information is completed, the input window WD can be cleared and the input of the schedule information can be completed by performing a predetermined end operation such as tapping the date area to be input with the electronic pen 200. The entered schedule information is displayed so as to be reduced to the target date area so that it can be confirmed at any time.

The biological information analysis unit 111 analyzes the stored data in the life data file 104 to form information indicating a change in the physical condition of the user, and records this in the analysis result file 106. Specifically, the biological information analysis unit 111 forms information indicating a high degree of happiness based on changes in blood pressure and pulse in chronological order. For example, happiness is high if you are calm because your blood pressure and pulse are stable, and happiness if you are nervous or excited because your blood pressure and pulse are high or changes are drastic. Analysis result data with a lower degree is formed and recorded in the analysis result file 106.

The analysis result providing unit 112 displays the analysis result based on the analysis result data of the analysis result file 106 when the output of the analysis information is instructed by the user's operation on the position detection sensor 107S by the electronic pen 200. Performs the process of displaying and outputting to 107D. FIG. 8 is a diagram for explaining an example of a graph showing changes in the physical condition formed by using the analysis result data recorded in the analysis result file 106 by the biological information analysis unit 111 in the management device 100.

The graph shown in FIG. 8 was created based on the analysis result information generated by analyzing the life data of May 15, 2019 shown in FIG. 5, and the horizontal axis indicates time and the vertical axis indicates time. The axis shows happiness. As shown in FIG. 5, both blood pressure and pulse are high because the patient overslept when waking up. Therefore, even in the graph of FIG. 8, the degree of happiness at the time of waking up is low.

And, although not shown in FIG. 5, by having breakfast, both blood pressure and pulse became stable, and as shown in FIG. 8, the degree of happiness increased moderately. However, it took time to prepare after that, and the blood pressure and pulse gradually increased, and as shown in FIG. 8, the degree of happiness turned to a decreasing tendency. After that, because he missed the bus to be boarded, the blood pressure and pulse increased as shown in FIG. 5, and the happiness decreased as shown in FIG.

However, by acting to walk to the next bus stop, blood pressure and pulse gradually stabilize, and happiness also begins to rise. After that, I got the opportunity to ride in the car of my friend's house, and as shown in Fig. 5, my blood pressure and pulse became stable, and as shown in Fig. 8, my happiness increased, and I arrived at school without being late. By doing so, the blood pressure and pulse are stabilized, and as shown in FIG. 8, the degree of happiness is also high.

The analysis result providing unit 112 of the management device 100 of this embodiment is a graph showing changes in the physical condition of the user based on the analysis result data of the analysis result file 106. In this example, the user feels. I am trying to display a graph showing the change in happiness.

As described above, the management device 100 of this embodiment cooperates with the watch device 300, and troubles the user with the schedule information, the biological information, the diary information composed of the past schedule information and the additional data. It is managed comprehensively so that it can be used appropriately.

[Summary of main processing of management device 100]
<Schedule information creation process>
FIG. 9 is a flowchart for explaining the schedule creation process executed by the management device 100. As shown in FIG. 1, the process shown in FIG. 9 is a process that is always executed by the control unit 102 of the management device 100 when the calendar is displayed.

The control unit 102 receives an instruction input for the date area using the electronic pen 200 through the position detection device unit including the position detection sensor 107S and the position detection circuit unit 108 (step S101). The process of step S101 is an operation of tapping the date area (in the case of FIG. 7, the area of April 15) to which the schedule information is to be input by using the electronic pen 200, as described with reference to FIG. Is the process of accepting.

Next, the control unit 102 determines in step S101 whether or not the date area instruction input (selection input) has been accepted (step S102). When it is determined in the determination process of step S102 that the instruction input of the date area is not accepted, the control unit 102 repeats the process from step S101 and waits for the instruction input of the date area to be performed. Become.

It is assumed that it is determined that the date area instruction input has been accepted in the determination process in step S102. In this case, the control unit 102 controls the prediction data generation unit 109 to generate prediction data related to the schedule based on the past schedule data of the life data file 104, and execute a process of recording the prediction data in the prediction data file 105. (Step S103). Next, as described with reference to FIG. 7, the control unit 102 forms an input area (input window WD) on the display screen of the display unit 107D, and the prediction data created on the specified date exists. If so, this is displayed in the input area (step S104).

When the prediction data exists by the process of step S104, the prediction data can be displayed in the input area and can be selected to be added or deleted as the schedule information as described with reference to FIG. 7. To do so. Further, other schedule information can be input through the position detection sensor 107S and the position detection circuit unit 108 using the electronic pen 200.

The control unit 102 receives an instruction input using the user's electronic pen 200 through an input area provided on the display screen of the display unit 107D (step S105). Then, in step S105, the control unit 102 determines whether or not the user has accepted a predetermined operation instructing the completion of the instruction input (step S106). The predetermined operation determined in step S106 is a predetermined operation such as reselection (instruction) of the selected date area, for example.

In the determination process of step S106, when it is determined that the predetermined operation for instructing completion is not accepted, the process from step S105 is repeated. In the determination process of step S106, when it is determined that the predetermined operation instructing the completion has been accepted, it is determined whether or not the input schedule information including the prediction data exists (step S107).

In the determination process of step S107, when it is determined that the input schedule information does not exist, it means that the schedule information has not been input, so the process from step S101 is repeated. When it is determined that the input schedule information exists in the determination process in step S107, the control unit 102 stores the input schedule information in the life data file 104 (step S108).

After that, the control unit 102 receives an instruction input from the user through the position detection sensor 107S and the position detection circuit unit 108 (step S109). In step S109, the control unit 102 determines whether or not the transfer instruction of the schedule information to the watch device 300 has been accepted (step S110). The determination process in step S110 is, for example, a process for determining whether or not the operation of selecting the "transfer button" displayed at a predetermined position on the display unit 107D using the electronic pen 200 has been accepted in step S109. ..

It is assumed that it is determined that the transfer instruction has been accepted in the determination process in step S110. In this case, the control unit 102 executes a process of transferring the schedule information registered in the life data file 104 to the watch device 300 through the short-range wireless communication unit 101 and the short-range wireless communication antenna 101A (step S111). .. Further, when it is determined in the determination process of step S110 that the transfer instruction is not accepted, it is determined whether or not the instruction received in step S109 is a predetermined end instruction (step S112). When it is determined that the end instruction is not accepted in the determination process in step S112, the process from step S109 is repeated.

When it is determined that the end instruction has been accepted after the process of step S111 and in the determination process of step S112, the process from step S101 is repeated so that the instruction input of the date is accepted again. In this way, in the management device 100, the schedule information can be input while the calendar is displayed, and the schedule to be repeated can be predicted by the prediction process based on the past schedule information. , You can remember to enter it. Further, the schedule information input to the management device 100 is transferred to the watch device 300 so that the schedule information can be used by the watch device 300.

Here, the schedule information input corresponding to the selected date is transferred to the watch device 300. However, it is not limited to this. For example, schedule information can be transferred from the management device 100 to the watch device 300 on a monthly or weekly basis. It is also possible to specify a period and transfer the schedule information for that period from the management device 100 to the watch device 300.

<Acquisition processing of biological information, etc.>
FIG. 10 is a flowchart for explaining the acquisition process of biological information and the like executed by the management device 100. In the process shown in FIG. 10, when the watch device 300 approaches the management device 100, short-range wireless communication is performed between the management device 100 and the watch device 300, mutual authentication is obtained, and the communication path is connected. In this case, it is executed by the control unit 102.

First, the control unit 102 requests the watch device 300 to provide biological information and the like (step S201). In response to this, biometric information and the like are transmitted from the watch device 300 by short-range wireless communication. The control unit 102 receives biometric information or the like from the watch device 300 through the short-range wireless communication antenna 101A and the short-range wireless communication unit 101, and stores this in the storage column of the corresponding date of the life data file 104 (step). S202).

After that, the control unit 102 displays an input field for additional information corresponding to each date on the display screen of the display unit 107D (step S203). The control unit 102 receives the input of additional information using the electronic pen 200 into the input field of the additional information through the position detection sensor 107S and the position detection circuit unit 108 (step S204). In step S204, additional information can be entered only for the required dates. Also, additional information need only be entered for dates that require additional information to be entered. Of course, it is possible to prevent the input of additional information at all. Further, in step S204, when the input of additional information is completed, a predetermined completion operation is performed.

Next, in step S204, the control unit 102 determines whether or not the completion operation has been accepted (step S205), and when it determines that the completion operation has not been accepted, repeats the process from step S204. In the determination process of step S205, when it is determined that the completion operation has been accepted, it is determined whether or not additional information has been input (step S206).

When it is determined that the additional information has been input in the determination process of step S206, the additional information received in step S204 is stored in the life data file 104 so as to be associated with the instructed date (step S207). If it is determined that no additional information has been input after the process of step S207 and in the determination process of step S206, the process shown in FIG. 10 is terminated.

In this way, the management device 100 can acquire the biometric information and the like collected by the watch device 300 from the watch device 300 and store them in the life data file 104 for each date. In addition, additional information can be additionally input for each date. In FIG. 10, the acquisition process of biological information and the like and the input process of additional information are continuously performed, but the present invention is not limited to this. The acquisition process of biological information and the input process of additional information can be performed at different timings as separate processes.

[Effect of Embodiment]
In the life-related information management system of the above-described embodiment, life-related information (life data) such as so-called diary information consisting of past schedule information and additional information such as schedule information and biological information is collectively managed. Can be done. In this case, the schedule information and additional information can be easily input by handwriting using the electronic pen 200. That is, it is not necessary to input through a so-called keyboard or the like.

In addition, the schedule information can be transferred to the watch device 300 and used through the watch device 300. Therefore, the schedule information can be used as needed not only through the life-related information management device installed in the home or the office but also through the watch device 300 worn by the user.

In addition, information such as biological information, current time, and current position is automatically acquired by the watch device 300. Therefore, the user of the watch device 300 does not perform any processing regarding the acquisition of biometric information, the current time, and the current position. That is, there is no burden on the user regarding the acquisition of biological information and the like. Further, the biological information and the like collected by the watch device 300 are provided to the management device 100 by short-range wireless communication and made available.

Therefore, various life-related information generated on one time axis can be acquired and appropriately managed without bothering the user, and can be easily used.

[Modification example]
<About the method used in the position detection device>
It has been explained that the management device 100 of the above-described embodiment includes a position detection device unit including a position detection sensor 107S and a position detection circuit unit 108, and can input instructions by the electronic pen 200. In this case, various methods can be used as the method used between the position detection device unit and the electronic pen 200.

For example, the main methods for indicating the position used in the input device consisting of the electronic pen and the position detection device are the electromagnetic induction method (EMR (ElectroMagnetic Resonance technology) method) and the capacitance method. There is. The capacitance method includes the capacitance method (ES (Electrostatic) method) that can detect the touch of the user's hand and the active capacitance method (AES) that actively transmits signals from the electronic pen. (Active Electrostatic) method). Any of these methods can be used in the life-related information management system of the present invention.

<About electronic pens that can physically leave handwriting>
Further, the electronic pen 200 of the above-described embodiment does not physically leave the handwriting on the display screen, but electronically draws and inputs by the various methods described above. However, it is not limited to this. For example, like a marker pen on a whiteboard, it is possible to electronically perform drawing input according to the physical handwriting while leaving a physical handwriting on the position detection sensor. In this case, the electronic pen has a function that can physically leave a handwriting with ink, such as a whiteboard marker pen or a felt-tip pen (sign-tip pen), in addition to the function as a simple electronic pen. You can do it like this.

Further, in this case, the management device 100 does not necessarily have to include a display unit. For example, a life according to the present invention provided with a position detection unit including a position detection sensor and a position detection circuit unit on an operation surface that can be physically written by a whiteboard marker pen, such as a whiteboard. It is also possible to realize a management information management device. In the case of a life management information management device that does not have a display unit, a memory for holding the entered schedule information and a memory for holding the entered schedule information as diary information in the manner shown in FIG. 5 when the implementation date and time have passed. Schedule information and diary information can be managed by providing a memory to be used.

In addition, a whiteboard eraser (erasa for whiteboard) is also required to erase handwriting such as schedule information physically recorded on the operation surface. In this case, the eraser is also equipped with a position indicating function in the same manner as the electronic pen. As a result, when the handwriting such as the schedule information physically recorded on the operation surface is erased, the life management information management device can process so as to erase the information in the memory holding the schedule information.

<Collaboration with external devices>
In the above-described embodiment, the management device 100 can provide the schedule information to the watch device 300, and the watch device 300 can notify the user of the arrival of the schedule based on the schedule information. For example, one day before the arrival of the schedule, one hour before the arrival of the schedule, and the like, the arrival of the schedule can be notified at the timing instructed by the user.

Similarly, the schedule information can be transmitted to the so-called smart speaker, and the smart speaker can notify the arrival of the schedule. Of course, when the management device 100 detects the arrival of a schedule based on the schedule information managed by the own device, the smart speaker is controlled by using the short-range wireless communication function, and the schedule arrives from the smart speaker. May be notified. The timing of the notification can be a timing based on the instruction (setting) of the user, such as one day before the arrival of the schedule, one hour before the arrival of the schedule.

<Other examples of watch device 300>
In the above-described embodiment, the watch device 300, which is a wristwatch-type device worn by the user on the wrist, is used, but the present invention is not limited to this. It is possible to use various wearable devices such as eyeglass-type devices, ring-type devices, earring-type devices, necklace-type devices, etc., which can be worn on the user's bare skin and can acquire biological information.

<Possibility of wired connection>
In the above-described embodiment, the management device 100 and the watch device 300 are connected by short-range wireless communication, but the present invention is not limited to this. Of course, you may connect by wire. For example, it is possible to connect using a USB (Universal Serial Bus) standard bus.

[Other]
As can be seen from the above description, each function of the position detection sensor unit and the position detection circuit unit of the life-related information management device according to claim is provided by the position detection sensor 107S and the position detection circuit unit 108 of the management device 100 of the embodiment. It has been realized. Further, the function of the management device side transmission unit of the life-related information management device according to the claim is realized by the short-range wireless communication unit 101 and the short-range wireless communication antenna 101A of the management device 100 of the embodiment.

Further, the function of the wearable device side receiving unit of the wearable device of the claim is realized by the short-range wireless communication unit 301 and the short-range wireless communication antenna 301A of the embodiment. Further, the storage device 303 realizes the function of the schedule information storage unit of the wearable device.

Further, the functions of the prediction data generation unit, the prediction data presentation unit, and the additional recording unit of the life-related information management device according to the claim are controlled by the prediction data generation unit 109, the prediction data providing unit 110, and the control of the management device 100 of the embodiment. Part 102 is realized.

Further, the functions of the biometric information acquisition unit and the current time providing unit of the wearable device according to the claim are realized by the biosensor 306 and the clock circuit 305 of the watch device 300 of the embodiment. Further, the functions of the acquisition control unit and the recording control unit of the wearable device of the embodiment are both realized by the control unit 302 of the watch device 300 of the embodiment. Further, the function of the wearable device side transmission unit of the wearable device is realized by the short-range wireless communication unit 301 and the short-range wireless communication antenna 301A of the watch device 300 of the embodiment.

Further, the function of the receiving unit on the management device side of the life-related information management device according to the claim is realized by the short-range wireless communication unit 101 and the short-range wireless communication antenna 101A of the management device 100 of the embodiment. Further, the function of the reception information recording control unit of the life-related information management device is realized by the control unit 102 of the management device 100 of the embodiment.

The function of the current position positioning unit of the wearable device according to the claim is realized by the GPS antenna 312A including the GPS unit 312 of the watch device 300 of the embodiment. Further, the function of the voice input unit of the wearable device according to the claim is realized by the voice processing unit 308 including the microphone 309 of the watch device 300 of the embodiment. Also. The function of the voice recording control unit of the wearable device according to the claim is realized by the control unit 302 of the watch device 300 of the embodiment.

Further, the function of the additional information storage unit of the life-related information management device according to the claim is realized by the control unit 102 of the management device 100 of the embodiment. The functions of the state change analysis unit and the analysis result providing unit of the life-related information management device according to the claim are realized by the biological information analysis unit 111 and the analysis result providing unit 112 of the management device of the embodiment.

100 ... Life-related information management device, 101A ... Short-range wireless communication antenna, 101 ... Short-range wireless communication unit, 102 ... Control unit, 103 ... Storage device, 104 ... Life data file, 105 ... Prediction data file, 106 ... Analysis result File, 107 ... Input device, 107D ... Display unit, 107S ... Position detection sensor, 108 ... Position light circuit unit, 109 ... Prediction data generation unit, 110 ... Prediction data provision unit, 111 ... Biological information analysis unit, 112 ... Analysis result Provider, 200 ... Electronic pen, 300 ... Watch device, 301A ... Short-range wireless communication antenna, 301 ... Short-range wireless communication unit, 302 ... Control unit, 303 ... Storage device, 304 ... Operation unit, 305 ... Clock circuit, 306 ... Biosensor, 307 ... 6-axis sensor, 308 ... Voice processing unit, 309 ... Microphone, 310 ... Display unit, 311 ... Data acquisition control unit, 312 ... GPS unit, 312A ... GPS antenna

Claims

A life-related information management system consisting of a life-related information management device and a wearable device.
The life-related information management device is
A position detection device unit consisting of a position detection sensor unit and a position detection circuit unit,
A life-related information storage unit that stores schedule information according to an instruction input by an electronic pen received through the position detection device unit, and a life-related information storage unit.
It is provided with a management device-side transmission unit that transmits schedule information stored in the life-related information storage unit to the wearable device.
The wearable device is
A wearable device-side receiver that receives the schedule information transmitted from the life-related information management device, and
A life-related information management system including a schedule information storage unit that stores the schedule information received by the wearable device-side receiving unit.
The life-related information management system according to claim 1.
A prediction data generation unit that generates prediction data for a schedule after the current time point based on the past schedule information stored in the life-related information storage unit.
A prediction data presentation unit that presents the prediction data generated by the prediction data generation unit to the user,
Among the prediction data presented through the prediction data presentation unit, the life-related aspect is provided with an additional recording unit that additionally records the prediction data instructed by the user as the schedule information in the life-related information storage unit. Information management system.
The life-related information management system according to claim 1 or 2.
The wearable device is
The biometric information acquisition unit that acquires the biometric information of the user who is wearing the machine,
The current time provider that provides the current time and
An acquisition control unit that acquires the biometric information and the current time indicating the acquisition time of the biometric information from the biometric information acquisition unit and the current time providing unit at predetermined timings.
A recording control unit that associates the biological information acquired by the acquisition control unit with the current time and records it in the acquisition information storage unit.
It is provided with a wearable device-side transmission unit that transmits information stored in the acquired information storage unit to the life-related information management device.
The life-related information management device is
A receiver on the management device side that receives information transmitted from the wearable device,
A life-related information management system characterized in that the life-related information storage unit is provided with a reception information recording control unit that records information received by the management device-side reception unit in association with a date.
The life-related information management system according to claim 3.
The wearable device is
Equipped with a current position positioning unit that positions the current position of the own machine
The acquisition control unit can acquire the current position indicating the acquisition position of the biometric information from the current position positioning.
The recording control unit can record the current position acquired by the acquisition control unit in the acquired information storage unit in association with the biological information and the current time. Information management system.
The life-related information management system according to claim 3 or 4.
The wearable device is
A voice input unit that accepts voice message input and
It is provided with a voice recording control unit that records a voice message received through the voice input unit in a voice information storage unit.
The wearable device-side transmission unit is a life-related information management system characterized in that the voice message stored in the voice information storage unit can be transmitted to the life-related information management device.
The life-related information management system according to any one of claims 3 to 5.
The life-related information management device is
Life is characterized by comprising an additional information recording control unit that records additional information corresponding to an instruction input by an electronic pen received through the position detection device unit in association with the information stored in the life-related information storage unit. Related information management system.
The life-related information management system according to any one of claims 3 to 6.
The life-related information management device is
A state change analysis unit that analyzes the data stored in the life-related information storage unit and detects changes in the user's physical condition according to a time series.
A life-related information management system including an analysis result providing unit that controls to output the detected state change.
The life-related information management device of the life-related information management system composed of a life-related information management device and a wearable device.
A position detection device unit consisting of a position detection sensor and a position detection circuit,
A life-related information storage unit that stores schedule information according to an instruction input by an electronic pen received through the position detection device unit, and a life-related information storage unit.
A life-related information management device including a management device-side transmission unit that transmits schedule information stored in the life-related information storage unit to the wearable device.
The life-related information management device according to claim 8.
A prediction data generation unit that generates prediction data for a schedule after the current time point based on the past schedule information stored in the life-related information storage unit.
A prediction data presentation unit that presents the prediction data generated by the prediction data generation unit to the user,
Among the prediction data presented through the prediction data presentation unit, the life-related aspect is provided with an additional recording unit that additionally records the prediction data instructed by the user as the schedule information in the life-related information storage unit. Information management device.
The life-related information management device according to claim 8 or 9.
Life is characterized by comprising an additional information recording control unit that records additional information corresponding to an instruction input by an electronic pen received through the position detection device unit in association with the information stored in the life-related information storage unit. Related information management device.
The life-related information management device according to any one of claims 8 to 10.
A receiver that receives the user's biometric information including the acquisition time from the wearable device, and
A recording control unit that records information received through the receiving unit in a life-related information storage unit in association with a date.
A state change analysis unit that analyzes the data stored in the life-related information storage unit and detects changes in the user's physical condition according to a time series.
A life-related information management device including an analysis result providing unit that controls to output the detected state change.