JP7073763B2 - Information processing system, information processing method, electronic device, server device and information processing program - Google Patents

Description

The present invention relates to an information processing system, an information processing method, an electronic device, a server device, and an information processing program.

In recent years, mobile terminals that can acquire and display biological information (for example, pulse rate, blood pressure, calorie consumption, etc.) of individual humans called wearable devices such as wristwatch-type mobile terminals and neck-strap-type mobile terminals have appeared. In addition, in companies, employees are often aware of social problems that cause health problems due to long hours of overwork and are working on preventive measures.

Among them, for example, as in the health management system disclosed in Patent Document 1 (Japanese Unexamined Patent Publication No. 2006-243696), a long time based on the entrance / exit information and work information collected by the health management data server. By extracting workers, sending instruction information to perform health checks to the workplace employee terminals of long-time workers, and accumulating the collected health check information in the health management database in association with employees. According to the technology delivered in response to a request from the health management department terminal, it is possible to grasp the health condition of an employee during long working hours and prevent health problems due to overwork of the employee.

However, since the health management system disclosed in Patent Document 1 determines the health condition of employees based on working hours, for example, all employees who work long hours are uniformly in good health. There is a problem that it is judged that there is a problem.

It is preferable that the health condition of the user can be judged more accurately, and that the result of the health check is not only grasped by the employer but also notified to the employee to encourage self-management. However, since the result of the health check is highly confidential personal information, when providing it to employees, it is preferable to provide it personally at an appropriate timing.

The present invention has been made in view of the above-mentioned problems, and is an information processing system, an information processing method, an electronic device, a server device, and an information processing system, an information processing method, an electronic device, a server device, which can more accurately judge a user's health condition and notify the user at an appropriate timing. The purpose is to provide an information processing program.

In order to solve the above-mentioned problems and achieve the object, the present invention is an information processing system including a mobile terminal and an electronic device that communicates between the mobile terminal, and the mobile terminal is a living body. The electronic device includes a biometric information acquisition unit that acquires biometric information generated based on the movement of the device and a transmission unit that transmits the biometric information, and the electronic device receives the biometric information transmitted from the mobile terminal. When displaying the analysis result of the receiving unit, the analysis unit that performs a predetermined analysis process based on the received biometric information, and the analysis result of the analysis unit on the display unit, the user who generated the biometric information logged in. It is provided with a display control unit that displays and controls the analysis result when logging out from the electronic device .

According to the present invention, it is possible to more accurately determine the health condition of the user and notify the user at an appropriate timing.

FIG. 1 is a diagram showing a system configuration of the information processing system of the first embodiment. FIG. 2 is a block diagram of a wristwatch-type terminal of the information processing system of the first embodiment. FIG. 3 is a functional block diagram showing a software configuration of a wristwatch-type terminal. FIG. 4 is a block diagram of the MFP of the first embodiment. FIG. 5 is a functional block diagram for explaining the software configuration of the MFP. FIG. 6 is a flowchart showing the flow of operation of the wristwatch-type terminal in the information processing system of the first embodiment. FIG. 7 is a flowchart showing a flow of operation of the MFP in the information processing system of the first embodiment. FIG. 8 is a diagram showing an example of biological information stored in a biological DB provided in the MFP in the information processing system of the first embodiment. FIG. 9 is a diagram showing an example of user information stored in the biological DB. FIG. 10 is a diagram showing a system configuration of the information processing system of the second embodiment. FIG. 11 is a block diagram of a server device provided in the information processing system of the second embodiment. FIG. 12 is a functional block diagram showing a software configuration of the server device. FIG. 13 is a flowchart showing the operation flow of the MFP of the information processing system of the second embodiment. FIG. 14 is a flowchart showing the operation flow of the server device of the information processing system of the second embodiment. FIG. 15 is a diagram showing biological information stored in a biological DB provided in the information processing system of the third embodiment. FIG. 16 is a diagram showing user information stored in a biological DB provided in the information processing system of the third embodiment. FIG. 17 is a diagram showing user information stored in a biological DB provided in the information processing system of the fourth embodiment. FIG. 18 is a block diagram of a wristwatch-type terminal 1 provided in the information processing system of the fifth embodiment. FIG. 19 is a sequence diagram for explaining the operation of each part of the information processing system according to the fifth embodiment. FIG. 20 is a diagram showing an example of a display image in the information processing system according to the fifth embodiment.

Hereinafter, as an example, an information processing system in which biometric information measured by a mobile terminal is received by a multifunction device (MFP: Multifunction Peripheral) and analyzed, and the analysis result is provided to a user at an enemy timing will be described.

(First Embodiment)
(System configuration)
FIG. 1 is a system configuration diagram of an information processing system according to the first embodiment. As shown in FIG. 1, the information processing system of the first embodiment includes a wristwatch-type terminal 1, an MFP 2, and a wireless LAN (Local Area Network) access point device 3. The wristwatch type terminal 1 is an example of a mobile terminal. MFP2 is an example of an electronic device. A plurality of wristwatch-type terminals 1 and MFP 2 may be provided.

As an example, the wristwatch-type terminal 1 and the MFP 2 are capable of direct communication by BLE (Bluetooth (registered trademark) Low Energy) and LAN communication via a wireless LAN access point device 3. Wireless communication compliant with Wi-Fi (registered trademark) standards such as IEEE (Institute of Electrical and Electronics Engineers) 802.11b is performed between the wristwatch type terminal 1 and the access point device 3 of the wireless LAN. Further, the MFP 2 and the wireless LAN access point device 3 are connected to Ethernet (registered trademark), and perform communication using a communication protocol conforming to the IEEE802.3 standard.

(Hardware configuration of wristwatch type terminal)
FIG. 2 is a block diagram showing a hardware configuration of a wristwatch-type terminal 1. As shown in FIG. 2, the wristwatch-type terminal 1 has an operation unit 9. It has a central processing unit (CPU) 10, a main memory 12, a flash memory 13, a first communication unit 14, a second communication unit 16, a display unit 18, and a biometric measurement unit 19.

The CPU 10 executes an OS (Operating System) stored in the flash memory 13. Further, the CPU 10 periodically or randomly generates biological information based on the movement of the user as a living body, such as a blood pressure value, a pulse rate, and a walking step count, by executing an information processing program as described later. It measures at the time and controls transmission to MFP2. As the main memory 12, for example, a DRAM (Dynamic Random Access Memory) is provided. The main memory 12 is used as a work area of the CPU 10, and temporarily stores biometric information and the like to be transmitted to the MFP 2. The flash memory 13 stores data necessary for system startup when the power is turned on, various programs for realizing the functions of the wristwatch-type terminal 1, and various information processing.

The first communication unit 14 is a communication unit that performs BLE communication, and performs wireless communication with the MFP 2 via the antenna 15 based on a wireless communication protocol compliant with the BLE standard. The second communication unit 16 is a communication unit that performs Wi-Fi (registered trademark) communication, and is, for example, a wireless LAN access point via an antenna 17 based on a wireless communication protocol compliant with the IEEE802.11b standard. Wireless communication is performed with the device 3.

The display unit 18 has, for example, an LCD (Liquid Crystal Display), an organic EL (Electro-Luminescence), or the like, and displays measured biological information, a predetermined message, or the like. When the wristwatch-type terminal 1 is attached to the user's wrist, the biometric measurement unit 19 has a pressure sensor provided so as to be located on the artery, a pressure sensor that pressurizes the pressure sensor and presses it against the artery, and an acceleration. It has a sensor. Further, the wristwatch-type terminal 1 has a measurement control unit (reference numeral 51 in FIG. 3) for calculating the user's systolic blood pressure, diastolic blood pressure, and pulse rate based on the vibration of the artery detected by the pressure sensor. There is. Further, the measurement control unit calculates the number of steps taken by the user based on the sensor output of the acceleration sensor, and also calculates the amount of exercise (many, medium, low, calories burned, etc.) corresponding to the number of steps taken by the user.

The wristwatch-type terminal 1 normally functions as a wristwatch and displays the current time and the like. Further, the wristwatch-type terminal 1 measures the biometric information of the user when designated by the user or designated by the MFP2, and transmits the biometric information to the MFP2.

(Software configuration of wristwatch type terminal)
FIG. 3 shows a functional block diagram of the software configuration of the wristwatch-type terminal 1. The CPU 10 shown in FIG. 2 realizes each function shown in FIG. 3 by executing an information processing program stored in the flash memory 13. Specifically, the CPU 10 is based on a first communication control unit 50 (an example of a transmission unit) that performs BLE communication by executing an information processing program, and an arterial vibration detected by the above-mentioned pressure sensor. Further, each function of the measurement control unit 51 (an example of the biological information acquisition unit) for calculating the user's systolic blood pressure, diastolic blood pressure, and pulse rate is realized.

Further, the CPU 10 functions as a measurement control unit 51 to calculate the number of steps taken by the user based on the sensor output of the acceleration sensor, and also to calculate the amount of exercise (calories burned, etc.) corresponding to the number of steps taken by the user. Calculate. Further, the CPU 10 executes the information processing program to transmit the measured biometric information and a predetermined message to the second communication unit 52 that performs Wi-Fi (registered trademark) communication and the display unit 18. Each function of the display control unit 53 to be displayed is realized.

Further, the operation unit 9 is a software key or a hardware key. By touching or pushing down the operation unit 9, the user instructs the wristwatch-type terminal 1 to perform an operation of measuring biometric information, an operation of transmitting the measured biometric information, and the like. By executing the information processing program, the CPU 10 realizes an operation processing unit 54 that processes such a user's input operation performed via the operation unit 9. Further, the CPU 10 realizes a storage control unit 55 that stores and controls the measured biological information in the main memory 12 or the flash memory 13 by executing an information processing program.

In this example, the first communication control unit 50 to the memory control unit 55 are realized by software, but a part or all of the first communication control unit 50 to the memory control unit 55 is IC. It may be realized by hardware such as (Integrated Circuit).

Further, the information processing program that realizes each function of the first communication control unit 50 to the storage control unit 55 in the CPU 10 is a file in an installable format or an executable format, such as a CD-ROM or a flexible disk (FD). It may be recorded and provided on a recording medium readable by a computer device. Further, it may be recorded and provided on a recording medium readable by a computer device such as a CD-R, a DVD (Digital Versatile Disk), a Blu-ray Disc (registered trademark), or a semiconductor memory. Further, the information processing program may be provided in the form of being installed via a network such as the Internet. Further, the information processing program may be provided by incorporating it into a ROM or the like in the device in advance.

(Hardware configuration of MFP)
Next, FIG. 4 is a block diagram showing a hardware configuration of the MFP 2. As shown in FIG. 4, the MFP 2 includes a CPU 60, a main memory 61, a flash memory 62, a bus controller 64, a PCI (Peripheral Component Interconnect) bridge 65, a cache memory 66, a scanner unit 70, and a print unit 72. .. Further, the MFP 2 includes a hard disk drive 74, a wired LAN communication unit 75, a LAN interface (LANI / F) 76, a first communication unit 77, a second communication unit 87, a hard key 80, a touch panel 82, and an RTC (Real). It has a Time Clock) 83. Further, the MFP 2 has a reader / writer 89. The reader / writer 89 reads the employee information, the user name, the authentication information of the department to which the IC card 100 is stored, and the like.

The CPU 60 executes an OS stored in a storage unit such as a flash memory 62 and performs predetermined information processing. Further, the CPU 60 performs a health check of the user based on the biometric information acquired from the wristwatch type terminal 1 by executing the information processing program stored in the flash memory 62, and notifies the user of the check result at a predetermined timing. do.

As the main memory 61 of the MFP 2, for example, a DRAM is provided and used in the work area of the CPU 60 or the like. The flash memory 62 is a non-volatile memory in which data is not erased even when the power is turned off, and various programs for starting the system when the power is turned on and realizing the functions of the MFP 2 are stored. Further, the flash memory 62 also stores data such as switches and parameters referred to when the program is executed.

The bus controller 64 controls data transfer between the CPU bus 84 and the bus 86. The PCI bridge 65 uses the cache memory 66 to transfer data between the PCI bus 85 and the CPU 60. For example, the cache memory 66, which is a DRAM, is used by the PCI bridge 65. The scanner unit 70 reads a paper image with a color CCD line sensor using, for example, a one-dimensionally arranged LED (Light Emitting Diode) array as a light source. Then, the image data obtained by digitizing each of the R (red), G (green), and B (blue) analog image signals output from the color CCD (Charge Coupled Device) line sensor is generated. Further, the scanner unit 70 generates image data of a color difference component (Cb, Cr) and image data of a brightness component (Y) based on each image data of RGB, and conforms to, for example, JPEG (Joint Photographic Experts Group). Generates image data that has been compressed (encoded).

The print unit 72 prints a color image or a monochrome image on a paper surface using cyan, magenta, yellow, and black toners. The HDD 74 stores image data input from the scanner 70, image data received via a network (Ethernet (registered trademark)), and the like.

The wired LAN communication unit 75 executes, for example, a communication protocol conforming to the IEEE802.3 standard, and controls communication with other devices connected to Ethernet (registered trademark) via LANI / F76. The first communication unit 77 is a BLE communication unit, executes a wireless communication protocol compliant with the BLE standard, and performs wireless communication with other devices via the antenna 78. The second communication unit 87 is a Wi-Fi (registered trademark) communication unit, for example, executes a wireless communication protocol compliant with the IEEE802.11b standard, and wirelessly communicates with other devices via the antenna 88. I do.

The hard key 80 is an input button physically provided on the operation unit of the MFP 2, the housing, or the like. As an example, the touch panel 82 is a capacitive touch panel in which a transparent conductive film formed of a transparent electrode or the like is laminated on an LCD display unit. On the touch panel 82, the result of the user's health check is displayed by the CPU 60, for example, at the timing when the user logs in to the MFP 2, the timing of attendance and departure, and the like. The RTC83 is a date clock, backed up by a battery (not shown), and measures the current time.

(Software configuration of MFP)
FIG. 5 is a functional block diagram showing a software configuration of the MFP 2. The CPU 60 of the MFP 2 executes an information processing program stored in the flash memory 62 to execute a first communication control unit 90 (an example of a reception unit), an input processing unit 91, and a wired LAN communication control unit 92 (electronic device communication). (Example), display control unit 93, analysis unit 94, user authentication unit 95, storage control unit 96, and second communication control unit 97 are realized.

The first communication control unit 90 is a BLE communication control unit, and controls the BLE communication of the first communication unit 77 shown in FIG. The input processing unit 91 detects the contact operation position of the touch panel 82. The wired LAN communication control unit 92 executes and controls the communication protocol conforming to the IEEE802.3 standard in the wired LAN communication unit 75. The analysis unit 94 performs a health check (analysis process) by comparing the biological information acquired from the user's wristwatch-type terminal 1 with the biological information of a healthy body. The display control unit 93 controls the display of the health check result (analysis result) of the analysis unit 94 on the touch panel 82 at a predetermined timing such as the timing when the user logs in to the MFP 2.

The storage control unit 96 stores and controls biometric information and the like received from each user's wristwatch-type terminal 1 in a storage unit such as the main memory 61, the flash memory 62, or the HDD 74. The second communication control unit 97 executes, for example, a wireless communication protocol conforming to the IEEE802.11b standard, and controls the communication of the second communication unit 87 that performs Wi-Fi (registered trademark) communication.

(Detection operation and transmission operation of biometric information in a wristwatch-type terminal)
Next, the operation of detecting the biometric information of the user by the wristwatch type terminal 1 and transmitting it to the MFP 2 will be described with reference to the flowchart of FIG. First, the user registers the user information in the wristwatch-type terminal 1 and the MFP 2 before detecting the biometric information. Specifically, at the timing when the information processing program is first started in the wristwatch-type terminal 1, the display control unit 53 of the wristwatch-type terminal 1 shown in FIG. 2 has, for example, a user name, age, gender, height, weight, and affiliation. Display the user information input screen such as department and medical history.

When the user inputs the user information via the operation unit 9, the storage control unit 96 stores and controls the input user information in the storage unit such as the flash memory 12. Further, the first communication control unit 90 establishes a BLE communication line with the MFP 2 and transmits the user information input from the user to the MFP 2. The storage control unit 96 of the MFP 2 stores and controls the user information received from the user's watch-type terminal 1 in a biological information database (biological DB) stored in a storage unit such as a flash memory 62. As a result, the user information of each user is collectively stored in the biological DB of the MFP2. In step S1 of the flowchart of FIG. 6, the display control unit 53 determines whether or not such registration of user information has been completed for the wristwatch-type terminal 1 and the MFP 2. Then, when it is determined that the registration of the user information is completed (step S1: Yes), the process proceeds to step S2.

The user operates the operation unit 9 of the wristwatch-type terminal 1 to give an instruction to acquire biometric information at a predetermined time such as when he / she arrives at the office in the morning or at lunch break. In step S2, the operation processing unit 54 determines whether or not such an instruction to acquire biometric information has been detected. Then, the process proceeds to step S3 at the timing when the operation processing unit 54 detects the instruction to acquire the biological information.

In step S3, the measurement control unit 51 acquires the biometric information of the user and stores it in a storage unit such as the flash memory 12. Specifically, when the wristwatch-type terminal 1 is correctly attached to the user's arm, the pressure sensor is positioned on the user's artery. In this state, the measurement control unit 51 controls the pressurizing mechanism so that the pressurized pressure sensor is pressed against the artery. The pressure sensor detects the frequency of the artery at a predetermined time during pressurization. The measurement control unit 51 calculates the user's systolic blood pressure, diastolic blood pressure, and pulse rate based on the frequency of the artery detected by the pressure sensor. The storage control unit 55 stores the calculated systolic blood pressure value, diastolic blood pressure value, and pulse rate value in a storage unit such as a flash memory 12 together with date and time information indicating the calculated date and time.

Further, the acceleration sensor provided in the wristwatch type terminal 1 outputs a sensor output each time the user walks. The measurement control unit 51 integrates the number of sensor outputs output from the acceleration sensor after the reset operation performed by the user via the operation unit 9. As a result, the number of steps taken by the user after the reset operation is accumulated. The measurement control unit 51 acquires the integrated number of sensor outputs when the instruction to acquire the biological information is detected. The storage control unit 55 stores the acquired sensor output number in the storage unit together with the above-mentioned blood pressure value and the like as step count information indicating the number of steps taken by the user when the acquisition instruction of the biological information is given.

Further, when the measurement control unit 51 acquires the number of sensor outputs when the instruction to acquire the biological information is detected, the measurement control unit 51 determines the amount of exercise of the user based on the comparison result with a predetermined threshold value, and determines the height, weight and number of steps. Calculate calories burned based on this. That is, the measurement control unit 51 has a first threshold value and a second threshold value (first threshold value> second threshold value), and when the number of sensor outputs is equal to or greater than the first threshold value, the amount of exercise is set to ". If the number of sensor outputs is less than the first threshold value and is greater than or equal to the second threshold value, the amount of exercise is determined to be "medium", and if the number of sensor outputs is less than the second threshold value, the amount of exercise is "medium". It is judged as "small". Further, the measurement control unit 51 calculates the calorie consumption from the reset operation to the detection of the biometric information acquisition instruction based on the user's "body weight" and the number of sensor outputs (= number of steps). The storage control unit 55 stores the exercise amount information and the calorie consumption information indicating the exercise amount calculated in this way in a storage unit such as the flash memory 13.

When such information is stored in the storage unit, the display control unit 53 of the wristwatch-type terminal 1 transmits biometric information such as "Do you want to transmit biometric information?" To the display unit 18. Display a message asking if there is any. The user operates the operation unit 9 to instruct transmission or non-transmission of biometric information. In step S4 of the flowchart of FIG. 6, the operation processing unit 54 determines whether or not the user has instructed to transmit biometric information. When the operation processing unit 54 detects the biometric information transmission instruction (step S4: Yes), the first communication control unit 50 establishes a BLE communication line with the MFP 2 in step S5.

Here, in step S6, the measurement control unit 51 determines whether or not the biological information such as the blood pressure value, the amount of exercise information, and the calorie consumption information transmitted to the MFP 2 last time is stored in the storage unit. When it is determined that the biometric information transmitted to the MFP 2 last time is not stored in the storage unit, that is, when the biometric information is first transmitted to the MFP 2 (step S6: No), the first communication control unit In step S8, 50 transmits biological information such as blood pressure value, exercise amount information, and calorie consumption information stored in the storage unit to the MFP 2 by BLE communication. As a result, all the processing of the flowchart of FIG. 6 is completed.

On the other hand, when it is determined that the biometric information transmitted to the MFP 2 last time is stored in the storage unit (step S6: Yes), the measurement control unit 51 receives the biometric information transmitted last time in step S7. Calculate the difference in the biometric information transmitted this time. That is, the measurement control unit 51 calculates the difference between the previous blood pressure value and the current blood pressure value, the difference between the previous calorie consumption and the current calorie consumption, and the like. Then, using this difference information as the biological information of this time, the first communication control unit 50 transmits to the MFP 2 by BLE communication in step S8, and completes all the processing of the flowchart of FIG. By transmitting the difference between the previous biometric information and the current biometric information, the amount of data to be transmitted can be reduced, the communication speed can be increased, and the required storage capacity can be reduced.

(Analysis operation of biometric information in MFP)
Next, the operation of the MFP 2 that analyzes the biological information received from the wristwatch-type terminal 1 will be described with reference to the flowchart of FIG. 7. First, in step S11, the first communication control unit 90 shown in FIG. 5 determines whether or not biometric information has been received from the wristwatch-type terminal 1, which is an example of a wearable device. At the timing when the biometric information is received (step S11: Yes), the process proceeds to step S12.

In step S12, the storage control unit 96 stores and controls the biological information received from the wristwatch type terminal 1 in the biological information database (biological DB) stored in the storage unit such as the flash memory 62. Then, the analysis unit 94 performs a health check by comparing the biological information acquired from the wristwatch-type terminal 1 with the biological information of a healthy body.

Specifically, when the analysis unit 94 receives the biological information in the state of the previous difference from the wristwatch type terminal 1, the analysis unit 94 reflects the difference information in the previous biological information to obtain the current biological information (full data). Is regenerated and compared with the biological information of a healthy body. Further, when the analysis unit 94 receives the biometric information from the wristwatch type terminal 1 in the state of full data instead of the difference information (at the time of the first measurement of the biometric information), the biometric information received in the state of the full data and the health It is compared with the biological information of the body.

Then, the analysis unit 94 determines in step S13 whether or not there is an abnormal value. As an example, the analysis unit 94 considers an abnormality when the heart rate is 100 beats or more per minute as a result of comparing and processing the biological information received from the wristwatch type terminal 1 with the biological information of a healthy body. Further, the analysis unit 94 considers that the systolic blood pressure value is 135 mmHg or more as abnormal. Further, the analysis unit 94 considers it as abnormal when the systolic blood pressure value is 85 mmHg or more. Further, the analysis unit 94 determines the presence or absence of stress based on the heart rate and the blood pressure value. That is, the analysis unit 94 determines that there is stress when both the heart rate and the blood pressure value are rising, and determines that there is no stress in other cases. The memory control unit 55 stores and controls the information indicating the presence or absence of stress determined by the analysis unit 94 in the biological DB as a part of the biological information.

Next, when an abnormal value is detected in such a health check (step S13: Yes), the process proceeds to step S14, and the display control unit 93 notifies the user of the abnormality at the timing described below. Then, all the processing of the flowchart of FIG. 7 is completed. The display control unit 93 adds an icon indicating that a health abnormality has occurred to notify the abnormality. With this icon, the user can recognize the health abnormality at a glance.

On the other hand, when an abnormal value is not detected in the health check (step S13: No), the process proceeds to step S15, and the display control unit 93 notifies the user of normality at the timing described below. Then, all the processing of the flowchart of FIG. 7 is completed.

Here, the health check result such as the abnormality notification or the normal notification is highly confidential personal information. Therefore, it is preferable that the display control unit 93 displays the health check result on the touch panel 82 at a predetermined timing that can be visually recognized by the user who has generated the biometric information (at a timing that the user can see). As an example, the MFP 2 allows only a legitimate user to use the copy function, the scanner function, or the like. The user who uses the MFP 2 brings the IC card 100 shown in FIG. 4 close to the reader / writer 89 to perform user authentication. The reader / writer 89 reads information necessary for user authentication, such as a user name and an employee number, from the IC card 100.

The user authentication unit 95 shown in FIG. 5 performs user authentication processing by referring to the biometric DB based on the user name and employee number read from the IC card 100. The display control unit 93 displays the health check result on the touch panel 82 when the user authentication unit 95 authenticates that the user is a legitimate user registered in the biological DB. As a result, when the user operates his / her IC card 100 close to the card reader 89 of the MFP2, the user's health check result is displayed on the touch panel 82 of the MFP2 at the timing when the user is located in front of the MFP2. Can be displayed. Therefore, it is possible to prevent the inconvenience that the health check result is known to others, and it is possible to provide the user with the confidentiality.

The display control unit 93 displays the health check result of the user each time the user authentication indicating that the user is a legitimate user is performed. Therefore, every time the IC card 100 is brought close to the reader / writer 89 to perform user authentication, the user can confirm his / her health check result. Therefore, the user authenticates the user at a desired timing by bringing the IC card 100 close to the reader / writer 89 not only when using the MFP 2 but also at a desired timing such as when he / she arrives at the office or when he / she leaves the office. You can check the check result.

Further, in this example, when the user can be authenticated by the IC card 100, the MFP 2 determines to display the health check result of the user. However, the user authentication process may be performed based on predetermined information such as a user name and a password input by the user via the touch panel 82, and the health check result may be displayed to a legitimate user.

Further, when the administrator or the like operates the touch panel 82 of the MFP 2 to input the administrator code and specifies the display of the health check result, the user authentication unit 95 of the MFP 2 is based on the input administrator code. , Perform user authentication processing. Then, when it is authenticated that the administrator is a legitimate administrator, the display control unit 93 displays a list screen of the health check results of each user on the touch panel 82. As a result, the administrator can confirm the health check result of each user at a desired timing.

Alternatively, the administrator or the like accesses the Web browser of the MFP 2 via the Web browser of the personal computer device, inputs the administrator code, and then specifies the display of the health check result. When the storage control unit 55 of the MFP 2 is authenticated by the user authentication unit 95 as a legitimate administrator, the storage control unit 55 reads out the health check result of each user from the biological DB. The wired LAN communication control unit 92 transmits the read health check result to the Web browser of the personal computer device via the wired LAN. As a result, the administrator can view the health check result of each user stored in the MFP 2 via the personal computer device.

FIG. 8 shows an example of biological information stored in the biological DB, and FIG. 9 shows an example of user information stored in the biological DB. First, as can be seen from FIG. 8, the biological information received from each user's wristwatch-type terminal 1 is stored in the biological DB for each user and each date. FIG. 8 shows an example in which the maximum blood pressure value, the minimum blood pressure value, the heart rate, and the presence or absence of stress of the user A and the user B from January 10, 2017 to January 13, 2017 are memorized. That is, the example of FIG. 8 is an example of measuring the biometric information of the user once a day with the wristwatch type terminal 1 at a predetermined time. The display control unit 93 first displays the health check result of the current day on the touch panel 82, and when the user performs a date designation operation, the display control unit 93 displays the health check result of the designated date on the touch panel 82.

(Notification operation corresponding to individual differences)
Here, the blood pressure value, the heart rate, and the like have some individual differences. Therefore, as shown in FIG. 8, the analysis unit 94 keeps a history of biological information for each user and calculates an average value of biological information such as a blood pressure value and a heart rate. Then, the analysis unit 94 compares the biological information of this time with the biological information of a healthy body and the calculated average value. When the value of the biological information of this time is less than the value of the biological information of a healthy body or less than the calculated average value, the analysis unit 94 generates an analysis result indicating that no abnormality has occurred. Further, the analysis unit 94 generates an analysis result indicating that an abnormality has occurred when the value of the biological information this time is equal to or greater than the value of the biological information of a healthy body and equal to or greater than the calculated average value. do.

The display control unit 93 notifies "no abnormality" when an analysis result indicating that no abnormality has occurred is obtained, but when an analysis result indicating that an abnormality has occurred is obtained, for example, an emergency. A message or the like is displayed in a character color meaning urgent, and an icon meaning urgent is added to notify an abnormality. As a result, the user can recognize that the health abnormality has occurred and can take appropriate measures such as a break, going to the hospital, or returning home.

Further, when an analysis result indicating that an abnormality has occurred is obtained, the communication unit such as the wired LAN communication control unit 92 or the second communication control unit 97 has notified the administrator of the abnormality. Notify the information indicating the user. As a result, the administrator can take appropriate measures such as urging the user who has been notified of the abnormality to take a break, go to the hospital, or return home.

(Predicted illness alert activation work)
On the other hand, FIG. 9 is a diagram showing an example of user information stored in the biological DB. The biological information shown in FIG. 8 and the user information shown in FIG. 9 are associated with each other and managed by the CPU 60. The user information shown in FIG. 9 is based on the information input by the user at the timing when the information processing program of the watch-type terminal 1 is first started as described above, the height and weight of the user, and the measurement control unit shown in FIG. The information indicates the body fat percentage calculated by 51 and the amount of exercise calculated based on the sensor output of the acceleration sensor of the user's watch-type terminal 1. Although it is an example, in the case of the example of FIG. 9, for user A, age: 38 years old, gender: male, height: 170 cm, weight 65 kg, body fat percentage: 22%, amount of exercise: low, department: accounting Department, medical history: User information such as duodenal ulcer is stored. Similarly, for User C, age: 28 years old, gender: female, height: 158 cm, weight: 42 kg, body fat percentage: 20%, amount of exercise: high, department: sales department, medical history: unequal user information. Is remembered. In other words, the generation DB stores user information indicating the age, gender, and physical characteristics of each user.

The analysis unit 94 of the MFP 2 collates the user information of the user who has analyzed the biological information with the user information of each user stored in the biological DB, and is the same for the user who has analyzed the biological information. Detect users who are similar in age and physical characteristics by gender. Then, the analysis unit 94 notifies the display control unit 93 of the information indicating the disease described in the medical history of the detected user. The concept of "illness" here is a broad concept that includes not only a state in which a mental or physical disorder or inconvenience has occurred, but also a syndrome, a disease, a disease, a fracture, and the like. The display control unit 93 provides the information indicating the disease notified from the analysis unit 94 to the user who has measured the biological information together with the health check result. Alternatively, the display control unit 93 generates a message or the like prompting the prevention of the disease notified from the analysis unit 94, and provides the user who has measured the biological information together with the health check result.

For example, the analysis unit 94 detects user D shown in FIG. 9 as a user of the same gender and similar age and physical characteristics to the user who measured the biological information, and the medical history of this user D is hypertension and hypertension. It is assumed that the blood glucose is described. In this case, the analysis unit 94 notifies the display control unit 93 of information indicating hypertension and hyperglycemia. The display control unit 93, together with the analysis result, displays hypertension and hyperglycemia as diseases that may develop in the future. or. The display control unit 93 sends a message urging the prevention of illnesses such as "Users of the same age and physique have the onset of hypertension and hyperglycemia. Avoid salt and exercise moderately." It is generated and provided to the user who measured the biometric information together with the health check result. As a result, the user can recognize the illness that may develop in the future together with the health check result, and can make efforts for prevention.

(Effect of the first embodiment)
As is clear from the above description, the information processing system of the first embodiment collects biological information such as a user's blood pressure value and heart rate by a wristwatch type terminal 1 and uploads it to the MFP 2. The MFP2 performs a health check of the user based on the uploaded biological information, and displays the health check result at the timing when the user is located in front of the MFP2. As a result, since the health check result is information generated by analyzing biological information such as the user's blood pressure value and heart rate, it is possible to accurately determine the user's health condition.

Further, the timing of displaying the health check result is displayed at the timing when the user is close to the MFP 2. As a result, the inconvenience that the health check result is seen by others can be prevented, and the health check result can be provided to the user in a state of maintaining the confidentiality.

In addition, the average value of the biological information is calculated based on the history of the biological information. If the current biological information shows an abnormal value in comparison with the biological information of a healthy body and also shows an abnormal value in comparison with the calculated average value, it is more important than the normal abnormality notification. Anomalous notification that means As a result, it is possible to give a notification corresponding to individual differences in biometric information.

In addition, user information indicating age, physique, and medical history is stored for each user, and when providing health check results, a notification urging prevention of illness described in the medical history of users with similar age and physique. I do. As a result, each user can be alerted to a disease that may develop in the future, and the disease can be prevented.

(Second embodiment)
Next, the information processing system of the second embodiment will be described. The first embodiment was an example of collecting and analyzing biometric information on the MFP2 side. On the other hand, in the second embodiment, the MFP 2 transfers the biological information to the server device, the server device collects and analyzes the biological information, and the health check result is transmitted to the MFP 2 and displayed. This is an example. It should be noted that only this point is different between the first embodiment and the second embodiment. Therefore, in the following, only the difference between the two will be explained, and the duplicate explanation will be omitted.

(System configuration)
FIG. 10 is a system configuration diagram of the information processing system of the second embodiment. As shown in FIG. 2, in the case of the information processing system of the second embodiment, the wristwatch type terminal 1, the MFP 2, and the access point device 3 have a server device 4 connected to Ethernet (registered trademark). There is.

FIG. 11 is a block diagram showing a hardware configuration of the server device 4. As shown in FIG. 11, the server device 4 has a CPU 110, a main memory 111, a flash memory 112, and a wired LAN communication unit 113. In addition to the OS, an information processing program for collecting and analyzing the above-mentioned biometric information is stored in a storage unit such as the main memory 111 or the flash memory 112. Further, in the storage unit such as the main memory 111 or the flash memory 112, the biological information of each user shown in FIG. 8 and the biological DB in which the user information of each user shown in FIG. 9 is stored are stored. ..

FIG. 12 is a functional block diagram of each function realized by the CPU 110 of the server device 4 executing an information processing program. As shown in FIG. 12, when the CPU 110 executes an information processing program, the wired LAN communication control unit 121 (an example of a server communication unit), the analysis unit 122 (an example of a server analysis unit), and the storage control unit 110 Functions as. As described above, some or all of the wired LAN communication control unit 121 to the storage control unit 110, which are to be realized by software, may be realized by hardware.

(Operation of MFP)
FIG. 13 is a flowchart showing the operation of the MFP 2 in the second embodiment. In this flowchart, in step S21, the first communication control unit 90 shown in FIG. 5 determines whether or not biometric information has been received from the wristwatch-type terminal 1 which is an example of a wearable device. The process proceeds to step S22 at the timing when the biological information is received from the wristwatch type terminal 1.

In step S22, the wired LAN communication control unit 92 controls the communication of the wired LAN communication unit 75 and transfers the biometric information received from the wristwatch-type terminal 1 to the server device 4. As will be described later, in the server device 4, the storage control unit 110 shown in FIG. 12 is transferred from the MFP 2 to the biological DB stored in the storage unit to store and control the biological information. As a result, a history of biometric information of each user is formed in the biometric DB of the server device 4, as described with reference to FIG. As described above, the biological DB of the server device 4 also stores the user information of each user described with reference to FIG. 9.

Further, in the server device 4, the analysis unit 122 analyzes the biometric information, and the wired LAN communication control unit 121 transmits the health check result, which is the analysis result, to the MFP 2. When the analysis unit 122 compares the biometric information of the user with the biometric information of a healthy body and detects an abnormal value as a result of comparing with the above-mentioned average value, the degree of abnormality (large, medium and small) is displayed in the health check result. ) Is added and transmitted to the MFP2. In step S23 of FIG. 13, the wired LAN communication control unit 92 of the MFP 2 receives the health check result, which is the analysis result from the server device 4, via the wired LAN communication unit 75.

In step S24, the display control unit 93 of the MFP 2 shown in FIG. 5 determines whether or not information indicating the degree of abnormality is added to the health check result, thereby determining whether or not an abnormal value exists in the health check result. To determine. When an abnormal value exists (step S24: Yes), the display control unit 93 displays the health check result on the touch panel at the above timing in step S25 according to the degree of abnormality (large, medium, small). Is displayed, and all the processing of the flowchart of FIG. 13 is completed.

On the other hand, when there is no abnormal value (step S24: No), the display control unit 93 gives a notification in step S26 indicating that the health state is normal (good) together with the health check result, and FIG. 13 Ends all processing of the flowchart of.

(Operation of server device)
Next, the operation of the server device 4 will be described with reference to the flowchart of FIG. First, in step S31, it is determined whether or not the wired LAN communication control unit 121 of the server device 4 shown in FIG. 12 has received the biometric information from the MFP 2 via the wired LAN communication unit 113 shown in FIG. Upon receiving the biological information from the MFP 2, the process proceeds to step S32.

In step S32, the analysis unit 122 shown in FIG. 12 performs the above-mentioned health check (analysis process) such as comparing the biological information received from the MFP 2 with the biological information of a healthy body. In step S33, the storage control unit 123 stores the health check result (analysis result) in the storage unit. Further, the wired LAN communication control unit 121 transmits the health check result (analysis result) to the MFP 2 via the wired LAN communication unit 113. As described above, the health check result includes information such as blood pressure value, heart rate, presence / absence of stress, and illness that is predicted to develop in the future.

The MFP 2 stores the health check result received from the server device 4 in a storage unit such as a flash memory 62. Then, the MFP 2 displays to the user via the touch panel 82 or the like at a predetermined timing such as the timing when the user logs in to the MFP 2. Alternatively, the MFP 2 provides the health check result to the administrator or the like via a network such as a wired LAN.

The MFP 2 may temporarily store the health check result received from the server device 4 in the storage unit, or may store it in the above-mentioned biological DB provided in the storage unit for a long period of time. good.

(Effect of the second embodiment)
In the information processing system of the second embodiment as described above, the server device 4 performs the analysis processing of the biological information. Therefore, the load of the analysis process of the MFP 2 can be significantly reduced, and the same effect as that of the first embodiment described above can be obtained.

(Third embodiment)
Next, the information processing system of the third embodiment will be described. Each of the above-described embodiments is an example in which biometric information is measured once a day and a health check result is provided. On the other hand, the information processing system of the third embodiment measures biometric information at predetermined time intervals such as 10 minutes or 1 hour, and provides a health check result at a predetermined timing. Is. It should be noted that only this point is different between each of the above-described embodiments and the third embodiment. Therefore, in the following, only the difference between the two will be explained, and the duplicate explanation will be omitted.

(Structure and operation of the third embodiment)
In the case of the information processing system of the third embodiment, the wristwatch-type terminal 1 measures biometric information at predetermined time intervals, for example, 10 minutes or 1 hour, and transmits the biometric information to the MFP 2. The MFP 2 or the server device 4 (when transferring the biological information from the MFP 2 to the server device 4) sequentially stores the transferred biological information in the biological DB. Hereinafter, the description will proceed assuming that the biological DB is provided in the MFP 2. When the server device 4 is provided with the biological DB, the same operation is performed, so refer to the following description.

FIG. 15 shows an example of biological information stored in the biological DB. The MFP 2 stores the biological information transmitted from the wristwatch-type terminal 1 in the biological DB at predetermined time intervals, so that the history of the biological information is formed in the biological DB for each user. The example of FIG. 15 is an example in which the biometric information of User A from 9:00 am to 19:05 pm on January 10, 2017 is stored.

Further, the example of FIG. 15 is an example in which the biometric information of the user B from 9:30 am to 16:15 pm on January 10, 2017 is stored. As shown in this example, the biological information indicates the minimum blood pressure value, the maximum blood pressure value, the heart rate, and the presence or absence of stress detected based on the blood pressure value and the heart rate as described above for each measurement time. The information is stored in the biological DB.

The analysis unit 94 of the MFP 2 detects the diastolic blood pressure value with the largest number of measurements as the basic diastolic blood pressure value among the diastolic blood pressure values stored in the biological DB for each user, and the storage control unit 96 stores the diastolic blood pressure value in the biological DB. Control. Similarly, the analysis unit 94 detects the hypertension value with the largest number of measurements as the basic hypertension value among the systolic blood pressure values for each user, and the memory control unit 96 stores and controls the memory in the biological DB. Similarly, the analysis unit 94 detects the heart rate with the highest number of measurements as the basic heart rate among the heart rates of each user, and the memory control unit 96 stores and controls the memory in the biological DB.

Such a basal diastolic blood pressure value, a basal systolic blood pressure value, and a basal heart rate are stored in a biological DB as shown in FIG. 16 as a part of biological information of each user. In the case of the example of FIG. 16, the value of 71 mHg as the basic diastolic blood pressure value (bottom) of the user A, the value of 112 mHg as the basic systolic blood pressure value (top), and the value of 61 times as the basic heart rate are the biological DBs, respectively. It is remembered in.

Further, in the case of the information processing system of the third embodiment, the threshold value for determining the abnormality of blood pressure and heart rate can be arbitrarily set by a user, an administrator, a healthcare expert, or the like. Further, in the case of the information processing system of the third embodiment, it is possible to set the number of times the abnormal blood pressure value or the abnormal heart rate is detected (the number of times the warning is started) until the abnormal warning is given. Further, in the case of the information processing system of the third embodiment, it is possible to set the timing of the abnormal warning to be performed when the abnormal blood pressure value or the abnormal heart rate is detected more than the set number of times.

Specifically, in the case of user A shown in FIG. 16, a heart rate of + 20% or more of the basic heart rate and a heart rate of -20% or less of the basic heart rate are set to be detected as abnormal heart rates (). ± 20% of basic heart rate). Further, in the case of user A, the systolic hypertension value of + 20% or more of the basal systolic blood pressure and the systolic blood pressure value of -20% or less of the basal systolic hypertension value are set to be detected as abnormal systolic hypertension values (basic systolic hypertension). ± 20% of the value). Further, in the case of user A, the diastolic blood pressure value of + 10% or more of the basal diastolic blood pressure and the diastolic blood pressure value of -10% or less of the basal diastolic blood pressure value are set to be detected as abnormal diastolic blood pressure values (basic diastolic blood pressure). ± 10% of the value). Then, when such an abnormal heart rate or an abnormal blood pressure value is measured "30 times" or more, it is set to warn the occurrence of the abnormal heart rate at the timing of the "leaving time" of the user A.

Therefore, in the case of the user A, the display control unit 93 leaves the company when any one or more of the abnormal heart rate, the abnormal systolic blood pressure value, and the abnormal diastolic blood pressure value is measured 30 times or more. At the timing, a warning message or the like indicating that the occurrence of an abnormal value has been measured is displayed on the touch panel 82. Similarly, in the case of the user B shown in FIG. 16, the display control unit 93 measures when any one or more of the abnormal heart rate, the abnormal systolic blood pressure value, and the abnormal diastolic blood pressure value is measured 10 times or more. At the timing of 3:00 pm, a warning message or the like indicating that the occurrence of an abnormal value has been measured is displayed on the touch panel 82.

The display control unit 93 displays a warning message or the like on the touch panel 82 as follows. In the case of user A, the user A logs in to the MFP 2 with his / her IC card 100 at the time of coming to work, and logs out of the MFP 2 with his / her IC card 100 at the time of leaving the office. When this logout operation is detected, the display control unit 93 displays a warning message or the like on the touch panel 82. As a result, when the user A is near the MFP2, a warning message or the like can be displayed. Alternatively, the touch panel 82 is provided with a leave button as a software key or the MFP 2 is provided with a leave button as a hardware key, and when the leave button is operated, the display control unit 93 displays a warning message or the like on the touch panel 82. As a result, when the user A is near the MFP2, a warning message or the like can be displayed.

Further, in the case of the user B who specifies the display timing of the warning message or the like as "3:00 pm", the user B moves to the front of the MFP 2 at 3:00 pm. The display control unit 93 displays a warning message or the like on the touch panel 82 at the timing when 3:00 pm is detected. As a result, a warning message or the like can be displayed on the touch panel 82 at the timing when the user B moves in front of the MFP 2. Alternatively, at 3:00 pm, the user B moves in front of the MFP 2 and performs a login operation with his / her IC card 100. The display control unit 93 displays a warning message or the like on the touch panel 82 when the login of the user B is detected around 3:00 pm (for example, between 2:50 pm and 3:10 pm). As a result, a warning message or the like can be displayed at the time specified by the user B and when the user B is near the MFP2.

(Effect of the third embodiment)
As described above, the information processing system of the third embodiment can measure biometric information at predetermined time intervals and provide health check results at predetermined timings. As a result, the health check result generated by analyzing the biological information in more detail can be safely provided at the timing desired by the user, and the same effect as that of each of the above-described embodiments can be obtained.

(Fourth Embodiment)
Next, the information processing system of the fourth embodiment will be described. In the first embodiment described above, an example in which a message urging the prevention of a disease that has been developed by a user having similar age and physical characteristics is provided to a user who has measured biometric information together with a health check result. Explained. Corresponding to such a modification of the first embodiment is the fourth embodiment described below. In addition, in order to avoid duplicate explanations, the following description of the fourth embodiment will only explain the differences between the above-mentioned embodiments.

(Operation of the fourth embodiment)
FIG. 17 shows an example of user information stored in the biological DB of the MFP 2 (or the server device 4) of the information processing system of the fourth embodiment. In the case of the example of FIG. 17, Mr. A having a user ID of 12345 is 40 years old, has a male gender, is 180 cm tall, and weighs 70 kg, and has detected 100 abnormal heartbeats per day. The number of abnormal blood pressures 10 times a day is detected. And Mr. A has suffered from illness A and illness B in the past. Similarly, Mr. B, whose user ID is 54321, is 35 years old, has a male gender, is 170 cm tall, and weighs 85 kg. The number of abnormal blood pressures has been detected. And Mr. B has suffered from illness A and illness C in the past.

In the case of the fourth embodiment, the analysis unit 94 of the MFP 2 (or the analysis unit 122 of the server device 4) has information on the combination of each disease and each parameter based on the user information of each user stored in the biological DB. To form. That is, in the case of the example of FIG. 17, the analysis unit 94 has [age 40 years old, illness A], [gender man, illness A], [height 180 cm, illness A], [weight] based on the user information of Mr. A. 70 kg, illness A], [heart rate abnormality 100 times, illness A], [blood pressure abnormality 10 times, illness A] to form combination information. Further, in the case of the example of FIG. 17, the analysis unit 94 has [age 40 years old, illness B], [gender man, illness B], [height 180 cm, illness B], [weight] based on the user information of Mr. A. 70 kg, illness B], [heartbeat abnormality 100 times, illness B], [blood pressure abnormality 10 times, illness B] to form combination information.

Further, in the case of the example of FIG. 17, the analysis unit 94 has [age 35 years old, illness A], [gender man, illness A], [height 170 cm, illness A], [weight] based on the user information of Mr. B. It forms combination information with 85 kg, illness A], [heartbeat abnormality 100 times, illness A], [blood pressure abnormality 15 times, illness A]. Further, in the case of the example of FIG. 17, the analysis unit 94 has [age 35 years old, illness C], [gender man, illness C], [height 170 cm, illness C], [weight] based on the user information of Mr. B. It forms combination information with 85 kg, illness C], [heartbeat abnormality 100 times, illness C], [blood pressure abnormality 15 times, illness C].

Next, the analysis unit 94 detects the combination information of each combination in descending order of the number. In the case of the above example, the combination information of [heart rate abnormality 100 times, illness A] is detected as the combination information of the most numerous combinations, and subsequently, as the combination information of the most numerous combinations, [gender man, illness A]. ] Combination information is detected.

Here, the detection result of such combination information is a detection result based on the user information of two users, user A and user B, but the combination information of each combination is detected based on the user information of more users. Then, in addition to the combination of [heart rate abnormality 100 times, disease A], the combination information of the combination such as [heart rate abnormality 101 times, disease A] and [heart rate abnormality 110 times, disease A] is also detected.

The analysis unit 94 identifies the cause of the disease and the disease to be affected by statistically determining such a detection result. In the case of the example of FIG. 17, since the most common combination is [heart rate abnormality 100 times, illness A], the analysis unit 94 determines that "the more heartbeat abnormalities, the more susceptible to illness A", and the heartbeat abnormality. The display control unit 93 is notified of information indicating that the illness that the user with a large number of times is likely to suffer from is illness A. The display control unit 93 provides the information indicating the disease notified from the analysis unit 94 to the user who has measured the biological information together with the health check result. Alternatively, the display control unit 93 generates a message or the like prompting the prevention of the disease notified from the analysis unit 94, and provides the user who has measured the biological information together with the health check result.

(Effect of the fourth embodiment)
As a result, it is possible to encourage the user to prevent diseases that are likely to occur in the future, and it is possible to obtain the same effects as those of the above-described embodiments.

(Fifth Embodiment)
Next, the information processing system of the fifth embodiment will be described. In the description of each of the above-described embodiments, the health check result is mainly displayed on the touch panel 82 of the MFP 2. The fifth embodiment is an example in which the server device transmits and displays the health check result generated based on the biological information collected from the wristwatch-type terminal 1 to the user's wristwatch-type terminal 1 via the MFP 2. be. In order to avoid duplicate explanations, the following fifth embodiment will be described only with respect to the differences between the above-described embodiments.

(Operation of the fifth embodiment)
(Health check result generation operation)
FIG. 18 shows a sequence diagram of the information processing system according to the fifth embodiment. In the sequence diagram of FIG. 18, steps S41 to S46 show the operation until the server device 4 generates and saves the health check result based on the collected biological information of the user.

Specifically, the user's wristwatch-type terminal 1 collects biometric information at regular or random times in step S41. As an example, for this collection of biometric information, a BLT communication line between the wristwatch type terminal 1 and the MFP 2 is always established. Then, when the wristwatch-type terminal 1 is located near the MFP2, the MFP2 requests the wristwatch-type terminal 1 to transmit biometric information. In step S42, the first communication control unit 50 and the first communication unit 14 of the wristwatch-type terminal 1 transmit biometric information together with the user ID and the like to the MFP 2 by BLE communication. In step S43, the MFP 2 stores the biometric information, the user ID, and the like transmitted from the wristwatch-type terminal 1 by BLE communication in a storage unit such as a flash memory 62 or an HDD 74.

The BLT communication line may be established at predetermined time intervals or at random. In other words, the wristwatch-type terminal 1 and the MFP 2 may be connected continuously (always) or intermittently by a predetermined communication line such as a BLT communication line. Further, the wristwatch-type terminal 1 decides to transmit the biological information to the MFP 2 in response to the transmission request from the MFP 2, but when the wristwatch-type terminal 1 is located near the MFP 2, the wristwatch-type terminal 1 voluntarily transmits the biometric information. Biological information or the like may be transmitted to the MFP 2.

Further, when the wristwatch-type terminal 1 touches the reader / writer 89 of the MFP 2 to transmit the authentication information such as the user ID to the MFP 2 during the print process or the scan process, and the user authentication is successful (after). In addition, the wristwatch-type terminal 1 that has received the response of the successful authentication may automatically transmit the biometric information to the MFP 2.

For example, the wired LAN communication unit 75 and the wired LAN communication control unit 92 of the MFP 2 store the biometric information of the user stored in the storage unit in this way at a periodic or random time in step S44, such as a user ID (employee number). Is transmitted to the server device 11. In addition to the wired LAN, the MFP 2 may transmit to the server device 4 in another communication form such as a wireless LAN or Wi-Fi (registered trademark) communication.

The analysis unit 122 of the server device 4 collates the received biometric information with the biometric information indicating a normal value as a sample, and the storage control unit 123 stores and controls the collation result as a health check result in the main memory 111. The biological information collected by the wristwatch-type terminal 1 in this way is stored in the server device 4 at the above-mentioned timing.

Next, in the case of the information processing system of the fifth embodiment, as shown in FIG. 18, the wristwatch type terminal 1 has a third communication unit 131 which is a non-contact wireless communication unit having a communication distance of, for example, about 30 cm. I have. Although it is an example, NFC (Near Field Communication) or the like can be used as the non-contact wireless communication unit.

Further, in the case of the information processing system of the fifth embodiment, the display control unit 93 of the MFP 2 touches the reader / writer 89 such as "Please touch the employee ID card or the wearable device" as shown in FIG. The display screen displaying the message prompting the operation is displayed on the touch operation panel 82 as the default screen G1.

For example, when going to work or leaving the office, the user touch-operates the reader / writer 89 of the MFP 2 with the IC card 100 or the wristwatch-type terminal 1 as shown in step S47. When this touch operation is performed, the reader / writer 89 reads out information such as a user ID (employee number) by performing non-contact wireless communication with the IC card 100 or the wristwatch type terminal 1, and goes to work as shown in step S48. It is stored in a storage unit such as the main memory 61 together with the time or the time of leaving work.

(When the health condition is normal)
Next, in step S49, the wired LAN communication control unit 92 of the MFP 2 transmits the user ID (employee number) acquired from the IC card 100 or the wristwatch-type terminal 1 to the server device 4, and requests the acquisition of the health check result. conduct. The storage control unit 123 of the server device 4 reads the health check result corresponding to the user ID (employee number) received from the MFP 2 from the storage unit. The wired LAN communication unit 121 of the server device 4 transmits the health check result read from the storage unit to the MFP 2 in step S50. The MFP 2 BLE transmits the health check result received from the server device 4 to the wristwatch-type terminal 1 via, for example, the first communication unit 77 in step S51.

As an example, health status information indicating normal or abnormal health status is added to the health check result transmitted from the server device 4 to the MFP 2. The display control unit 53 of the wristwatch-type terminal 1 determines the health state (normal or abnormal) of the user based on the health state information added to the health check result. When it is determined that the health condition of the user is normal, the display control unit 53 of the wristwatch type terminal 1 determines the user ID (employee number), name, and status (attendance, attendance, as shown in the display image G2 of FIG. 19). Various information indicating leaving work, vacation, etc.), attendance time, and health condition (normal in this case) is displayed and controlled on the display unit 18.

(If your health is abnormal)
On the other hand, when it is determined that the health condition of the user is abnormal, the display control unit 53 of the wristwatch type terminal 1 has a user ID (employee number), a name, and a status as shown in the display image G3 of FIG. (Attendance, leaving work, vacation, etc.), along with the attendance time, the character "abnormal" is displayed and controlled on the display unit 18 as information indicating the health condition.

In the case of the fifth embodiment, each user pre-registers a desired e-mail address to be a contact. This e-mail address is stored in a storage unit such as the HDD 74 of the MFP 2 and / or in a storage unit such as the main memory 12 of the wristwatch type terminal 1. When the e-mail address is stored in the storage unit such as the main memory 111 of the server device 4 and the "abnormal" health check result is transmitted, the wired LAN communication control unit 121 uses the MFP 2 or (and). , May be transmitted to the wristwatch type terminal 1.

The second communication control unit 52 (an example of the analysis result notification unit) of the wristwatch type terminal 1 is included in the health check result to the e-mail address stored in the storage unit such as the main memory 12 in step S52. Detailed information on the health condition is transmitted using WiFi communication. As a result, the detailed information of the health check is transmitted to, for example, the user's personal computer device, mobile terminal device, MFP2, wristwatch-type terminal 1, or the like according to the registered e-mail address.

(When touch operation is performed with an IC card)
Next, in the case of the fifth embodiment, when the reader / writer 89 of the MFP 2 is touch-operated by the IC card 100 such as an employee ID card in step S47 described above, the first communication control unit 90 of the MFP 2 is operated. In step S53, the advertisement information of the wristwatch-type terminal is transmitted to the wristwatch-type terminal 1 by BLE communication.

This advertising information includes information about a detail button for specifying the display of the detailed information of the advertisement. The display control unit 53 of the wristwatch-type terminal 1 displays and controls the advertisement image and the detail button 150 of the wristwatch-type terminal on the display unit 18 based on the advertisement information received from the MFP 2, for example, as shown in the display image G4 of FIG. do. When the user wants to know the details of the displayed advertisement, he / she operates the detail button 150. The operation processing unit 54 of the wristwatch-type terminal 1 detects the operation of the detail button 150 by the user in step S54. When the operation of the detail button 150 is detected, the display control unit 53 displays the detailed information of the advertisement information received from the MFP 2 on the display unit 18 in step S155.

In this example, when the IC card 100 is touch-operated, the MFP 2 displays the advertisement information on the user's wristwatch-type terminal 1, but in addition, the MFP 2 displays the advertisement information on the touch panel 82. Alternatively, the advertisement information may be transmitted and displayed to other communication devices of the user such as a personal computer device or a mobile terminal device.

(In case of touch operation mistake)
Next, in step S47, when the touch operation on the reader / writer 89 of the MFP 2 performed using the wristwatch-type terminal 1 is a touch operation error, the first communication control unit 90 of the MFP 2 is shown in FIG. In step S56, the error message image G5 is transmitted to the user's wristwatch-type terminal 1 by BLE communication. When the display control unit 53 of the wristwatch type terminal 1 receives the error message image G5 from the MFP 2, it displays it on the display unit 18. As a result, the user recognizes that the touch operation error has occurred by looking at the display unit 18 of the wristwatch type terminal 1, and performs the touch operation again. Along with displaying such an error message image G5, the user may be notified of a touch operation error by an electronic sound or voice.

When a touch operation error is made in the IC card 100, the display control unit 93 of the MFP 2 controls the display of the above-mentioned error message image G5 on the touch panel 82 of the MFP 2. As a result, the user recognizes that the touch operation error has occurred by looking at the touch panel 82 of the MFP 2, and performs the touch operation again. In this case as well, the user may be notified of the touch operation error by an electronic sound or voice together with the display of the error message image G5.

(Effect of the fifth embodiment)
As is clear from the above description, in the information processing system of the fifth embodiment, the BLT communication line between the wristwatch type terminal 1 and the MFP 2 is always established (even if it is established at predetermined time intervals). Good), when the distance between the wristwatch-type terminal 1 and the MFP 2 becomes a predetermined distance, the MFP 2 automatically collects biometric information from the wristwatch-type terminal 1. As a result, the MFP2 can automatically collect biometric information and provide the health check result to each user without requiring any special operation or setting. Further, by displaying the health check result on the wristwatch-type terminal 1, confidential information (health check result) can be provided to the user in a state of maintaining confidentiality, and the same as in each of the above-described embodiments. The effect can be obtained.

In the description of the fifth embodiment described above, the images G1 to G5 such as the message or the health check result shown in FIG. 19 are mainly displayed on the wristwatch type terminal 1, but the touch panel of the MFP 2 is used. It may be displayed on 82.

(Variation example of each embodiment)
Each of the above embodiments is presented as an example and is not intended to limit the scope of the invention. This novel embodiment can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention.

That is, the information processing system may be any system as long as it is a system for sharing information between an electronic device and a mobile terminal. For example, another information processing device such as a copy device or a scanner device may be used instead of the MFP.

In addition, we decided to analyze human biological information, but by acquiring biological information of non-human organisms such as dogs and cats and displaying it on electronic devices, for example, with a collar-type mobile terminal, etc., other than humans. You may try to manage the health of the living organisms.

The CPUs 10 and 60 described above include a processor programmed to execute each function by software, and an ASIC (Application Specific Integrated Circuit), IC (Integrated Circuit) or circuit module designed to execute each function. It shall include hardware such as.

Further, each of the above-described embodiments is carried out by an ASIC (Application Specific Integrated Circuits) or a device configured by connecting conventional circuit modules if the engineer has ordinary knowledge in the information processing technology field. It is possible.

Further, each function described in each of the above-described embodiments can be realized by one or a plurality of processing circuits (Circuit), respectively. Here, the "processing circuit" in the present specification includes hardware such as a processor programmed to execute each function by software, an ASIC designed to execute each function, and a circuit module.

Further, it was decided to use the wristwatch type terminal 1 as the mobile terminal. However, as the mobile terminal, for example, a smartphone, a tablet terminal, or the like may be used in addition to a ring-type or eyeglass-type mobile terminal as long as biological information such as a blood pressure value, a pulse rate, a walking step count, and an amount of exercise can be detected. Further, the mobile terminal may be a terminal worn on a predetermined part of the body such as a head or a chest, in addition to the one worn on the arm as in the wristwatch type terminal 1 described above. Further, it may not be attached to a predetermined part of the body, for example, it may be in the form of being held in a hand, or it may be operated while being kept in a pocket of clothes or the like.

That is, the mobile terminal is a device called a so-called smart terminal such as a smartphone, a tablet terminal, or a wearable device as a mobile communication terminal capable of communicating with the MFP 2 by the above-mentioned short-range wireless communication. A smartphone is typically a terminal having multiple functions such as a call function provided in a mobile phone device, an image pickup function by a camera device, and a Web information display function such as a personal computer device. Further, the tablet terminal is typically a tablet-type terminal that functions as a multifunctional terminal like a smartphone.

Further, the wearable device is typically a device that can be worn on the head such as user goggles, a device that can be worn on the wrist such as a watch, or a device that can be worn on the chest or the like such as a neck strap. However, the wearable device is not limited to this, and the wearable device may be attached to an object owned by the user, such as a hat, a school bag, or a bag. That is, in each of the above-described embodiments, the "mobile phone" may include both a case where it is directly attached to the user's body and a case where it is indirectly attached to the user's body.

Such embodiments and modifications of the embodiments are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and the equivalent scope thereof.

1 Wristwatch type terminal 2 Multifunction device (MFP)
3 Wireless LAN access point device 4 Server device 9 Operation unit 10 CPU
18 Display unit 19 Biometric measurement unit 30 Rim unit 32 Ear hook unit 51 Measurement control unit 53 Display control unit 82 Touch panel 89 Reader / writer 93 Display control unit 94 Analysis unit 95 User authentication unit 95 Storage control unit 100 IC card 122 Analysis unit 123 Storage Control unit

Japanese Unexamined Patent Publication No. 2006-2436969

Claims (15)

An information processing system including a mobile terminal and an electronic device that communicates with the mobile terminal.
The mobile terminal is
A biological information acquisition unit that acquires biological information generated based on movement as a living body,
A transmission unit that transmits the biometric information and
Equipped with
The electronic device is
A receiving unit that receives the biometric information transmitted from the mobile terminal, and
An analysis unit that performs a predetermined analysis process based on the received biometric information,
When displaying the analysis result of the analysis unit on the display unit, a display control unit that displays and controls the analysis result when the user who generated the biometric information logs out from the logged-in electronic device .
An information processing system characterized by being equipped with. An information system including an electronic device that communicates between a mobile terminal and the mobile terminal, and a server device that communicates between the electronic device.
The mobile terminal is
A biological information acquisition unit that acquires biological information generated based on movement as a living body,
A transmission unit for transmitting the biometric information is provided.
The electronic device is
An electronic device communication unit that receives the biometric information transmitted from the mobile terminal, transfers the biometric information to the server device, and receives an analysis result of the biometric information transmitted from the server device.
When the analysis result of the biometric information received from the server device is displayed on the display unit, the display control unit that displays and controls the analysis result when the user who is the generation source of the biometric information logs out from the logged-in electronic device. When,
Equipped with
The server device is
A server communication unit that receives the biometric information transferred from the electronic device and transmits the analysis result of the biometric information to the electronic device.
A server analysis unit that performs a predetermined analysis process based on the biological information received from the electronic device, and a server analysis unit.
An information processing system characterized by being equipped with. When the biometric information transmitted last time exists, the transmitting unit of the mobile terminal generates differential information that is a difference between the biometric information transmitted last time and the biometric information transmitted this time, and transmits the difference information to the electronic device.
The analysis unit of the electronic device or the server analysis unit of the server device regenerates the current biometric information by reflecting the difference information in the biometric information previously analyzed, and based on the reproduced biometric information. The information processing system according to claim 1 or 2, wherein a predetermined analysis process is performed. The analysis unit of the electronic device or the server analysis unit of the server device is characterized in that it generates the analysis result which is a comparison result between the received biological information and the biological information of a healthy body. The information processing system according to any one of claims 1 to 3. The analysis unit of the electronic device or the server analysis unit of the server device calculates an average value of a plurality of biometric information received in the past, and the biometric information received this time is equal to or greater than the biometric information of the healthy body. And, an analysis result showing that an abnormality has occurred when the value is equal to or higher than the average value is generated, and an analysis showing that an abnormality has not occurred when the biometric information received this time is at least less than the average value. The information processing system according to claim 4, wherein the result is generated. The analysis unit of the electronic device or the server analysis unit of the server device calculates a basic value which is an average value of a plurality of biometric information received in the past, and determines the number of occurrences of an abnormal value with respect to the basic value. Detect and
When the number of occurrences of the abnormal value exceeds a predetermined number of times, the display control unit has a timing designated for each user and a predetermined timing that can be visually recognized by the user who is the source of the biometric information. The information processing system according to claim 4, wherein the analysis result is displayed and controlled on the display unit. It has a storage unit in which user information including age, gender, physical characteristics and medical history for each user is stored.
The analysis unit of the electronic device or the server analysis unit of the server device describes the disease described in the medical history of the user who is close to the age, sex, and physical characteristics of the user who analyzed the biological information. Detected from the storage unit and notified to the display control unit,
The display control unit comprises the display control of the notified information indicating the disease on the display unit together with the analysis result of the biological information, according to any one of claims 1 to 6. The information processing system described. The analysis unit of the electronic device or the server analysis unit of the server device stores the combination of each parameter stored as the user information in the storage unit and the disease stored as the medical history. The biometric information is detected for each user stored in the unit, and the cause of the disease and the disease that may be afflicted in the future are identified based on the combination of the parameter and the disease in a predetermined number or more. Notify the display control unit
The information processing system according to claim 7, wherein the display control unit displays and controls the notified information indicating the disease on the display unit together with the analysis result of the biological information. The portable terminal is a wristwatch-type terminal, and when worn on the user's arm, it detects a blood pressure value and a pulse rate based on the vibration of the user's artery and transmits the biometric information to the electronic device. The information processing system according to any one of claims 1 to 8, which is characterized. The mobile terminal includes a mobile display unit and a mobile display control unit that controls the display of the mobile display unit.
The information processing system according to claim 1, wherein the mobile display control unit displays and controls the analysis result of the biological information received from the electronic device on the mobile terminal display unit. The mobile terminal and the electronic device are continuously or intermittently connected by a predetermined communication line.
The electronic device collects the biometric information from the mobile terminal when the distance to the mobile terminal becomes a predetermined distance or less, or at predetermined time intervals via the predetermined communication line. The information processing system according to any one of claims 1 to 10, wherein the information processing system is characterized. The information according to any one of claims 2 to 8, wherein the electronic device transmits the biometric information collected from the mobile terminal to the server device at predetermined time intervals. Processing system. When the analysis result of the biological information received from the electronic device indicates an abnormality in the health condition, the mobile terminal transmits detailed information of the analysis result indicating the abnormal health condition to a predetermined e-mail address. The information processing system according to any one of claims 1 to 12, characterized in that it has an analysis result notification unit. When the display control unit displays the analysis result of the analysis unit on the display unit, the display control unit logs out using the IC card from the electronic device in which the user who generated the biometric information logged in using the IC card. The information processing system according to claim 1 to 13, wherein the analysis result is sometimes displayed and controlled. An information processing method in an information processing system having an electronic device that communicates between a mobile terminal and the mobile terminal.
In the mobile terminal
A biometric information acquisition step in which the biometric information acquisition unit acquires biometric information generated based on movement as a living body.
A transmission step in which the transmission unit transmits the biometric information,
Equipped with
In the electronic device
A reception step in which the receiving unit receives the biometric information transmitted from the mobile terminal, and
An analysis step in which the analysis unit performs a predetermined analysis process based on the received biometric information, and
When the display control unit displays the analysis result of the analysis unit on the display unit, the display control step of displaying and controlling the analysis result when the user who is the generation source of the biometric information logs out from the logged-in electronic device . An information processing method characterized by being provided with.

Images