JP2018191786A - Information processing apparatus, information processing method, and program - Google Patents

Abstract

To provide an information processing apparatus, an information processing method, and a program, which can provide a user with a training menu capable of imparting a suitable load on the user by considering biometric information including at least a blood pressure value.SOLUTION: The information processing apparatus comprises: a biometric information acquisition unit which acquires biometric information including at least a blood pressure value of a user; a determination unit which, on the basis of the biometric information, determines a blood pressure regulating ability of the user; and a generation unit which generates menu information that indicates a training menu corresponding to the blood pressure regulating ability.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an information processing apparatus, an information processing method, and a program for presenting a training menu to a user.

  Conventionally, various apparatuses or services for generating a training menu corresponding to a request from a user and providing the training menu to the user have been proposed. This type of device or service generates a training menu for the purpose of reducing weight or improving physical strength based on, for example, the height and weight of the user included in the request, and provides the training menu to the user.

Japanese Patent Laid-Open No. 2006-119006

  However, even if the user has the same height or weight, biological information (vital data) such as blood pressure may be different. For this reason, when the device or service generates the training menu based on the weight and height of the user, depending on the user, the load caused by the training becomes too large, and there is a possibility that a brain / cardiovascular event may occur.

  Therefore, the present invention provides an information processing apparatus, an information processing method, and a program capable of providing a training menu that can give a load suitable for a user in consideration of biological information including at least a blood pressure value.

  In order to solve the above-described problem, an information processing apparatus according to a first embodiment determines a user's blood pressure adjustment capability based on a biological information acquisition unit that acquires biological information including at least a blood pressure value of the user, and the biological information. A determination unit; and a generation unit that generates menu information indicating a training menu corresponding to the blood pressure adjustment capability.

  The generation unit according to a second embodiment generates the menu information including a breathing training menu or a walking training menu as the training menu.

  The menu for breathing training or the menu for walking training according to the third embodiment is provided by sound guidance.

  The information processing apparatus according to a fourth aspect further includes a motion information acquisition unit that acquires motion information indicating a motion that has occurred in a part of the user's body, and the determination unit is further based on the motion information The blood pressure adjustment ability is determined.

  The information processing apparatus according to the fifth aspect further includes an environmental information acquisition unit that acquires environmental information including at least air temperature, and the determination unit determines the blood pressure adjustment capability based further on the environmental information.

  The determination unit according to a sixth aspect determines the state of the user's autonomic nerve, and the generation unit generates the menu information indicating a training menu further based on the state of the autonomic nerve as the training menu. .

  According to the first mode, the information processing apparatus generates menu information indicating a training menu corresponding to the blood pressure adjustment capability of the user. As a result, the user can perform a load training suitable for his / her blood pressure adjustment ability. Therefore, the information processing apparatus can reduce the risk of developing a brain / cardiovascular event.

  According to the second embodiment, the information processing apparatus provides a breathing training or walking training menu as the training menu. As a result, the user can perform training suitable for his / her blood pressure adjustment ability without using special equipment or facilities.

  According to the third aspect, the information processing apparatus provides the breathing training or walking training menu with sound guidance. For this reason, the user can always perform appropriate load training without overloading, for example, by adjusting to the tempo sound.

  According to the fourth aspect, the information processing apparatus determines the blood pressure adjustment ability in consideration of the body movement information in addition to the user's biological information, and generates a training menu. For example, the information processing apparatus determines the blood pressure adjustment ability in consideration of the state of movement of the user (for example, the speed and amount of movement). As a result, the information processing apparatus can more accurately determine the user's blood pressure adjustment capability than when determining the user's blood pressure adjustment capability based on the biological information.

  According to the fifth aspect, the information processing apparatus further determines the blood pressure adjustment capability of the user by further considering the environment information of the place where the user exists. As a result, the information processing apparatus can more accurately determine the blood pressure adjustment ability in consideration of changes in biological information caused by the environment.

  According to the sixth aspect, the information processing apparatus can generate a training menu suitable for the user based on the blood pressure adjustment ability.

FIG. 1 is a diagram schematically illustrating a configuration example of a providing system. FIG. 2 is a block diagram illustrating a configuration example of the server apparatus. FIG. 3 is a block diagram illustrating a configuration example of the detection apparatus. FIG. 4 is a block diagram illustrating a configuration example of the mobile terminal. FIG. 5 is a block diagram illustrating a configuration example of functions of the server apparatus. FIG. 6 is a flowchart illustrating an operation example of the server apparatus.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
The providing system according to an embodiment determines the blood pressure adjustment capability of the user based on various information. The providing system determines the user's training menu based on the user's blood pressure adjustment capability. The providing system presents the determined training menu to the user.

FIG. 1 is a diagram schematically showing a configuration example of a providing system 1 according to an embodiment of the present invention.
As shown in FIG. 1, the providing system 1 includes a server device 10, a detection device 20, a mobile terminal 30, and the like. The providing system 1 may include a configuration as necessary in addition to the configuration illustrated in FIG. 1 or may exclude a specific configuration.

The server apparatus 10 (information processing apparatus) transmits / receives data to / from the mobile terminal 30 through the communication network 40 such as the Internet. The server device 10 determines the blood pressure adjustment ability of the user based on data from the mobile terminal 30 or the like. The server device 10 determines the user's training menu based on the user's blood pressure adjustment capability and the like. The server device 10 transmits menu information indicating the determined training menu to the mobile terminal 30.
The server device 10 will be described in detail later with reference to FIG.

  The detection device 20 is a wristwatch-type wearable terminal attached to the user's arm. The detection apparatus 20 acquires a user's biometric information using various sensors. Moreover, the detection apparatus 20 acquires acceleration information indicating acceleration generated in the user's body. Moreover, the detection apparatus 20 acquires surrounding environmental information through various sensors. The detection device 20 transmits the acquired biological information, acceleration information, and environment information to the server device 10.

The detection device 20 may use any sensor as long as it can detect the biological information of the user, and the type of the device is not limited to the wearable terminal.
The detection device 20 will be described in detail later with reference to FIG.

The mobile terminal 30 is a terminal owned by the user. For example, the portable terminal 30 is a notebook PC, a tablet PC, a smartphone, or a wearable terminal. The portable terminal 30 transmits / receives data to / from the server device 10 through a communication network 40 such as the Internet. In addition, the mobile terminal 30 transmits and receives data to and from the detection device 20. The portable terminal 30 transmits data from the detection device 20 to the server device 10. In addition, the mobile terminal 30 presents a training menu indicated by the menu information from the server device 10.
The portable terminal 30 will be described in detail later using FIG.

Next, the server device 10 will be described.
FIG. 2 is a block diagram illustrating a configuration example of the server device 10 according to an embodiment.
In the configuration example illustrated in FIG. 2, the server device 10 includes a processor 11, a memory 12, a communication unit 13, an operation unit 14, a display unit 15, and the like. These units are connected to each other via a data bus. The server device 10 may include a configuration as necessary in addition to the configuration illustrated in FIG. 2 or may exclude a specific configuration.

  The processor 11 has a function of controlling the overall operation of the server device 10. The processor 11 may include an internal cache and various interfaces. The processor 11 implements various processes by executing programs stored in the internal cache or the memory 12 in advance.

  Note that some of the various functions realized by the processor 11 executing the program may be realized by a hardware circuit. In this case, the processor 11 controls a function executed by the hardware circuit.

The memory 12 stores various data. For example, the memory 12 functions as a ROM, a RAM, and an NVM.
For example, the memory 12 stores a control program, control data, and the like. The control program and control data are incorporated in advance according to the specifications of the server device 10. For example, the control program is a program that supports a function realized by the server device 10.

  The memory 12 temporarily stores data being processed by the processor 11. The memory 12 may store data necessary for executing the application program, the execution result of the application program, and the like.

  The communication unit 13 is an interface for transmitting / receiving data to / from the mobile terminal 30. The communication unit 13 transmits and receives data to and from the mobile terminal 30 through a communication network 40 such as the Internet. For example, the communication unit 13 supports a LAN connection or the like.

  The operation unit 14 includes, for example, a keyboard, a numeric keypad, and a touch panel. The operation unit 14 captures various operation instructions input by the operator of the server device 10 and transmits a signal representing the operation instruction input by the operator to the processor 11.

  The display unit 15 is composed of a liquid crystal monitor, for example. The display unit 15 displays various information under the control of the processor 11. When the operation unit 14 is configured with a touch panel or the like, the display unit 15 may be formed integrally with the operation unit 14.

Next, the detection device 20 will be described.
FIG. 3 is a block diagram illustrating a configuration example of the detection device 20 according to an embodiment.
In the configuration example illustrated in FIG. 3, the detection device 20 includes a processor 21, a memory 22, a communication unit 23, an operation unit 24, a display unit 25, a biosensor 26, an acceleration sensor 27, and an environment sensor 28. These units are connected to each other via a data bus. Note that the detection device 20 may include a configuration as necessary in addition to the configuration illustrated in FIG. 3 or may exclude a specific configuration.

  The processor 21 has a function of controlling the operation of the entire detection device 20. The processor 21 may include an internal cache and various interfaces. The processor 21 implements various processes by executing a program stored in advance in the internal cache or the memory 22.

  Note that some of the various functions realized by the processor 21 executing the program may be realized by a hardware circuit. In this case, the processor 21 controls a function executed by the hardware circuit.

  The memory 22 stores various data. For example, the memory 22 stores a control program, control data, and the like. The control program and control data are incorporated in advance according to the specification of the detection device 20. The control program is a program that supports a function realized by the detection apparatus 20.

  The memory 22 temporarily stores data being processed by the processor 21. The memory 22 may store data necessary for executing the application program, an execution result of the application program, and the like. The memory 22 temporarily or non-temporarily stores the user's biological information, acceleration information, environmental information, and the like.

  The communication unit 23 is an interface for transmitting and receiving data to and from the mobile terminal 30. For example, the communication unit 23 is connected to the mobile terminal 30 via a wired or wireless line. For example, the communication unit 23 may support LAN connection, USB connection, or Bluetooth.

  The operation unit 24 includes, for example, a numeric keypad and a touch panel. The operation unit 24 takes in various operation instructions input by a user wearing the detection device 20 and outputs a signal representing the operation instructions to the processor 21.

  The display unit 25 is composed of a liquid crystal monitor, for example. The display unit 25 displays various information under the control of the processor 21. When the operation unit 24 is configured with a touch panel or the like, the display unit 25 may be formed integrally with the operation unit 24.

  The biological sensor 26 is configured by a sensor for measuring biological information to be measured. The biological sensor 26 continuously measures biological information related to the user's biological body. The biosensor 26 includes a blood pressure sensor 261 that measures at least blood pressure. The biosensor 26 measures a heart rate sensor that measures a heart rate, an electrocardiogram sensor that measures an electrocardiogram, a pulse wave sensor that measures a pulse wave, a pulse sensor that measures a pulse, a body temperature sensor that measures body temperature, or a sweating state. It may include a sweat sensor. The biosensor 26 may be one that receives sensor data from a sensor that is installed on the head and measures brain waves.

  The blood pressure sensor 261 is a sensor that measures a user's blood pressure as biological information. For example, the blood pressure sensor 261 is a blood pressure sensor (hereinafter referred to as a continuous blood pressure sensor) that can measure blood pressure for each beat (continuous) of the user's heartbeat. The continuous blood pressure sensor may continuously measure a user's blood pressure from a pulse wave transit time (PTT), or may realize continuous measurement by a tonometry method or other techniques. The blood pressure sensor 261 is not limited to a specific configuration.

  Each sensor other than the blood pressure sensor 261 also measures the user's biological information continuously or at predetermined time intervals. That is, each sensor constituting the biological sensor 26 may measure the biological information every time the heart beats (continuously), or may measure the biological information at predetermined time intervals.

  In addition, each sensor constituting the biological sensor 26 outputs a measurement value indicating a measurement result (a value indicating a state of biological information (measurement value of biological information)) to the processor 21. For example, each sensor of the biosensor 26 may output a measurement value of the biometric information measured each time biometric information is measured to the processor 21. In addition, each sensor of the biosensor 26 may transmit a measurement value of biometric information to the processor 21 at a predetermined time interval. Further, the biometric sensor 26 may have a buffer memory, and may collectively output the measurement values of the biometric information measured within a predetermined time interval to the processor 21.

  The acceleration sensor 27 detects the acceleration received by the acceleration sensor 27. The acceleration sensor 27 detects acceleration (motion) generated in a part of the user's body. Since the detection device 20 is attached to the user's wrist, the acceleration sensor 27 detects triaxial acceleration information generated on the user's wrist. The acceleration sensor 27 outputs acceleration information (motion information) indicating a measured value of acceleration to the processor 21.

  The environmental sensor 28 continuously measures environmental information indicating the environment around the user. For example, the environmental sensor 28 includes an air temperature sensor 281 that measures air temperature as environmental information. The environmental sensor 28 may include a humidity sensor that measures humidity, an atmospheric pressure sensor that measures atmospheric pressure, an illuminance sensor that measures illuminance, or a microphone that measures sound.

  The temperature sensor 281 includes a thermistor, a thermocouple, an infrared sensor, or the like. The temperature sensor 281 measures the temperature around the user. Further, the temperature sensor 281 may output a value obtained by correcting the value actually measured by the detection unit according to the influence of the user's body temperature as a measured value of the temperature. The configuration of the temperature sensor 281 is not limited to a specific configuration. The processor 21 may measure the temperature by correcting the measurement value of the temperature sensor 281 according to the influence of the user's body temperature.

  Each sensor of the environmental sensor 28 outputs a value indicating a measurement result (a value indicating an environmental state (a measured value of environmental information)) to the processor 21. For example, the environment sensor 28 may output a measurement value of the environment information to the processor 21 every time the environment information is measured. In addition, each sensor of the environmental sensor 28 may transmit a measurement value of environmental information to the processor 21 at a predetermined time interval. For example, the environment sensor 28 may include a buffer memory, and collectively transmit measured values of environment information measured within a predetermined interval to the processor 21.

  Note that the detection device 20 may include a gyro sensor or the like. For example, the gyro sensor detects the rotation in the three axis directions and transmits the detection result to the processor 21.

Next, the mobile terminal 30 will be described.
FIG. 4 is a block diagram illustrating a configuration example of the mobile terminal 30 according to an embodiment.
In the configuration example illustrated in FIG. 4, the mobile terminal 30 includes a processor 31, a memory 32, a first communication unit 33, a second communication unit 34, an operation unit 35, a display unit 36, a speaker unit 37, and the like. These units are connected to each other via a data bus. Note that the mobile terminal 30 may include a configuration as necessary in addition to the configuration illustrated in FIG. 4 or may exclude a specific configuration.

  The processor 31 has a function of controlling the operation of the entire mobile terminal 30. The processor 31 may include an internal cache and various interfaces. The processor 31 implements various processes by executing a program stored in advance in the internal cache or the memory 32.

  Note that some of the various functions realized by the processor 31 executing the program may be realized by a hardware circuit. In this case, the processor 31 controls a function executed by the hardware circuit.

The memory 32 stores various data. For example, the memory 32 functions as a ROM, a RAM, and an NVM.
For example, the memory 32 stores a control program, control data, and the like. The control program and control data are incorporated in advance according to the specifications of the mobile terminal 30. For example, the control program is a program that supports functions realized by the mobile terminal 30.

  The memory 32 temporarily stores data being processed by the processor 31. The memory 32 may store data necessary for executing the application program, the execution result of the application program, and the like.

  The first communication unit 33 is an interface for transmitting and receiving data to and from the server device 10. The first communication unit 33 transmits / receives data to / from the server device 10 through the communication network 40 such as the Internet. For example, the first communication unit 33 supports LAN connection and the like.

The second communication unit 34 is an interface for transmitting and receiving data to and from the detection device 20. The second communication unit 34 connects to the detection device 20 wirelessly or by wire. For example, the first communication unit 33 supports LAN connection, USB connection, or Bluetooth.
Note that the first communication unit 33 and the second communication unit 34 may be integrally formed.

  The operation unit 35 includes, for example, a keyboard, a numeric keypad, and a touch panel. The operation unit 35 captures various operation instructions input by the user and transmits a signal representing the operation instruction input by the user to the processor 31.

  The display unit 36 is composed of, for example, a liquid crystal monitor. The display unit 36 displays various information under the control of the processor 31. When the operation unit 35 is configured with a touch panel or the like, the display unit 36 may be formed integrally with the operation unit 35.

  The speaker part 37 is comprised from a speaker etc., for example. The speaker unit 37 outputs various sounds under the control of the processor 31. The mobile terminal 30 may include an interface connected to an earphone or a speaker for outputting sound.

Next, functions realized by the server device 10, the detection device 20, and the mobile terminal 30 will be described.
First, functions realized by the processor 21 of the detection device 20 will be described.
First, the processor 21 has a function of acquiring biological information from each sensor of the biological sensor 26. For example, the processor 21 acquires a blood pressure measurement value (blood pressure value) from the blood pressure sensor 261 as biological information.

  For example, the processor 21 transmits a command for acquiring a blood pressure value to the blood pressure sensor 261, and acquires the blood pressure value as a response to the command. The processor 21 may acquire a blood pressure value transmitted by the blood pressure sensor 261 at a predetermined timing. Note that the processor 21 may acquire a measurement value of a heart rate, an electrocardiogram, a pulse wave, a pulse, a body temperature, sweating, or an electroencephalogram from the biosensor 26 as a measurement value of biometric information.

The processor 21 has a function of acquiring acceleration information from the acceleration sensor 27.
For example, the processor 21 transmits a command for acquiring acceleration information to the acceleration sensor 27, and acquires acceleration information as a response to the command. Further, the processor 21 may acquire acceleration information transmitted by the acceleration sensor 27 at a predetermined timing.

  The processor 21 has a function of acquiring environment information from the environment sensor 28. For example, the processor 21 acquires the temperature from the temperature sensor 281 as a measurement value of the environmental information.

  For example, the processor 21 transmits a command for acquiring the temperature to the temperature sensor 281 and acquires the temperature as a response to the command. Further, the processor 21 may acquire the temperature transmitted by the temperature sensor 281 at a predetermined timing. The processor 21 may acquire a value indicating the state of humidity, atmospheric pressure, illuminance, or sound from the environment sensor 28 as a measurement value of the environment information.

Further, the processor 21 has a function of transmitting biological information, acceleration information, and environment information to the mobile terminal 30.
For example, the processor 21 transmits biological information, acceleration information, and environment information to the mobile terminal 30 through the communication unit 23.

  For example, when the processor 21 receives a request for biological information, acceleration information, and environmental information from the portable terminal 30 through the communication unit 23, the processor 21 transmits biological information, acceleration information, and environmental information as a response to the request. Further, the processor 21 may transmit biological information, acceleration information, and environment information to the portable terminal 30 through the communication unit 23 at a predetermined timing (for example, when communication with the portable terminal 30 is established).

Further, the processor 21 may include time information indicating time in the biological information, acceleration information, and environment information. For example, the processor 21 may include time information indicating the time when the measured value of the biological information, the measured value of the acceleration information, and the measured value of the environmental information are measured in the biological information, the acceleration information, and the environmental information, respectively.
Further, the processor 21 may acquire time information indicating the time at which each measurement value is measured from the biological sensor 26, the acceleration sensor 27, and the environment sensor 28.

Note that the processor 21 may individually transmit biological information, acceleration information, and environment information to the mobile terminal 30. For example, the processor 21 may receive a request for requesting each of biological information, acceleration information, and environmental information, and transmit each of the biological information, acceleration information, and environmental information to the portable terminal 30 as a response to the request. .
Further, the processor 21 may transmit other information to the mobile terminal 30.

Next, functions realized by the processor 31 of the mobile terminal 30 will be described.
First, the processor 31 has a function of acquiring biological information. The processor 31 acquires biological information from the detection device 20 through the second communication unit 34. For example, the processor 31 transmits a request for biometric information to the detection device 20 through the second communication unit 34, and receives the biometric information as a response to the request. Further, the processor 31 may receive biological information transmitted from the detection device 20 at a predetermined timing through the second communication unit 34.

  The processor 31 has a function of acquiring acceleration information. The processor 31 acquires acceleration information from the detection device 20 through the second communication unit 34. For example, the processor 31 transmits a request for acceleration information to the detection device 20 through the second communication unit 34, and receives the acceleration information as a response to the request. Further, the processor 31 may receive acceleration information transmitted from the detection device 20 at a predetermined timing through the second communication unit 34.

  The processor 31 has a function of acquiring environment information. The processor 31 acquires environmental information from the detection device 20 through the second communication unit 34. For example, the processor 31 transmits a request for environmental information to the detection device 20 through the second communication unit 34, and receives the environmental information as a response to the request. Further, the processor 31 may receive environment information transmitted by the detection device 20 at a predetermined timing through the second communication unit 34.

  Note that the processor 31 may acquire environment information from a device other than the detection device 20. For example, the providing system 1 may include a measurement device that measures environmental information at a predetermined position (for example, in the house 100). For example, the measuring device may be composed of a temperature sensor or the like. For example, the processor 31 may acquire environmental information indicating a measured value such as a temperature from the measurement device.

Further, the processor 31 has a function of transmitting biological information, acceleration information, and environment information to the server device 10.
For example, the processor 31 transmits biological information, acceleration information, and environment information to the server device 10 through the first communication unit 33.

  For example, when the processor 31 receives a request for biological information, acceleration information, and environmental information from the server device 10 through the first communication unit 33, the processor 31 transmits biological information, acceleration information, and environmental information as a response to the request. Further, the processor 31 may transmit biometric information, acceleration information, and environment information to the server device 10 through the first communication unit 33 at a predetermined timing (such as when an application is activated).

  Note that the processor 31 may individually transmit biological information, acceleration information, and environment information to the server device 10. For example, the processor 31 may receive a request for requesting each of biological information, acceleration information, and environmental information, and transmit each of the biological information, acceleration information, and environmental information to the server device 10 as a response to the request. .

The processor 31 has a function of presenting a training menu indicated by the menu information from the server device 10 to the user.
The processor 31 acquires menu information from the server device 10 through the first communication unit 33. For example, the processor 31 transmits a request for menu information to the server device 10 and receives the menu information as a response to the request. Further, the processor 31 may receive menu information transmitted from the server device 10 at a predetermined timing.

  The training menu indicated by the menu information is based on the blood pressure adjustment ability of the user. The training menu is training that has an effect of improving the blood pressure adjustment ability of the user. For example, the training menu is breathing training (breathing training menu) or walking training (walking training menu).

  Breathing training improves blood pressure control ability through breathing. For example, breathing training is provided with sound guidance (eg, voice guidance). In the breathing training, breathing (sucking and exhaling) is performed at a timing in accordance with a tempo sound that sounds at predetermined intervals. The processor 31 presents sound guidance for breathing training through the speaker unit 37.

  Note that the breathing training may use an image. For example, the breathing training may be one in which a predetermined pose is shown as an image and breathing is performed in the pose. The breathing training may be a combination of images and sound guidance.

  Walking training improves blood pressure adjustment ability through walking. For example, walking training is provided by sound guidance. In walking training, walking is performed in accordance with a tempo sound generated at predetermined intervals. In addition, the walking training may be performed in accordance with music.

  The walking training may include interval training. For example, the walking training may repeat walking at a relatively fast speed and walking at a relatively slow speed.

The processor 31 presents sound guidance for walking training through the speaker unit 37.
In the walking training, the walking pace may be indicated by text. The walking training may be a combination of images and sound guidance.

  The menu information may indicate a plurality of trainings. For example, the menu information may indicate a plurality of breathing trainings or a plurality of walking trainings. The menu information may indicate a combination of breathing training and walking training.

  Further, when the menu information instructs to perform a training selected from a plurality of trainings, the processor 31 may accept a training selection from the user. For example, the processor 31 displays a plurality of trainings on the display unit 36 and accepts a selection from the user. The processor 31 presents the selected training to the user.

  Further, when the menu information indicates that any of the plurality of trainings is to be performed, the processor 31 may display a message or the like prompting to perform any of the trainings on the display unit 36.

  Further, when the menu information gives priority to a plurality of trainings, the processor 31 may display the plurality of trainings with priority given according to the menu information. The processor 31 may display a message or the like on the display unit 36 urging to perform training according to the priority order.

  Further, the processor 31 may acquire state information indicating the state of the user from the server device 10. For example, the status information indicates the blood pressure adjustment capability of the user. Further, the state information may indicate that the user's ability to adjust blood pressure has improved or decreased. The processor 31 displays the user status indicated by the status information on the display unit 36.

Next, functions realized by the processor 11 of the server device 10 will be described.
FIG. 5 is a block diagram illustrating functions realized by the server device 10. As illustrated in FIG. 5, the server device 10 includes a biological information acquisition unit 41, an acceleration information acquisition unit 42, an environment information acquisition unit 43, a determination unit 44, a generation unit 45, and the like. These functions are realized by the processor 11 executing a program stored in the memory 12 or the like.

  First, the processor 11 has a function of acquiring biological information as the biological information acquisition unit 41. The processor 11 acquires biological information from the portable terminal 30 through the communication unit 13. For example, the processor 11 transmits a request for biometric information to the portable terminal 30 through the communication unit 13 and receives the biometric information as a response to the request. Further, the processor 11 may receive the biological information transmitted from the mobile terminal 30 at a predetermined timing through the communication unit 13.

  The processor 11 has a function of acquiring acceleration information as the acceleration information acquisition unit 42. The processor 11 acquires acceleration information from the portable terminal 30 through the communication unit 13. For example, the processor 11 transmits a request for acceleration information to the portable terminal 30 through the communication unit 13, and receives the acceleration information as a response to the request. Further, the processor 11 may receive acceleration information that the mobile terminal 30 transmits at a predetermined timing through the communication unit 13.

The processor 11 has a function of acquiring environment information as the environment information acquisition unit 43. The processor 11 acquires environment information from the portable terminal 30 through the communication unit 13. For example, the processor 11 transmits a request for environment information to the mobile terminal 30 through the communication unit 13 and receives the environment information as a response to the request. Further, the processor 11 may receive environment information transmitted by the portable terminal 30 at a predetermined timing through the communication unit 13.
Note that the processor 11 may acquire biological information, acceleration information, and environment information from the mobile terminal 30 at the same time.

Further, the processor 11 has a function of determining the blood pressure adjustment ability of the user as the determination unit 44.
The processor 11 determines the blood pressure adjustment capability of the user based on the blood pressure value indicated by the biological information. The blood pressure adjustment ability is an ability of a user to adjust blood pressure, and is generally defined in various academic societies or papers at the time of filing this application. For example, the processor 11 determines an index indicating the blood pressure adjustment capability of the user.

  For example, the processor 11 determines the blood pressure adjustment ability of the user based on the blood pressure value in time series. The processor 11 determines the blood pressure adjustment ability of the user based on the fluctuation of the blood pressure value. For example, the processor 11 determines the blood pressure adjustment capability based on the number of times that a blood pressure surge has occurred.

A blood pressure surge is a rapid increase in blood pressure. For example, a blood pressure surge is an increase in blood pressure value that exceeds a predetermined threshold at a predetermined number of beats (or period).
The processor 11 determines that the blood pressure adjustment capability is lower as the number of blood pressure surges is larger. Further, the processor 11 may determine and count the risk level (for example, the risk level according to the increased blood pressure value) for each blood pressure surge. For example, the processor 11 may determine the blood pressure adjustment capability by weighting the number of blood pressure surges for each risk level.

  In addition, the processor 11 may determine the blood pressure adjustment capability based on the time after the blood pressure surge (or blood pressure increase or decrease) occurs until the increased blood pressure value returns to the original blood pressure value. For example, the processor 11 determines that the blood pressure adjustment ability is lower as the time until the increased blood pressure value returns to the original blood pressure value is longer.

Further, the processor 11 determines the blood pressure adjustment ability based on the acceleration information.
For example, the processor 11 calculates a time-series amount of exercise based on the acceleration information. The processor 11 further determines the blood pressure adjustment ability based on the time-series exercise amount. For example, the processor 11 determines that the blood pressure adjustment ability is low when the blood pressure value rises or falls during a period in which the amount of exercise is small.

  In addition, when a blood pressure surge occurs during a period in which the amount of exercise increases, the processor 11 determines that the change in blood pressure is caused by the amount of exercise. For example, the processor 11 does not count the blood pressure surge. Further, the processor 11 may determine that the blood pressure surge is a blood pressure surge with a low risk level.

  In addition, the processor 11 may determine the blood pressure adjustment ability based on the time from when the amount of exercise decreases (after the user stops exercising) until the blood pressure value increased by the exercise returns to the original blood pressure value. For example, the processor 11 determines that the blood pressure adjustment ability is lower as the time until the blood pressure value increased by the exercise returns to the original blood pressure value is longer.

Further, the processor 11 determines the blood pressure adjustment capability based further on the environmental information.
For example, the processor 11 determines the blood pressure adjustment capability based further on the temperature indicated by the environmental information. When the blood pressure value rises during a period in which the temperature changes (for example, decreases), the processor 11 determines that the increase in blood pressure value is caused by the temperature. For example, if the increase in blood pressure value is equal to or less than a predetermined threshold, the processor 11 does not determine that the increase in blood pressure value is an element indicating a decrease in blood pressure adjustment capability. Further, the processor 11 determines that the blood pressure adjustment capability is low if the increase in the blood pressure value is equal to or greater than a predetermined threshold (for example, a blood pressure surge).

  In addition, the processor 11 may determine the blood pressure adjustment ability based on the time until the blood pressure value that has increased due to the change in temperature returns to the original blood pressure value. For example, the processor 11 determines that the blood pressure adjustment ability is lower as the time until returning to the original blood pressure value is longer.

  The processor 11 may determine the blood pressure adjustment capability based on other factors. The method by which the processor 11 determines the blood pressure adjustment ability is not limited to a specific method.

Further, the processor 11 may determine the state of the user's autonomic nerve as the determination unit 44. For example, the processor 11 determines an index indicating the state of the user's autonomic nerve.
For example, the processor 11 determines the ability to adjust the heart rate as the state of the autonomic nerve. The processor 11 determines the heart rate adjustment capability based on the heart rate indicated by the biological information.

  The processor 11 determines the heart rate adjustment capability based on the time-series heart rate. For example, the processor 11 determines the heart rate adjustment capability based on the fluctuation of the heart rate. For example, when a fluctuation exceeding a predetermined threshold occurs during a predetermined period, the processor 11 determines that the heartbeat adjustment capability is low.

Further, the processor 11 may determine the heartbeat adjustment capability based on the acceleration information.
For example, the processor 11 calculates a time-series amount of exercise based on the acceleration information. The processor 11 further determines the ability to adjust the heart rate based on the time-series exercise amount. For example, the processor 11 determines that the ability to adjust the heart rate is low when the heart rate increases or decreases during a period in which the amount of exercise is small.

  In addition, the processor 11 may determine the heart rate adjustment capability based on the time from when the amount of exercise decreases (after the user stops exercising) until the original heart rate is restored. For example, the processor 11 determines that the ability to adjust the heart rate is lower as the time until returning to the original heart rate is longer.

Moreover, the processor 11 may determine the adjustment capability of a heart rate further based on environmental information.
For example, the processor 11 determines the ability to adjust the heart rate further based on the temperature indicated by the environmental information. When the heart rate increases during a period when the temperature changes (for example, decreases), the processor 11 determines that the increase in blood pressure value is caused by the temperature. For example, if the increase in heart rate is equal to or less than a predetermined threshold, the processor 11 does not determine that the increase in heart rate is an element that indicates a decrease in the ability to adjust the heart rate. Further, the processor 11 determines that the heart rate adjustment capability is low if the increase in the heart rate is equal to or higher than a predetermined threshold (for example, a blood pressure surge).

  Further, the processor 11 may determine the ability to adjust the heart rate based on the time until the heart rate that has increased due to a change in temperature returns to the original blood pressure value. For example, the processor 11 determines that the ability to adjust the heart rate is lower as the time until returning to the original heart rate is longer.

The processor 11 may determine the heartbeat adjustment capability based on other factors. The method by which the processor 11 determines the heart rate adjustment capability is not limited to a specific method.
Further, the processor 11 may determine the state of adjustment ability such as breathing, sweating, digestion, or body temperature as the state of the autonomic nerve.

Further, the processor 11 has a function of generating menu information indicating a training menu corresponding to the blood pressure adjustment capability as the generation unit 45.
The processor 11 determines the training to be presented to the user based on the blood pressure adjustment ability. For example, the processor 11 determines training with reference to a table in which an index of blood pressure adjustment capability and training are associated with each other.

  The training menu corresponds to the blood pressure adjustment ability. For example, the training menu is a menu that allows the user of the blood pressure adjustment ability to improve the blood pressure adjustment ability without difficulty.

  As described above, the training menu includes breathing training or walking training. The processor 11 determines breathing training or walking training corresponding to the index of blood pressure adjustment ability as a training menu.

  The processor 11 may determine one of breathing training and walking training as the training menu, or may determine both. The processor 11 may determine a plurality of breathing trainings or a plurality of walking trainings.

  Note that the processor 11 may determine the training menu based further on the state of the user's autonomic nerve. For example, the processor 11 determines the training with reference to a table in which the blood pressure adjustment ability index and the autonomic nerve state index are associated with the training. In addition, the processor 11 may determine training based on other factors.

  Further, the processor 11 may determine another training as a training menu. The manner in which the processor 11 determines the training and the determined training configuration are not limited to a particular configuration.

  The processor 11 generates menu information indicating the determined training. For example, the processor 11 generates menu information including training sounds or images. Further, the processor 11 may generate menu information including a code indicating training or the like.

When a plurality of trainings are determined, the processor 11 may generate menu information instructing to select and perform any training. In this case, the processor 11 may generate menu information instructing to perform any training. In this case, the processor 11 may generate menu information that gives priority to training.
The processor 11 transmits the generated menu information to the mobile terminal 30 through the communication unit 13. For example, the processor 11 transmits menu information as a response to the request from the mobile terminal 30. Further, the processor 11 may transmit the menu information to the portable terminal 30 at a predetermined timing.

  Note that the processor 11 may generate state information indicating the state of the user based on biological information, acceleration information, environment information, and the like. For example, the processor 11 generates state information indicating an index of blood pressure adjustment capability. Further, the processor 11 may generate state information indicating an index of the state of the autonomic nerve.

The processor 11 transmits the generated state information to the mobile terminal 30 through the communication unit 13.
Further, the processor 11 may transmit other information to the portable terminal 30 through the communication unit 13.

Next, an operation example of the server device 10 will be described.
FIG. 6 is a flowchart for explaining an operation example of the server apparatus 10. Here, it is assumed that the mobile terminal 30 has acquired biological information, acceleration information, and environmental information from the detection device 20. The mobile terminal 30 is assumed to be communicably connected to the communication network 40.

  First, the processor 11 of the server device 10 acquires biometric information from the portable terminal 30 through the communication unit 13 (S11). When the biological information is acquired, the processor 11 acquires acceleration information from the portable terminal 30 through the communication unit 13 (S12).

  When the acceleration information is acquired, the processor 11 acquires environmental information from the portable terminal 30 through the communication unit 13 (S13). When the environmental information is acquired, the processor 11 determines the blood pressure adjustment ability of the user (S14).

  When determining the blood pressure adjustment ability of the user, the processor 11 determines the state of the autonomic nerve (S15). When the state of the autonomic nerve is determined, the processor 11 generates menu information indicating a training menu (S16).

  When the menu information is generated, the processor 11 transmits the menu information to the portable terminal 30 through the communication unit 13 (S17). When the menu information is transmitted to the portable terminal 30, the processor 11 ends the operation.

  When the processor 11 acquires biometric information from the portable terminal 30 (when S11 occurs), the processor 11 may execute S12 and subsequent steps. Further, the processor 11 may perform S <b> 11 to S <b> 19 when receiving a request for requesting menu information from the portable terminal 30. Further, the processor 11 may perform S11 to S19 at a predetermined timing (such as a predetermined time).

  Further, the processor 11 may perform S11 to S13 in a different order or simultaneously. Further, the processor 11 may perform S14 after S15.

  Further, the detection device 20 may have the function of the mobile terminal 30. For example, the detection device 20 transmits and receives data to and from the server device 10 via a cellular network or a router. The detection device 20 transmits biological information, acceleration information, environmental information, and the like to the server device 10. The detection device 20 receives menu information from the server device 10. The detection device 20 presents menu information to the user.

  Further, the detection device 20 may have the function of the server device 10. For example, the detection device 20 determines blood pressure adjustment capability based on biological information, acceleration information, and environment information. The detection device 20 presents a training menu based on the blood pressure adjustment capability and the like to the user.

  The providing system configured as described above determines the blood pressure adjustment capability and the like based on the user's biological information and the like. The providing system determines the user's training menu based on the blood pressure adjustment capability and the like. The providing system presents a training menu to the user through the mobile terminal. As a result, the providing system can prompt the user to perform training corresponding to the blood pressure adjustment capability of the user. Therefore, the providing system can improve the blood pressure adjustment capability of the user.

  The present invention is not limited to the above embodiment. As a sensor used for detecting the movement of the user's body, an angular velocity sensor may be used in addition to the acceleration sensor, or a combination of both may be used.

  Various modifications can be made in the implementation stage without departing from the scope of the invention. Further, the embodiments may be implemented in combination as appropriate, and in that case, the combined effect can be obtained. Furthermore, the present invention includes various inventions, and various inventions can be extracted by combinations selected from a plurality of disclosed constituent elements. For example, even if several constituent requirements are deleted from all the constituent requirements shown in the embodiment, if the problem can be solved and an effect can be obtained, the configuration from which the constituent requirements are deleted can be extracted as an invention.

A part or all of the above embodiment may be described as in the following supplementary notes, but is not limited thereto.
(Appendix 1)
A memory and a processor that operates with a program stored in the memory;
With
The processor is
Obtain biometric information including at least the blood pressure value of the user,
Determining the blood pressure adjustment ability of the user based on the biological information;
Configured to generate menu information indicating a training menu corresponding to the blood pressure adjustment capability;
Information processing device.
(Appendix 2)
An information processing method executed by a processor,
Obtain biometric information including at least the blood pressure value of the user,
Determining the blood pressure adjustment ability of the user based on the biological information;
Generating menu information indicating a training menu corresponding to the blood pressure adjustment ability;
Information processing method.

  DESCRIPTION OF SYMBOLS 1 ... Provision system, 10 ... Server apparatus, 11 ... Processor, 13 ... Communication part, 20 ... Detection apparatus, 21 ... Processor, 26 ... Biosensor, 27 ... Acceleration sensor, 28 ... Environmental sensor, 30 ... Portable terminal, 31 ... Processor, 33 ... 1st communication part, 34 ... 2nd communication part, 36 ... Display part, 37 ... Speaker part, 261 ... Blood pressure sensor, 281 ... Temperature sensor.

Claims (8)

A biological information acquisition unit that acquires biological information including at least a blood pressure value of the user;
A determination unit that determines a blood pressure adjustment ability of the user based on the biological information;
A generating unit that generates menu information indicating a training menu corresponding to the blood pressure adjustment capability;
An information processing apparatus comprising: The generation unit generates the menu information including a respiratory training menu or a walking training menu as the training menu.
The information processing apparatus according to claim 1. The breathing training menu or the walking training menu is provided by sound guidance.
The information processing apparatus according to claim 2. A movement information acquisition unit that acquires movement information indicating movement generated in a part of the user's body;
The determination unit determines the blood pressure adjustment ability based on the movement information;
The information processing apparatus according to any one of claims 1 to 3. An environmental information acquisition unit that acquires environmental information including at least the temperature;
The determination unit determines the blood pressure adjustment ability based on the environment information;
The information processing apparatus according to any one of claims 1 to 4. The determination unit determines the state of the user's autonomic nerve,
The generation unit generates the menu information indicating a training menu further based on the state of the autonomic nerve as the training menu.
The information processing apparatus according to any one of claims 1 to 5. A process in which the information processing apparatus acquires biometric information including at least a blood pressure value of the user;
The information processing apparatus determines a user's blood pressure adjustment ability based on the biological information;
The information processing apparatus generates menu information indicating a training menu corresponding to the blood pressure adjustment capability;
An information processing method comprising:   The program which makes a processor function as each part with which the information processing apparatus of any one of Claims 1 thru | or 6 is provided.