JP7167833B2 - Wearable sensor and operation support system using it - Google Patents

Description

The present invention relates to a wearable sensor that performs predetermined processing based on a user's biometric information and an operation support system using the wearable sensor.

2. Description of the Related Art Conventionally, wearable sensors have been proposed that give advice on health management and the like based on user's biological information. Specifically, this wearable sensor acquires user behavior information and biometric information. Then, the wearable sensor determines the biological information based on the behavior information, and gives advice such as health management based on the determination result.

Japanese Patent No. 3846844

However, the wearable sensor only gives advice when operating a mobile object such as a vehicle. At present, there is a demand to provide a comfortable operating environment for users who operate mobile bodies.

In view of the above points, an object of the present invention is to provide a wearable sensor and an operation support system that can provide a comfortable operating environment for a user who operates a mobile body.

In claims 1 and 3 for achieving the above object, a wearable sensor that is worn by a user and performs predetermined processing based on the user's biological information, comprising a measurement unit (120) that measures the user's biological information , a sensor communication unit (110) configured to be communicable with a mobile communication unit (210) mounted on a mobile object (20) that can be moved by a user's operation, and connected to the measurement unit and the sensor communication unit and a sensor control unit (140) configured to determine whether or not the user is the operator of the mobile object according to the communication state between the sensor communication unit and the mobile object communication unit. is determined to be the operator of the mobile object, the biometric information is acquired from the measurement unit, and it is determined whether the biometric information is normal based on a predetermined biometric threshold, and the biometric information is determined to be abnormal. Then, the user is notified that the biological information is abnormal, and a biological sedation signal is transmitted to the moving body so that control for calming the notified biological information is executed.
In claim 1, the sensor control unit further causes the measurement unit to measure the biological information even when the user is not the operator, and determines that the user is not the operator when the user is determined to be the operator. The interval at which the biological information is measured by the measuring unit is made shorter than in the case.
In claim 3, the sensor control unit further performs multiple regression analysis based on a regression equation in which a predetermined partial regression coefficient (β(ti)) is set, and calculates a plurality of user's emotion values based on biometric information. In addition to calculating, comparing a plurality of emotion values with respective set emotion thresholds, and if there is one emotion value greater than the emotion threshold value, the emotion indicated by the emotion value is displayed by the user. Emotion is estimated, and if there are multiple emotion values greater than the emotion threshold, the emotion indicated by the emotion value having the largest difference from the emotion threshold is estimated as the user's emotion, and the user's estimated emotion. is notified, and an emotional calming signal is transmitted to the moving body so that control for calming the notified emotion is executed.

According to this, when the wearable sensor determines that the user is the operator, if the biological information is abnormal, the wearable sensor notifies the user and executes control to calm the biological state of the user notified by the mobile body. It sends a bio-sedation signal that allows it to be sedated. Therefore, it is possible to provide the user with a comfortable operating environment.

Further, according to claim 11, there is provided an operation support system that performs predetermined processing according to the state of a user sitting on an operating seat of a mobile object, the system being worn by the user and performing predetermined processing based on the user's biometric information. and a mobile body (20) that can be operated by the user, and the wearable sensor includes a measurement unit (120) that measures the user's biological information A sensor communication unit (110) configured to be able to communicate with a mobile communication unit (210) mounted on a mobile object (20) that can move, and a sensor control unit (140) connected to the measurement unit and the sensor communication unit. ), and the sensor control unit determines whether or not the user is the operator of the mobile object according to the communication state between the sensor communication unit and the mobile object communication unit, and determines whether the user is the operator of the mobile object. If it is determined that the biological information is normal, it is determined that the biological information is normal based on a predetermined biological threshold, and if it is determined that the biological information is abnormal, the biological information is sent to the user. is notified that the is abnormal, and transmits to the mobile body a biological sedation signal for executing control to calm the notified biological information, and the mobile body It has a communication unit, a sedation unit (220) that performs predetermined processing, and a mobile unit control unit (250) connected to the mobile unit communication unit and the sedation unit. Upon reception, the sedation unit is controlled so that the biological information determined to be abnormal is sedated. Further, the sensor control unit performs multiple regression analysis based on a regression equation in which a predetermined partial regression coefficient (β(ti)) is set, calculates a plurality of user's emotion values based on the biological information, and calculates a plurality of user's emotion values. compares the emotion value of each with an emotion threshold set for each, and if there is one emotion value greater than the emotion threshold, the emotion indicated by the emotion value is estimated to be the user's emotion, If there are multiple emotion values greater than the emotion threshold, the emotion indicated by the emotion value with the greatest difference from the emotion threshold is estimated as the user's emotion, and the user is notified of the estimated emotion. At the same time, an emotional calming signal is transmitted to the moving body so that control for calming the notified emotion is executed, and when the mobile body control unit receives the emotional calming signal, the emotional calming signal The sedative part is controlled so that the triggering emotion is sedated.

According to this, if the biological information is abnormal, the moving body executes control to calm the biological state determined to be abnormal. Therefore, it is possible to provide the user with a comfortable operating environment.

Further, according to claims 1 to 3 , there is provided an operation support system for performing predetermined processing according to the state of a user sitting on an operating seat of a mobile body, wherein the system is worn by the user and performs predetermined processing based on the biological information of the user. A wearable sensor (10) that performs processing, a mobile body (20) that can be operated by a user, and a server (30) configured to communicate with the wearable sensor, wherein the wearable sensor receives the user's biological information. and a sensor communication unit (110) configured to communicate with a mobile communication unit (210) mounted on a mobile object (20) that can be moved by a user's operation. , and a sensor control unit (140) connected to the measurement unit and the sensor communication unit, and the sensor control unit enables the user to operate the mobile object according to the communication state between the sensor communication unit and the mobile communication unit. If it is determined that the user is the operator of the moving body, the biometric information is acquired from the measurement unit and transmitted to the server, and the determination result indicating that the biometric information is abnormal is sent from the server. is transmitted, the user is notified that the biological information is abnormal, and the moving body is controlled to calm the notified biological information. and the mobile unit has a mobile unit communication unit, a sedation unit (220) that performs predetermined processing, and a mobile unit control unit (250) connected to the mobile unit communication unit and the sedation unit, When receiving the biological sedation signal, the mobile body control unit controls the sedation unit so that the biological information determined to be abnormal is sedated, and the server is a server communication unit (410) configured to communicate with the sensor communication unit. and a server control unit (420) that is connected to the server communication unit and performs predetermined processing. It determines whether the biological information is normal and transmits the determination result to the wearable sensor. Furthermore, when the biological information is transmitted from the wearable sensor, the server control unit performs multiple regression analysis based on a regression equation in which a predetermined partial regression coefficient (β(ti)) is set, and the user's A plurality of emotion values are calculated, the plurality of emotion values are compared with respective emotion threshold values, and if one emotion value is greater than the emotion threshold value, the emotion value is determined. is the user's emotion, and if there are multiple emotion values greater than the emotion threshold, the emotion indicated by the emotion value with the largest difference from the emotion threshold is estimated to be the user's emotion. Then, the estimated emotion is transmitted to the wearable sensor, and the sensor control unit notifies the received emotion to the user, and controls the moving object to calm the notified emotion. When the moving body control unit receives the emotional sedation signal, it controls the sedation unit so that the emotion triggered by the emotional sedation signal is sedated.

According to this, if the biological information is abnormal, the moving body executes control to calm the biological state determined to be abnormal. Therefore, it is possible to provide the user with a comfortable operating environment. Moreover, determination of biometric information is performed by the server. Therefore, compared with the case where the wearable sensor determines the biological information, the configuration of the wearable sensor can be simplified.

It should be noted that the reference numerals in parentheses attached to each component etc. indicate an example of the correspondence relationship between the component etc. and specific components etc. described in the embodiments described later.

1 is a block diagram showing an operation support system according to a first embodiment; FIG. It is a figure which shows the relationship between the voltage of the measurement result sent to a sensor control part, and time. 4 is a flow chart showing operations performed by a sensor control unit; 4 is a flowchart showing operations performed by a vehicle control unit; It is a figure which shows the relationship of the voltage of the measurement result transmitted to the sensor control part in the modification of 1st Embodiment, and time. It is a block diagram which shows the operation assistance system in 2nd Embodiment. 9 is a flowchart showing operations performed by a sensor control unit in the second embodiment; FIG. 10 is a flow chart showing operations performed by a sensor control unit in the third embodiment; FIG. FIG. 11 is a flowchart showing operations performed by a vehicle control unit in the third embodiment; FIG. It is a block diagram which shows the operation assistance system in 4th Embodiment. FIG. 10 is a flow chart showing operations performed by a sensor control unit in the fourth embodiment; FIG. FIG. 14 is a flow chart showing operations performed by a server control unit in the fourth embodiment; FIG.

An embodiment of the present invention will be described below with reference to the drawings. In addition, in each of the following embodiments, portions that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
A first embodiment will be described with reference to the drawings. The operation support system of this embodiment includes a wearable sensor 10 and a vehicle 20 as a mobile object. Note that the mobile object is not limited to the vehicle 20, and may be any object such as a train, an airplane, a ship, or the like that can be moved by a user's operation. In the following, a vehicle such as a general four-wheeled vehicle will be described as an example of the vehicle 20 as a moving object. In the following, an example will be described in which the vehicle 20 as a moving body is equipped with a driving support device 240 that performs automatic emergency braking, automatic driving, and the like, as will be described later.

First, the configuration of the wearable sensor 10 of this embodiment will be described. The wearable sensor 10 is configured to be worn by a user, for example, configured to be worn on the user's wrist. The wearable sensor 10 includes a sensor communication section 110, a measurement section 120, an input/output section 130, and a sensor control section 140 connected to these.

The sensor communication unit 110 is configured to be able to communicate with a vehicle communication unit 210 mounted on the vehicle 20, which will be described later, and includes, for example, an antenna, a modulation unit, a demodulation unit, and the like. The sensor communication unit 110 modulates the signal transmitted from the sensor control unit 140 and transmits it from the antenna, and demodulates the radio waves received by the antenna and transmits the signal to the sensor control unit 140 .

The measurement unit 120 measures the user's biological information. In this embodiment, the measuring unit 120 is configured to have a pulse measuring unit 121, a respiratory rate measuring unit 122, a body temperature measuring unit 123, a perspiration measuring unit 124, and the like. The result is sent to the sensor control section 140 .

For example, the pulse measurement unit 121 utilizes the property that light is contained in hemoglobin in blood, emits light from a light emitting diode or the like, and measures the user's pulse based on the peak value of scattered light reflected by blood flow. do. Then, pulse measuring section 121 transmits the measurement result to sensor control section 140 .

The respiratory rate measurement unit 122 measures the user's respiratory rate based on the periodic variation of the peak value detected by the pulse measurement unit 121 . The respiration rate measurement unit 122 then transmits the measurement result to the sensor control unit 140 .

The body temperature measurement unit 123 detects infrared rays emitted from the user's surface using a thermopile or the like, and measures the user's body temperature based on the detection result. Body temperature measurement unit 123 then transmits the measurement result to sensor control unit 140 .

The perspiration measurement unit 124 applies a weak electric current to the body using the bioimpedance method, and measures the amount of perspiration of the user based on changes in impedance. Perspiration measurement unit 124 then transmits the measurement result to sensor control unit 140 .

Note that each measuring unit 121 to 124 is configured such that the measurement interval of the biological information can be adjusted. The measuring units 121 to 124, which will be described in detail later, are designed to shorten the measurement intervals when the user is a driver compared to when the user is not a driver.

The input/output unit 130 outputs notifications to the user and receives responses from the user. In this embodiment, the input/output unit 130 includes an audio device 131 having a speaker, a MEMS microphone, a control unit, and the like, a display unit such as a touch panel display, a display device 132 having a control unit, and the like. The input/output unit 130 outputs a notification to the user under the control of the sensor control unit 140 and transmits a response input by the user to the sensor control unit 140 .

Note that, when the input from the user is voice, the input/output unit 130 transmits the result of text conversion of the voice by the voice device 131 to the sensor control unit 140 as the input result. Further, when the input from the user is an operation to the display device 132, the input/output unit 130 transmits a result based on the operation of the display device 132 to the sensor control unit 140 as an input result.

The sensor control unit 140 is configured by a microcomputer or the like including a CPU (not shown) and a storage unit configured by non-transitional physical storage media such as ROM, RAM, flash memory, and HDD. CPU is an abbreviation for Central Processing Unit, ROM is an abbreviation for Read Only Memory, RAM is an abbreviation for Random Access Memory, and HDD is an abbreviation for Hard Disk Drive. The sensor control unit 140 implements various control operations by having the CPU read and execute programs (that is, each routine to be described later) from the ROM or the like. Various data (for example, initial values, lookup tables, maps, etc.) used in executing the program are stored in advance in the ROM or the like. A storage medium such as a ROM is a non-transitional substantive storage medium.

Specifically, sensor control unit 140 controls sensor communication unit 110 to determine whether communication with vehicle communication unit 210, which will be described later, is possible. As will be described later, the vehicle communication unit 210 is arranged and configured to be able to communicate with the sensor communication unit 110 when the user wearing the wearable sensor 10 sits on the driver's seat (that is, the operator's seat). there is That is, the sensor control unit 140 determines whether or not the user is seated in the driver's seat. In other words, the sensor control unit 140 determines whether the user is the driver (that is, the operator of the moving object).

When the sensor control unit 140 determines that the user is the driver, the sensor control unit 140 performs the following processing. Specifically, first, based on the measurement results from the measurement units 121 to 124, it is determined whether or not each biometric information of the user is normal. In this embodiment, the sensor control unit 140 determines whether or not the biological information is normal by comparing the measurement results for each predetermined period.

For example, as shown in FIG. 2, the sensor control section 140 acquires the measurement result of the pulse measurement section 121 as a voltage. Then, the sensor control unit 140 sets the waveform of the target period as an evaluation waveform, sets the waveform of the immediately preceding period as a reference waveform, and calculates the deviation amount between the evaluation waveform and the reference waveform. The amount of deviation may be the amount of deviation between the shapes of the evaluation waveform and the reference waveform itself, or may be the amount of deviation of the peak value.

Then, when the calculated deviation amount is larger than a predetermined biological threshold, the sensor control unit 140 determines that the biological information is abnormal. The predetermined biological threshold is set to 20% in the initial state, for example, but is adjusted according to the user as the wearable sensor 10 is continuously used, as will be described later.

For example, in FIG. 2, the waveform of period T1 from time t1 to time t2, the waveform of period T2 from time t2 to time t3, the waveform of period T3 from time t3 to time t4, and the period from time t4 to time t5 A waveform of T4 and a waveform of period T5 from time t5 to time t6 are shown. In this case, when the waveform of the period T2 is used as the evaluation waveform, the sensor control section 140 uses the waveform of the period T1 as the reference waveform, and derives the deviation amount between the evaluation waveform of the period T2 and the reference waveform of the period T1. When the waveform of the period T5 is used as the evaluation waveform, the sensor control section 140 uses the waveform of the period T4 as the reference waveform, and derives the deviation amount between the evaluation waveform of the period T5 and the reference waveform of the period T4. When the biological threshold is 20%, the sensor control unit 140 determines that the biological information is abnormal because the difference between the evaluation waveform in the period T5 and the reference waveform in the period T4 is 20% or more. judge.

The sensor control unit 140 also makes the same determination as above for the measurement results of the respiration rate measurement unit 122, the body temperature measurement unit 123, and the perspiration measurement unit 124. FIG. In this case, the biological thresholds for the measurement results of the measurement units 122 to 124 may be the same in the initial state, or may be different. However, these biological thresholds are adjusted according to the user by continuous use of the wearable sensor 10, like the biological thresholds for the measurement result of the pulse measurement unit 121 described above.

When the sensor control unit 140 determines that any of the biometric information is abnormal, the sensor control unit 140 controls the input/output unit 130 to notify the user of the biometric information being abnormal. For example, when the sensor control unit 140 determines that the measurement result of the pulse measurement unit 121 is abnormal, the sensor control unit 140 controls the input/output unit 130 to notify the user by asking, “Your pulse seems to be fast. do. In this case, since the user is the driver, the sensor control unit 140 controls the audio device 131 to notify the user by voice.

Then, the sensor control unit 140 performs predetermined processing based on the response from the user. Here, since the user is the driver, predetermined processing is performed based on the voice response of the user. In other words, when the user is a driver and the sensor control unit 140 determines that there is an abnormality in the determination result of the biological information, the sensor control unit 140 performs predetermined processing based on the interaction with the user.

Specifically, when the response from the user indicates that the biological information is normal, such as "no problem", the sensor control unit 140 adjusts the biological threshold used to determine the measurement result. I do. For example, as described above, when the biological threshold for the measurement result of the pulse measuring section 121 is set to 20%, the sensor control section 140 performs processing to adjust the biological threshold to 21%. As a result, an appropriate biometric threshold for the user is set, and determination accuracy can be improved.

Further, when the response from the user is affirmative that there is an abnormality in the biological information, such as "I am a little tired", the sensor control unit 140 controls the input/output unit 130 to indicate that "I need to take a rest." We recommend that you The sensor control unit 140 also transmits a biological sedation signal according to the measurement result to the vehicle control unit 250, which will be described later. As a result, the vehicle control unit 250 controls the sedation unit 220 according to the biological sedation signal, and performs processing in accordance with the user's biological information, as will be specifically described later.

Further, when there is no response from the user, the sensor control unit 140 determines that the user may be suffering from a serious disease such as myocardial infarction and is in a state where the user cannot respond. That is, the sensor control unit 140 determines that the user cannot operate the vehicle 20 . In this case, sensor control unit 140 transmits an emergency signal to vehicle control unit 250, which will be described later. As a result, the vehicle control unit 250 controls the driving support device 240 to operate the vehicle 20, which will be specifically described later.

The above is the configuration of the wearable sensor 10 according to the present embodiment. Further, in the present embodiment, the sensor control unit 140 determines whether or not there is an abnormality in the biological information based on the measurement results from the measurement units 121 to 124 even when it is determined that the user is not the driver. I'm trying When the sensor control unit 140 determines that there is an abnormality in the measurement result, the sensor control unit 140 controls the input/output unit 130 to notify the user, and performs predetermined processing according to the user's response. When the sensor control unit 140 notifies that there is an abnormality in the biological information, if the user is not the driver, the sensor control unit 140 may notify by both the audio device 131 and the display device 132. Only one of 131 or display device 132 may be used for notification. Then, when the response from the user indicates that the biological information is normal, such as "no problem", the sensor control unit 140 adjusts the biological threshold used to determine the measurement result. That is, the sensor control unit 140 of this embodiment adjusts the biometric threshold even when the user is not the driver. Therefore, the sensor control unit 140 has more opportunities to obtain user information, and can perform determination with higher accuracy.

However, in this embodiment, when it is determined that the user is not the driver, for example, when the user is sleeping, the biological threshold for determining biological information is set high, for example, 50%. It is said that That is, when the user is sleeping, it is determined that there is an abnormality when the amount of deviation between the target waveform and the reference waveform is 50% or more. In this case, the sensor control unit 140 may determine whether or not the user is sleeping by providing a clock, a counter, or the like inside the wearable sensor 10 so that the biometric threshold is changed every hour. , the biometric threshold may be changed by the user's operation. In the present embodiment, when the user is not a driver and the user is not a driver, the sensor control unit 140 adjusts the biological threshold based on the user's awake state.

Further, the sensor control unit 140 does not notify the user for a predetermined period of time even if there is an abnormality in the biological information when the user is asleep or in a meeting and is in a state where the user cannot respond or does not want to respond. It may be configured to allow setting to be performed. In this case, the sensor control unit 140 may notify the user that the biological information is abnormal after a predetermined period of time.

Next, the configuration of the vehicle 20 as a moving object will be described. The vehicle 20 includes a vehicle communication unit 210, a calming unit 220, a navigation device 230, a driving support device 240, and a vehicle control unit 250 connected to these devices. In this embodiment, the vehicle communication section 210 corresponds to the mobile communication section, and the vehicle control section 250 corresponds to the mobile control section.

The vehicle communication unit 210 is configured to be able to communicate with the sensor communication unit 110 of the wearable sensor 10, and includes, for example, an antenna, a modulation unit, a demodulation unit, and the like. Vehicle communication unit 210 modulates a signal input from vehicle control unit 250 and transmits the signal from an antenna, and demodulates a radio wave received by the antenna and transmits the signal to vehicle control unit 250 .

The vehicle communication unit 210 is arranged and configured so as to be able to communicate with a limited range around the vehicle 20 including the driver's seat. More specifically, the vehicle communication unit 210 is arranged and configured to be able to communicate with the sensor communication unit 110 when the user who wears the wearable sensor 10 in the driver's seat is seated. That is, the vehicle communication unit 210 is arranged and configured so as to be able to communicate with the sensor communication unit 110 of the wearable sensor 10 worn by the driver.

The navigation device 230 includes a display section, a storage section, a control section, and the like provided in front of the driver's seat. The display unit is configured by a touch panel display, and the storage unit is configured by non-transitional physical storage media such as ROM, RAM, flash memory, and HDD. The navigation device 230 acquires map data from the road map data and the like stored in the storage unit, and also calculates the current position of the vehicle based on GPS signals and the like received via a GPS (abbreviation of Global Positioning System) antenna. Calculate the position. Further, the navigation device 230 executes control for displaying the current location of the host vehicle on the display unit. Furthermore, when the destination is set, the navigation device 230 executes control and the like for guiding the route from the current location to the destination. In addition, in this embodiment, the destination may be set by the vehicle control unit 250 as described later.

The calming unit 220 has an audio device 221, an air conditioner device 222, and the like. The calming section 220 is configured to be controlled by the vehicle control section 250 .

The audio device 221 is configured to include an audio device mounted on the vehicle 20, a storage section, a control section, and the like. The storage unit is composed of non-transitional physical storage media such as ROM, RAM, flash memory, and HDD. The storage unit stores music or the like that calms the user's condition in accordance with the biological information. The music that calms the user's condition in accordance with the biological information is, for example, music that relaxes the user when it is assumed that the user is tense, such as having a fast pulse, or music that is assumed to be hot, such as when the user is sweating a lot. It is music or the like that gives the user an exhilarating feeling when The stored music is sample music in the initial state, but the user can change it according to his or her taste. Then, the audio device 221 controls the audio equipment to play predetermined music or the like.

The air conditioner device 222 is configured to include an air conditioner mounted on the vehicle 20, a storage section, a control section, and the like. The storage unit is composed of non-transitional physical storage media such as ROM, RAM, flash memory, and HDD. The storage unit stores an adjustment method and the like for sedating the user's condition in accordance with the biological information. For example, the adjustment method for calming the user's condition in accordance with biological information is a method for adjusting the temperature, wind direction, etc. in the passenger compartment that gives the user a refreshing feeling when it is assumed to be hot, such as when the amount of perspiration is large. . Note that the stored adjustment method is the sample adjustment method in the initial state, but the user can change it as appropriate according to his/her preference. Then, the air conditioner device 222 controls the air conditioner so that the vehicle interior is in a predetermined state.

The driving assistance device 240 has a storage unit, a control unit, and the like for executing automatic emergency braking, automatic driving, and the like, and is configured so that predetermined control is performed by the vehicle control unit 250 .

The vehicle control unit 250 is configured by a microcomputer or the like having a CPU (not shown) and a storage unit configured by non-transitional physical storage media such as ROM, RAM, flash memory, and HDD. In this embodiment, since the moving body 20 is a vehicle, the vehicle control unit 250 is configured by a vehicle ECU (Electronic Control Unit) or the like. The vehicle control unit 250 implements various control operations by having the CPU read and execute programs (that is, each routine to be described later) from the ROM or the like. Various data (for example, initial values, lookup tables, maps, etc.) used in executing the program are stored in advance in the ROM or the like. A storage medium such as a ROM is a non-transitional substantive storage medium.

Specifically, vehicle control unit 250 controls vehicle communication unit 210 to enable communication with sensor communication unit 110 . As described above, the vehicle communication unit 210 is arranged and configured so as to be able to communicate with the sensor communication unit 110 of the wearable sensor 10 worn by the driver.

When the vehicle control unit 250 receives a biological sedation signal from the sensor control unit 140, the vehicle control unit 250 controls the sedation unit 220 based on the biological sedation signal. For example, when the vehicle control unit 250 receives a biological sedation signal indicating that the pulse is faster than the biological threshold, it is assumed that the user is tense, so it can control the audio device 221 to relax the user. Let the music you can play. Further, for example, when the vehicle control unit 250 receives a bio-sedation signal indicating that the amount of perspiration is large, it is assumed that the user is hot. Lower it or change the direction of the wind.

Furthermore, vehicle control unit 250 controls driving support device 240 when an emergency signal is received from sensor control unit 140 . For example, the vehicle control unit 250 controls the driving support device 240 to stop the vehicle 20 in a safe place while alerting surrounding vehicles by blinking the hazard lamps mounted on the vehicle 20. . Further, for example, the vehicle control unit 250 controls the navigation device 230 to set a nearby hospital as the destination, and controls the driving support device 240 to drive the vehicle 20 to the destination.

The above is the configuration of the operation support system according to the present embodiment. Next, operations performed by the sensor control unit 140 and the vehicle control unit 250 in the operation support system will be described.

First, the operation of the sensor control section 140 will be described with reference to FIG. Note that the sensor control unit 140 performs the following processing when the wearable sensor 10 is powered on. In this case, the wearable sensor 10 may be provided with a power switch so that the wearable sensor 10 can be turned on and off, or the wearable sensor 10 can be turned on and off automatically according to the attachment and detachment of the wearable sensor 10 . good too.

In step S101, the sensor control unit 140 controls the sensor communication unit 110 and determines whether communication with the vehicle communication unit 210 is possible. That is, the sensor control unit 140 determines whether the user wearing the wearable sensor 10 is a driver.

When sensor control unit 140 determines that communication with vehicle communication unit 210 is possible (that is, step S101: YES), in step S102, measurement units 121 to 124 measure biological information in driver mode. make it Note that in this embodiment, the biometric information is measured by the measurement units 121 to 124 even when the user is not the driver. The driver mode is a mode in which the measurement intervals of the measurement units 121 to 124 are shorter than when the user is not the driver. In other words, when the sensor control unit 140 determines that the user is the driver, the sampling frequencies of the measurement units 121 to 124 are increased.

The sensor control unit 140 acquires measurement results from the measurement units 121 to 124 in step S103. In this embodiment, the sensor control unit 140 determines whether or not the biological information is normal based on the waveform for each predetermined period, as described above. determine whether or not

When the sensor control unit 140 determines that the predetermined period has passed (that is, step S104: YES), in step S105, based on the measurement results of the measurement units 121 to 124, each biological information is normal. Determine whether or not there is When the sensor control unit 140 determines that each biological information is normal (that is, step S105: YES), the process ends. Further, when the sensor control unit 140 determines that the predetermined period has not passed (that is, step S104: NO), the process of step S103 is performed again.

On the other hand, if the sensor control unit 140 determines in step S105 that an abnormality has occurred in any of the biological information (that is, step S105: NO), the sensor control unit 140 controls the input/output unit 130 in step S106. Then, the user is notified that an abnormality has occurred in the biometric information. In this case, since the user is the driver, the sensor control unit 140 controls the audio device 131 to notify the user. For example, when the biological information is abnormal due to a rapid pulse, the sensor control unit 140 notifies the user by asking, "Your pulse seems to be rapid. Is this okay?"

Subsequently, in step S107, the sensor control unit 140 determines whether or not there is a response from the user. When the sensor control unit 140 determines that there is a response from the user (that is, step S107: YES), in step S108, it determines whether the biometric information is normal based on the content of the response. For example, when the sensor control unit 140 determines that the user responds with "No problem", "I'm fine", etc., the sensor control unit 140 determines that the biometric information determined to be abnormal is normal. When the sensor control unit 140 determines that the biological information is normal (ie, step S108: YES), the sensor control unit 140 adjusts the biological threshold in step S109. For example, as described above, the sensor control unit 140 determines that the biological threshold is set to 20% and that the biological information is abnormal. Processing is performed to adjust the threshold to 21%. As a result, an appropriate biometric threshold is set for each biometric information of the user, and the determination accuracy can be improved.

On the other hand, when the sensor control unit 140 determines that the user has responded such as "I am tired" or "I am not feeling well", the sensor control unit 140 determines that the biological information is abnormal (ie, step S108: NO). . Then, in step S110, the sensor control unit 140 controls the input/output unit 130 to give advice such as "It is recommended to take a rest" and transmits a biological sedation signal to the vehicle control unit 250. . As a result, the vehicle control unit 250 performs an operation according to the biological sedation signal, as will be described later. The biological sedation signal includes the judgment result of the biological information judged to be abnormal.

After executing the processing of step S109 or step S110, the sensor control unit 140 performs predetermined processing in step S111, and then terminates this processing.

Further, when the sensor control unit 140 determines that there is no response from the user (that is, step S107: NO), the sensor control unit 140 determines that the user cannot respond, and outputs an emergency signal to the vehicle control unit 140 in step S112. 250. Thereby, the vehicle control unit 250 performs an operation according to the emergency signal, as will be described later. When determining that there is no response from the user, the vehicle control unit 250 determines that there is no response from the user if there is no response even after the user is notified in step S106 a plurality of times. good too.

On the other hand, when sensor control unit 140 determines that communication with vehicle communication unit 210 is not possible (that is, step S101: NO), normal processing is performed in step S113. That is, when the sensor control unit 140 determines that the user is not the driver, the normal processing is executed. In the normal processing of this embodiment, first, measurement results of the measurement units 121 to 124 are obtained. It should be noted that, as described above, in normal processing, the measurement intervals of the measurement units 121 to 124 are longer than when the user is the driver. Then, the sensor control unit 140 determines whether or not each piece of biological information is normal, and notifies the user when it is determined that any of the biological information is abnormal. After that, when there is a response from the user, the sensor control section 140 performs processing according to the user's response. In this case, when the sensor control unit 140 of the present embodiment determines that there is an abnormality in the biological information and receives a response such as "no problem" from the user, the biological threshold is set as in step S109. Perform adjustment processing.

That is, the sensor control unit 140 of this embodiment adjusts the biometric threshold even when the user is not the driver. Therefore, the sensor control unit 140 has more opportunities to obtain user information, and can perform determination with higher accuracy.

Next, operations performed by the vehicle control unit 250 will be described with reference to FIG. Note that vehicle control unit 250 performs the following operation when the ignition switch is turned on.

In step S201, the vehicle control unit 250 controls the vehicle communication unit 210 to enable communication with a nearby area including the driver's seat. Accordingly, when the user wearing the wearable sensor 10 sits in the driver's seat, communication with the wearable sensor 10 becomes possible.

Next, in step S202, vehicle control unit 250 determines whether or not a biological sedation signal has been received. When the vehicle control unit 250 determines that the biological sedation signal has been received (that is, step S202: YES), the vehicle control unit 250 controls the sedation unit 220 to perform predetermined processing. For example, when the biological sedation signal indicates that the user's pulse is fast, the vehicle control unit 250 controls the audio device 221 to relax the user because it is assumed that the user is tense. Let the music flow. In addition, when the biological sedation signal indicates that the user is sweating a lot, the vehicle control unit 250 controls the air conditioner device 222 to temperature is lowered and the wind direction is adjusted.

When the vehicle control unit 250 determines that the biological sedation signal has not been received (that is, step S202: NO), in step S204, the vehicle control unit 250 determines whether or not the emergency signal has been received. When the vehicle control unit 250 determines that an emergency signal has been received (step S204: YES), the vehicle control unit 250 controls the driving support device 240 to perform predetermined processing in step S205. For example, the vehicle control unit 250 controls the driving support device 240 to stop the vehicle 20 at a safe place while alerting surrounding vehicles by blinking a hazard lamp mounted on the vehicle 20.例文帳に追加Further, for example, the vehicle control unit 250 controls the navigation device 230 to set a nearby hospital as the destination, and controls the driving support device 240 to drive the vehicle to the destination.

The vehicle control unit 250 terminates the process of step S203, the process of step S205, or when it determines that an emergency signal has not been received (that is, step S204: NO).

As described above, in the present embodiment, when the wearable sensor 10 determines that the user is the driver, the wearable sensor 10 informs the user if the biological information is abnormal, and the user's condition calms down in the vehicle 20. Sending a bio-sedation signal that causes control to take effect. Therefore, it is possible to provide the user with a comfortable operating environment.

Further, when the wearable sensor 10 determines that there is no response from the user after informing the user that the biological information is abnormal, the wearable sensor 10 transmits an emergency signal so that the driving support device 240 is controlled in the vehicle 20. ing. Therefore, it is possible to suppress the occurrence of accidents.

Furthermore, the wearable sensor 10 adjusts the biometric threshold when determining that there is a response indicating that the biometric information is normal from the user after informing the user that the biometric information is abnormal. Therefore, a biometric threshold is set according to each user. Therefore, the determination accuracy of biometric information can be improved.

In addition, the wearable sensor 10 makes the biometric information measurement intervals shorter when the user is a driver than when the user is not a driver. Therefore, it is possible to improve the measurement accuracy when the user is the driver, and to reduce the power consumption when the user is not the driver.

(Modified example of the first embodiment)
A modification of the first embodiment will be described. In the first embodiment described above, the sensor control unit 140 determines whether or not the biological information is normal based on the amount of deviation between the predicted value and the actual measurement based on the measurement results from the measurement units 121 to 124. You may make it judge.

For example, as shown in FIG. 5, the sensor control section 140 acquires the measurement result as a voltage. Further, the sensor control unit 140 controls voltage y(t-3), voltage y(t-2), voltage y Predict voltage Y(t0) at time x(t0) from (t−1). Then, the sensor control unit 140 determines whether or not the amount of deviation ε between the predicted voltage Y(t0) and the voltage y(t0), which is the actually measured value at the time point x(t0), is greater than the biological threshold. , it may be determined whether or not the biological information is normal.

Moreover, although not particularly illustrated, the sensor control section 140 may derive a reference waveform from a plurality of waveforms and compare the reference waveform with the target waveform of each period. That is, the sensor control section 140 may compare the common reference waveform and the symmetrical waveform. In this case, by updating the reference waveform based on the waveform determined to be normal, it is possible to obtain a suitable waveform for each user.

(Second embodiment)
A second embodiment will be described. This embodiment changes the structure of the wearable sensor 10 with respect to 1st Embodiment. Others are the same as those of the first embodiment, so description thereof is omitted here.

As shown in FIG. 6, the operation support system of this embodiment includes a predetermined communication terminal 30 in addition to the wearable sensor 10 and the vehicle 20. As shown in FIG. The basic configuration of the wearable sensor 10 of the present embodiment is the same as that of the first embodiment, but the wearable sensor 10 is configured to be able to communicate with the communication terminal 30 as well. Note that the predetermined communication terminal 30 is a smartphone owned by a person related to the user, such as a user's relatives, friends, or co-workers, or a communication facility installed in a predetermined medical institution.

Next, operations performed by the sensor control unit 140 of this embodiment will be described with reference to FIG.

After transmitting the emergency signal in step S112, the sensor control unit 140 of the present embodiment transmits to the communication terminal 30 a communication signal indicating that there is no response from the user in step S114. In other words, the sensor control unit 140 transmits information indicating that the user's state is unknown to the parties concerned.

As described above, in this embodiment, after transmitting an emergency signal, the sensor control unit 140 transmits to the communication terminal 30 a contact signal indicating that there is no response from the user. As a result, the concerned parties can grasp the user's situation, and can promptly take action thereafter.

(Third embodiment)
A third embodiment will be described. The present embodiment differs from the first embodiment in that the sensor control unit 140 determines the user's emotion. Others are the same as those of the first embodiment, so description thereof is omitted here.

数式１中では、Ｘ（ｔｉ）が説明変数であり、Ｙ（ｔ）が目的変数であり、β（ｔｉ）が偏回帰係数である。また、偏回帰係数β（ｔｉ）は、各感情に対してそれぞれ値が設定されている。 First, the configuration of the wearable sensor 10 of this embodiment will be described. The sensor control unit 140 of the present embodiment stores a regression equation expressed by Equation 1 below regarding emotions associated with each piece of biometric information. Emotions include, for example, joy, anger, sadness, pleasure, fatigue, confusion, anxiety, and calmness.

In Equation 1, X(ti) is the explanatory variable, Y(t) is the objective variable, and β(ti) is the partial regression coefficient. Also, the partial regression coefficient β(ti) has a value set for each emotion.

Then, when the user is a driver, the sensor control unit 140 also estimates the user's emotion by performing multiple regression analysis using Equation 1 above based on each biological information. Specifically, the sensor control unit 140 uses each biological information as an explanatory variable X(ti) and an emotion as an objective variable Y(t) to estimate the emotion. More specifically, the sensor control unit 140 calculates the value of each set emotion from Equation 1 above. Then, the sensor control unit 140 determines whether or not the value of each emotion is greater than a predetermined emotion threshold, and determines that the user has the emotion when it is determined to be greater than the predetermined emotion threshold. However, when a plurality of emotions exceed a predetermined emotion threshold at the same time, the sensor control unit 140 determines that the emotion with the largest difference between the emotion value and the emotion threshold is the user's emotion. For example, when the value indicating sadness and the value indicating anxiety both exceed the emotion threshold, the sensor control unit 140 determines which value has a greater difference from the emotion threshold, Emotions and judgment.

As will be described later, the emotion threshold for each emotion is adjusted according to the user through continuous use of the wearable sensor 10 . Further, in this embodiment, when the value of each emotion such as joy, anger, sadness, and pleasure does not exceed the emotion threshold, the sensor control unit 140 determines that the user is calm. That is, in the present embodiment, the sensor control unit 140 determines that the user is not normal when there is an emotion value exceeding the emotion threshold.

Then, when the sensor control unit 140 determines that the user is not calm, the sensor control unit 140 controls the input/output unit 130 to notify the user of the emotion. For example, when the estimated emotion is sadness, the sensor control unit 140 controls the input/output unit 130 and notifies the user by asking, "You seem to be very sad. Are you okay?"

Then, the sensor control unit 140 performs predetermined processing based on the response from the user. For example, when the response from the user indicates that the user's emotion is normal, such as "no problem", the sensor control unit 140 adjusts at least one of the partial regression coefficient and the emotion threshold. . As a result, at least one of the partial regression coefficient and the emotion threshold is adjusted, and the emotion determination accuracy can be improved.

Further, for example, when the response from the user is an affirmation of sadness such as “I am sad”, the sensor control unit 140 controls the input/output unit 130 to say “It is recommended to take a rest.” ,” and other advice. Further, the sensor control unit 140 transmits to the vehicle control unit 250 an emotional sedation signal according to the determination result. Accordingly, the vehicle control unit 250 controls the sedation unit 220 according to the emotional sedation signal, and performs processing according to the user's emotion.

The above is the configuration of the sensor control unit 140 in this embodiment. Note that, in this embodiment, the sensor control unit 140 estimates the emotion even when the user is not the driver, and performs predetermined processing according to the response from the user. Next, the configuration of the vehicle 20 according to this embodiment will be described.

In the audio device 221 of this embodiment, the storage unit also stores music or the like that calms the user's emotions. Music that soothes the user's emotions is, for example, music that eases sadness when the user is sad, or music that relaxes the user when angry. It should be noted that the stored music can be appropriately changed by the user according to his or her taste. Then, the audio device 221 controls the audio equipment to play predetermined music or the like.

Similarly, the air conditioner device 222 also stores an adjustment method for calming the user's emotions in the storage unit. The adjustment method for soothing the user's emotions is, for example, a method for adjusting the temperature in the passenger compartment and the direction of the wind, which gives the user a feeling of refreshment, because body temperature tends to rise when the user is angry. It should be noted that the stored adjustment method can be changed as appropriate by the user according to his/her preference. Then, the air conditioner device 222 controls the air conditioner so that the vehicle interior is in a predetermined state.

When the vehicle control unit 250 receives the emotional calming signal from the wearable sensor 10, the vehicle control unit 250 controls the calming unit 220 based on the emotional calming signal. For example, when the vehicle control unit 250 receives an emotionally calming signal indicating that the user is sad, the vehicle control unit 250 controls the audio device 221 to play soothing music.

Next, operations performed by the sensor control unit 140 in this embodiment will be described with reference to FIG. It should be noted that the following processing is executed in the predetermined processing in step S111.

In the predetermined process in step S111, the sensor control unit 140 estimates the user's emotion using Equation 1 above based on the biological information acquired in step S103 in step S121. Then, in step S122, sensor control unit 140 determines whether or not the user's emotion is normal.

When the sensor control unit 140 determines that the user is calm (that is, step S122: YES), the process ends. On the other hand, when the sensor control unit 140 determines that the user's emotion is not normal (that is, step S122: NO), the sensor control unit 140 controls the input/output unit 130 to notify the user of the emotion in step S123. For example, when the sensor control unit 140 determines that the user is in a sad state, the sensor control unit 140 asks the user, "You seem sad. Are you okay?"

Subsequently, in step S124, sensor control unit 140 determines whether or not there is a response from the user. Then, when the sensor control unit 140 determines that there is a response from the user (that is, step S124: YES), in step S125, based on the content of the response, determines whether or not the user's feeling is normal. do. For example, when the sensor control unit 140 determines that the user responds with "No problem", "I'm fine", etc., the sensor control unit 140 determines that the user's feeling is normal. Then, when the sensor control unit 140 determines that the user's emotion is normal (that is, step S125: YES), in step S126, the sensor control unit 140 adjusts at least one of the partial regression coefficient and the emotion threshold. This makes it possible to perform a highly accurate determination suitable for the user.

On the other hand, when the sensor control unit 140 determines that the user has made a response such as "I am sad", the sensor control unit 140 determines that the user's emotion is not normal (that is, step S125: NO). Then, in step S127, the sensor control unit 140 controls the input/output unit 130 to provide advice such as "It is recommended to take a rest" and to transmit an emotional calming signal to the vehicle control unit 250. . As a result, vehicle control unit 250 performs an operation according to the emotional sedation signal. It should be noted that the emotional sedation signal includes the determined emotional signal. After executing the process of step S126 or step S127, the sensor control unit 140 ends this process.

Moreover, when the sensor control unit 140 determines that there is no response from the user (that is, step S124: NO), the process of step S123 is executed again. That is, since the sensor control unit 140 has already obtained a response from the user in step S107 described in the first embodiment, it waits until there is a response from the user.

Then, in the normal processing in step S113, the sensor control unit 140 also estimates the emotion, and performs predetermined processing according to the response from the user.

Next, operations performed by the vehicle control unit 250 will be described with reference to FIG.

The vehicle control unit 250 performs steps S201 to S205 in the same manner as in the first embodiment. After executing the process of step S203, the vehicle control unit 250 determines in step S206 whether or not the emotional sedation signal has been received. When the vehicle control unit 250 determines that the emotional calming signal has been received (that is, step S206: YES), the vehicle control unit 250 controls the calming unit 220 to perform predetermined processing. For example, when the emotional calming signal indicates the user's sadness, the vehicle control unit 250 controls the audio device 221 to play music that alleviates sadness. When performing different controls for the biological sedation signal and the emotional sedation signal, the vehicle control unit 250 gives priority to the emotional sedation signal and performs control based on the emotional sedation signal.

As described above, in the present embodiment, the wearable sensor 10 notifies the user that the user's emotions are not normal, and also controls the vehicle 20 to calm the user's emotions. Sending sedation signals. Therefore, it is possible to provide the user with a comfortable operating environment that matches his or her emotions.

In addition, when the wearable sensor 10 determines that the user has responded to indicate that he/she is calm after informing the user of his or her emotions, the wearable sensor 10 adjusts at least one of the partial regression coefficient and the emotion threshold. Therefore, at least one of the partial regression coefficient and the emotion threshold is set according to each user. Therefore, it is possible to improve the determination accuracy of emotion.

Furthermore, the sensor control unit 140 estimates the user's emotion based on a plurality of pieces of biological information. For this reason, the estimated user's emotion is more likely to match the user than one piece of biometric information. Then, in the vehicle control unit 250, when performing different controls for the biological sedation signal and the emotional sedation signal, priority is given to the emotional sedation signal. Therefore, it is possible to provide the user with a more comfortable operating environment.

(Fourth embodiment)
A fourth embodiment will be described. This embodiment adds a server to the first embodiment. Others are the same as those of the first embodiment, so the description is omitted here.

The operation support system of this embodiment includes a server 40 in addition to the wearable sensor 10 and the vehicle 20, as shown in FIG.

The wearable sensor 10 of this embodiment is configured such that the sensor communication unit 110 can also communicate with a server communication unit 410 of the server 40 described later. Then, the sensor control unit 140 transmits the measurement results of the biological information measured by the measurement units 121-124. In addition, in this embodiment, the wearable sensor 10 transmits each measurement result to the server 40 regardless of whether the user is a driver.

Further, as will be described later, the sensor control unit 140 receives the determination result of the biometric information from the server 40 and notifies the user if the biometric information is abnormal. Then, when the response from the user to the biological information notified as abnormal indicates that the biological information is normal, such as "no problem", the sensor control unit 140 sets the biological threshold based on the response. A biological threshold adjustment signal to be adjusted is transmitted to the server 40 .

The server 40 has a server communication section 410, a server control section 420, and the like. The server communication unit 410 is configured to be able to communicate with the sensor communication unit 110 of the wearable sensor 10 .

The server control unit 420 is configured by a microcomputer or the like including a CPU (not shown) and a storage unit configured by non-transitional physical storage media such as ROM, RAM, flash memory, and HDD. The server control unit 420 implements various control operations by having the CPU read and execute programs (that is, each routine to be described later) from the ROM or the like. Various data (for example, initial values, lookup tables, maps, etc.) used in executing the program are stored in advance in the ROM or the like. A storage medium such as a ROM is a non-transitional substantive storage medium.

Specifically, when each measurement result is transmitted from the wearable sensor 10, the server control unit 420 compares the biometric information with a predetermined biometric threshold to determine whether the biometric information is normal. This determination method is the same as the method described with reference to FIGS. 2 and 5 of the first embodiment. That is, in the present embodiment, the server 40 executes determination of biometric information. The server control unit 420 then transmits the determination result regarding the biometric information to the wearable sensor 10 .

Further, when the wearable sensor 10 transmits the biological threshold adjustment signal, the server control unit 420 adjusts the biological threshold. The biological threshold adjustment performed by the server control unit 420 is the same as the biological threshold adjustment performed by the sensor control unit 140 described in the first embodiment.

The above is the configuration of the operation support system according to the present embodiment. Next, operations performed by the sensor control unit 140 of this embodiment will be described with reference to FIG. 11 .

After acquiring each measurement result in step S103, the sensor control unit 140 transmits each measurement result to the server 40 in step S115, and checks whether or not the determination result has been received from the server 40 in step S116. judge. When the sensor control unit 140 determines that the determination result has not been received (that is, S116: NO), the process ends.

On the other hand, when the sensor control unit 140 determines that the determination result has been received (that is, step S116: YES), in step S105, it determines whether each biological information is normal based on the received determination result. judge.

Then, if the sensor control unit 140 determines that there is an abnormality in the biometric information and that there is a response from the user indicating that the biometric information is normal after notifying the user (that is, step S108: YES), step A biological threshold adjustment signal is transmitted to the server 40 in S117. Thereafter, the sensor control unit 140 performs predetermined processing in step S111, and ends this processing.

Next, operations performed by the server control unit 420 of this embodiment will be described with reference to FIG. 12 .

In step S301, the server control unit 420 determines whether or not the measurement result has been received, and if it determines that the measurement result has been received (that is, step S301: YES), whether the biological information is normal. A determination is made as to whether or not Then, the server control unit 420 transmits the determination result to the wearable sensor 10 in step S303.

After transmitting the determination result, or when determining that the measurement result has not been received (that is, step S301: NO), the server control unit 420 receives the biological threshold adjustment signal in step S304. Determine whether or not When the server control unit 420 determines that the biological threshold adjustment signal has been received (that is, step S304: YES), it adjusts the biological threshold. After adjusting the biological threshold value, or when determining that the biological threshold value adjustment signal has not been received (that is, step S304: NO), the server control unit 420 ends this process.

As described above, in the present embodiment, the server 40 determines the biometric information and adjusts the biometric threshold. Therefore, the configuration of the sensor control unit 140 in the wearable sensor 10 can be simplified, and the increase in size of the wearable sensor 10 can be suppressed.

(Modified example of the fourth embodiment)
In the fourth embodiment described above, the combination of the processing executed by the wearable sensor 10 and the processing executed by the server 40 may be changed as appropriate. For example, the sensor control unit 140 may determine the biometric information, and the server control unit 420 may adjust the biometric threshold and transmit it to the sensor control unit 140 . Even with such a configuration, the configuration of the wearable sensor 10 can be simplified compared to the case where the wearable sensor 10 performs all the processing, and the same effects as those of the fourth embodiment can be obtained.

(Other embodiments)
The present invention is not limited to the above-described embodiments, and can be appropriately modified within the scope of the claims.

For example, in each of the above-described embodiments, the measurement unit 120 that measures the user's biological information may be configured to include an electroencephalogram measurement unit, a blood flow measurement unit, and the like. Alternatively, a MEMS microphone or the like for inputting the user's response in the audio device 131 may be used as the measurement unit 120, and the sensor control unit 140 may determine biometric information based on the strength and content of the user's voice. . Furthermore, the measuring section 120 may be composed of only one measuring section.

Further, in each of the above embodiments, the case where the user is the driver has been described, but the same processing may be performed for the user seated in the front passenger seat or the rear seat. For example, when the wearable sensor 10 is worn by a user sitting in the front passenger seat, if the biological information of the user is abnormal, the sedation unit 220 is controlled based on the biological information of the user. can be If different bio-sedation signals are sent to the vehicle control unit 250 for the driver and the user sitting in the front passenger seat, the driver's bio-sedation signal may be prioritized. Effects similar to those of the above-described embodiments can be obtained.

Furthermore, in each of the above embodiments, if the sensor control unit 140 can determine whether or not the user wearing the wearable sensor 10 is a driver, the configurations of the sensor communication unit 110 and the vehicle communication unit 210 can be changed as appropriate. It is possible. For example, vehicle communication unit 210 may be configured to have a plurality of communication units installed separately from each other in the vehicle interior. Then, the sensor control unit 140 grasps the communication strength with the communication units installed in the vehicle interior, and determines whether or not the user is the driver based on the communication strength with each communication unit. good. For example, the sensor control unit 140 determines whether or not the user is a driver by determining whether or not the communication strength with the communication unit, which has the highest communication strength when the user is a driver, is the highest. You may make it judge.

Furthermore, in each of the above embodiments, the input/output unit 130 may be divided into an input unit and an output unit. For example, the audio device 131 may separately control a speaker as an output unit and a MEMS micro fan as an input unit.

In the first to third embodiments described above, if the user is not the driver, the sensor control unit 140 may not acquire biometric information or determine whether the biometric information is abnormal. In this case, the biometric threshold for judging biometric information is set based on information when the user is a driver. Therefore, it is possible to highly accurately set the biometric threshold for the biometric information when the user is a driver. Similarly, in the above-described third embodiment, the sensor control unit 140 may not perform emotion estimation when the user is not the driver. Furthermore, in the fourth embodiment, if the user is not the driver, the sensor control unit 140 may not acquire the biometric information, and the server control unit 420 may not determine the biometric information. can be

Further, in each of the above-described embodiments, when the sensor control unit 140 determines that the biological information is abnormal, the sensor control unit 140 does not perform notification from the input/output unit 130, and transmits the content of the notification to the vehicle control unit 250. good too. Then, upon receiving the content, the vehicle control unit 250 may notify that the biological information is abnormal from the navigation device 230 or the like. In other words, when the sensor control unit 140 determines that the biological information is abnormal, the user is notified that the biological information is abnormal. Similarly, in the third embodiment, the sensor control unit 140 may notify the estimated emotion from the navigation device 230 or the like.

In each of the above embodiments, when the sensor control unit 140 determines that the biological information is abnormal, the sensor control unit 140 may transmit the biological sedation signal regardless of the response from the user. Further, in the above-described third embodiment, the emotional calming signal may be transmitted regardless of the response from the user.

Further, in each of the above-described embodiments, the biometric threshold for judging biometric information when the user is a driver may be changed according to the state before the user is seated in the driver's seat. For example, if the user's sleep time is short (eg, less than 5 hours), it is assumed that the user will be more easily distracted. In this case, the sensor control unit 140 may compare the sleep duration of the user with the sleep threshold, and set the biometric threshold low to make the determination regarding the biometric information stricter if the sleep duration is shorter than the sleep threshold. That is, the sensor control unit 140 adjusts the biological threshold so that it becomes more difficult to determine that the biological information is normal when the user's sleep time is shorter than the sleep threshold than when the sleep time is equal to or greater than the sleep threshold. You may make it

Whether or not the user is asleep may be determined, for example, by providing a clock, a counter, or the like inside the wearable sensor 10, or by user's operation. . Furthermore, whether or not the user is sleeping may be determined by equipping the wearable sensor 10 with an electroencephalogram measuring unit or the like, or by equipping the wearable sensor 10 with an acceleration sensor or the like, and determining whether the user is sleeping or not based on the posture of the user. It may be determined by

In addition, the biometric threshold for judging biometric information when the user is a driver may be changed according to the user's driving history. For example, if the user has an accident history in which he or she has had an accident in the past, the biometric threshold may be set low to strictly determine the biometric information. That is, the sensor control unit 140 adjusts the biometric threshold so that it becomes more difficult to determine that the biometric information is normal when the user's operation history includes an accident history than when the user's operation history does not include an accident history. You may do so.

Incidentally, whether or not the user has caused an accident in the past can be determined by, for example, storing accident information in an IC chip mounted on a driver's license, and the sensor control unit 140 reads the information on the IC chip. It may be determined by Further, whether or not the user has caused an accident in the past may be determined by the user's operation.

Furthermore, in each of the embodiments described above, the wearable sensor 10 and the vehicle 20 may be configured so that an electronic key system is applied. In other words, the wearable sensor 10 and the vehicle 20 transmit and receive a confirmation signal such as ID authentication between the sensor control unit 140 and the vehicle control unit 250, and based on the result, perform operations including locking and unlocking the door. It may be configured to apply an electronic key system. That is, the wearable sensor 10 may also function as an electronic key in an electronic key system.

Each of the above embodiments can also be applied to the vehicle 20 in which the driving support device 240 is not installed.

Further, in the third embodiment, the vehicle control unit 250 may give priority to control according to the biological sedation signal when executing different controls for the biological sedation signal and the emotional sedation signal.

Further, each of the above embodiments can be combined as appropriate. For example, the second embodiment may be combined with the third and fourth embodiments, and the sensor control unit 140 may transmit the contact signal after transmitting the emergency signal.

Further, the above third embodiment may be combined with the above fourth embodiment, and the server 40 may estimate the emotion and adjust at least one of the partial regression coefficient and the emotion threshold. In this case, since the wearable sensor 10 transmits the measurement result of the biological information to the server 40 , the server control unit 420 estimates the emotion and transmits the estimation result to the wearable sensor 10 . Then, if the response from the user after notification of the estimated emotion is "I am calm" or the like, the wearable sensor 10 transmits to the server 40 an emotion threshold adjustment signal for adjusting the emotion threshold based on the response. You can do it like this. Furthermore, when the wearable sensor 10 transmits the emotion threshold adjustment, the server control unit 420 may adjust at least one of the partial regression coefficient and the emotion threshold.

Further, combinations of the above embodiments may be further combined.

10 wearable sensor 20 vehicle (moving body)
110 sensor communication unit 120 measurement unit 140 sensor control unit

Claims (15)

A wearable sensor that is worn by a user and performs predetermined processing based on the user's biological information,
a measurement unit (120) for measuring the user's biological information;
a sensor communication unit (110) configured to be communicable with a mobile communication unit (210) mounted on a mobile object (20) that can move by being operated by the user;
a sensor control unit (140) connected to the measurement unit and the sensor communication unit;
The sensor control unit
determining whether or not the user is an operator of the mobile object according to a communication state between the sensor communication unit and the mobile communication unit;
When it is determined that the user is the operator of the moving object, the biological information is acquired from the measurement unit, and whether or not the biological information is normal is determined based on a predetermined biological threshold. When it is determined that the information is abnormal, the user is notified that the biological information is abnormal, and the moving body is controlled to calm the notified biological information. send a bio-sedation signal to
Further, the measurement unit measures the biometric information even when the user is not the operator, and when the user is determined to be the operator, the biometric information is measured more than when the user is determined not to be the operator. A wearable sensor that shortens the intervals at which the biometric information is measured by the measuring unit . The sensor control unit
Performing multiple regression analysis based on a regression equation in which a predetermined partial regression coefficient (β(ti)) is set, calculating a plurality of emotion values of the user based on the biometric information, and calculating the plurality of emotion values and the emotional threshold set for each,
If there is one emotion value greater than the emotion threshold, the emotion indicated by the emotion value is estimated to be the emotion of the user, and the emotion value greater than the emotion threshold is estimated to be the emotion of the user. If there are a plurality of emotions, the emotion indicated by the emotion value having the largest difference from the emotion threshold is estimated to be the emotion of the user, and the estimated emotion is notified to the user; 2. The wearable sensor according to claim 1, wherein the wearable sensor transmits an emotion-calming signal that causes the mobile body to perform the control that calms the emotion to be notified. A wearable sensor that is worn by a user and performs predetermined processing based on the user's biological information,
a measurement unit (120) for measuring the user's biological information;
a sensor communication unit (110) configured to be communicable with a mobile communication unit (210) mounted on a mobile object (20) that can move by being operated by the user;
a sensor control unit (140) connected to the measurement unit and the sensor communication unit;
The sensor control unit
determining whether or not the user is an operator of the mobile object according to a communication state between the sensor communication unit and the mobile communication unit;
When it is determined that the user is the operator of the moving object, the biological information is acquired from the measurement unit, and whether or not the biological information is normal is determined based on a predetermined biological threshold. When it is determined that the information is abnormal, the user is notified that the biological information is abnormal, and the moving body is controlled to calm the notified biological information. send a bio-sedation signal to
Furthermore, multiple regression analysis is performed based on a regression equation in which a predetermined partial regression coefficient (β(ti)) is set, and the values of the plurality of emotions of the user are calculated based on the biological information, and the plurality of emotions are calculated based on the biological information. Compare the value of and the emotional threshold set for each,
If there is one emotion value greater than the emotion threshold, the emotion indicated by the emotion value is estimated to be the emotion of the user, and the emotion value greater than the emotion threshold is estimated to be the emotion of the user. If there are a plurality of emotions, the emotion indicated by the emotion value having the largest difference from the emotion threshold is estimated to be the emotion of the user, and the estimated emotion is notified to the user; A wearable sensor that transmits an emotion-calming signal that causes the mobile object to execute the alerted emotion-calming control . If the sensor control unit determines that there is a response from the user indicating that the emotion is different from the emotion after the user is notified of the emotion, the sensor control unit determines that at least the partial regression coefficient and the emotion threshold 4. The wearable sensor according to claim 2 or 3 , wherein either one is adjusted. When the sensor control unit determines that there is no response from the user after the user is informed that the biological information is abnormal, the sensor control unit causes the moving body to be disabled from the user's operation. 5. The wearable sensor according to any one of claims 1 to 4, which transmits an emergency signal that causes a set control to be executed when the wearable sensor. The sensor communication unit is configured to be communicable with a predetermined communication terminal (30),
When the sensor control unit determines that there is no response from the user after the user is notified that the biological information is abnormal, the sensor control unit determines that the communication terminal has no response from the user. 6. The wearable sensor according to claim 5 , which transmits a contact signal indicating the. If the sensor control unit determines that there is a response indicating that the biological information is normal from the user after notifying the user that the biological information is abnormal, the sensor control unit sets the biological threshold. 7. The wearable sensor according to any one of claims 1 to 6 , wherein the wearable sensor performs adjustment. The sensor control unit grasps the sleep time of the user, and when it is determined that the sleep time is shorter than a predetermined sleep threshold, the sleep time is longer than when it is determined that the sleep time is equal to or greater than the predetermined sleep threshold. The wearable sensor according to any one of claims 1 to 7 , wherein the biological threshold is adjusted so that it becomes difficult to determine that the biological information is normal. The sensor control unit grasps the past operation history in which the user operated the moving object, and determines that the operation history includes an accident history, the operation history does not include an accident history. The wearable sensor according to any one of claims 1 to 8 , wherein the biological threshold is adjusted so that it becomes difficult to determine that the biological information is normal than when it is determined that the biological information is normal. the moving body is a vehicle,
The sensor control unit performs operations including locking and unlocking the doors of the vehicle by transmitting and receiving a predetermined confirmation signal to and from a vehicle control unit (250) mounted on the vehicle. 10. The wearable sensor according to any one of claims 1 to 9, which also functions as an electronic key. An operation support system that performs predetermined processing according to the state of a user sitting on an operation seat of a mobile object,
A wearable sensor (10) that is worn by the user and performs predetermined processing based on the user's biological information;
a mobile body (20) that is operable by the user;
The wearable sensor is
a measurement unit (120) for measuring the user's biological information;
a sensor communication unit (110) configured to be communicable with a mobile communication unit (210) mounted on a mobile object (20) that can move by being operated by the user;
a sensor control unit (140) connected to the measurement unit and the sensor communication unit;
The sensor control unit
determining whether or not the user is an operator of the mobile object according to a communication state between the sensor communication unit and the mobile communication unit;
When it is determined that the user is the operator of the moving object, the biological information is acquired from the measurement unit, and whether or not the biological information is normal is determined based on a predetermined biological threshold. When it is determined that the information is abnormal, the user is notified that the biological information is abnormal, and the moving body is controlled to calm the notified biological information. send a bio-sedation signal to
The moving body is
the mobile communication unit;
a calming unit (220) that performs a predetermined process;
a mobile control unit (250) connected to the mobile communication unit and the calming unit;
When the moving body control unit receives the biological sedation signal, the moving body control unit controls the sedation unit so that the biological information determined to be abnormal is sedated;
Furthermore, the sensor control unit
Performing multiple regression analysis based on a regression equation in which a predetermined partial regression coefficient (β(ti)) is set, calculating a plurality of emotion values of the user based on the biometric information, and calculating the plurality of emotion values and the emotional threshold set for each,
If there is one emotion value greater than the emotion threshold, the emotion indicated by the emotion value is estimated to be the emotion of the user, and the emotion value greater than the emotion threshold is estimated to be the emotion of the user. If there are a plurality of emotions, the emotion indicated by the emotion value having the largest difference from the emotion threshold is estimated to be the emotion of the user, and the estimated emotion is notified to the user; transmitting to the mobile body an emotion-calming signal that causes the alerted emotion-calming control to be executed;
The operation support system wherein, when the moving body control unit receives the emotional calming signal, the moving body control unit controls the calming unit so as to calm the emotion that triggered the emotional calming signal . When control of the sedation unit based on the biological sedation signal and control of the sedation unit based on the emotional sedation signal are different, the moving body control unit controls the sedation unit based on the emotional sedation signal. 12. The operation support system according to claim 11 , wherein priority is given to . An operation support system that performs predetermined processing according to the state of a user sitting on an operation seat of a mobile body,
A wearable sensor (10) that is worn by the user and performs predetermined processing based on the user's biological information;
a moving object (20) that can be operated by the user;
A server (30) configured to communicate with the wearable sensor,
The wearable sensor is
a measurement unit (120) for measuring the user's biological information;
a sensor communication unit (110) configured to be communicable with a mobile communication unit (210) mounted on a mobile object (20) that can move by being operated by the user;
a sensor control unit (140) connected to the measurement unit and the sensor communication unit;
The sensor control unit
determining whether or not the user is an operator of the mobile object according to a communication state between the sensor communication unit and the mobile communication unit;
When it is determined that the user is an operator of the mobile object, the biometric information is acquired from the measurement unit and transmitted to the server, and a determination result indicating that the biometric information is abnormal is transmitted from the server. Then, the user is notified that the biological information is abnormal, and the moving object is controlled to calm the notified biological information. send a sedative signal,
The moving body is
the mobile communication unit;
a calming unit (220) that performs a predetermined process;
a mobile control unit (250) connected to the mobile communication unit and the calming unit;
When the moving body control unit receives the biological sedation signal, the moving body control unit controls the sedation unit so that the biological information determined to be abnormal is sedated;
The server is
a server communication unit (410) configured to be communicable with the sensor communication unit;
a server control unit (420) that is connected to the server communication unit and performs predetermined processing;
When the biological information is transmitted from the sensor control unit, the server control unit determines whether or not the biological information is normal based on a predetermined biological threshold, and transmits the determination result to the wearable sensor. ,
Furthermore, when the biological information is transmitted from the wearable sensor, the server control unit
Performing multiple regression analysis based on a regression equation in which a predetermined partial regression coefficient (β(ti)) is set, calculating a plurality of emotion values of the user based on the biometric information, and calculating the plurality of emotion values and the emotional threshold set for each,
If there is one emotion value greater than the emotion threshold, the emotion indicated by the emotion value is estimated to be the emotion of the user, and the emotion value greater than the emotion threshold is estimated to be the emotion of the user. if there are multiple, the emotion indicated by the emotion value having the largest difference from the emotion threshold is estimated to be the emotion of the user, and the estimated emotion is transmitted to the wearable sensor;
The sensor control unit notifies the received emotion to the user, and sends an emotional sedation signal to the moving body so that control for calming the notified emotion is executed. send and
The operation support system wherein, when the moving body control section receives the emotional calming signal, the moving body control section controls the calming section so as to calm the emotion that triggered the emotional calming signal . If the sensor control unit determines that the user has responded that the biological information is normal after notifying the user that the biological information is abnormal, the sensor control unit sets the biological threshold. transmitting a biological threshold adjustment signal to be adjusted to the server;
4. The operation support system according to claim 1 , wherein the server control unit adjusts the biological threshold value when the biological threshold value adjustment signal is transmitted from the sensor control unit. When the sensor control unit determines that there is a response from the user indicating that the emotion is different from the emotion after the user is notified of the emotion, the sensor control unit provides an emotion threshold adjustment signal indicating the content of the response. to the server, and
15. The operation support system according to claim 1 , wherein the server control unit adjusts at least one of the partial regression coefficient and the emotion threshold when the emotion threshold adjustment signal is transmitted from the sensor control unit. .

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