JP2013061763A - Determining device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a determining device capable of more appropriately determining whether or not a user is in the condition where the user may feel stress.SOLUTION: The determining device comprises: acquisition means for acquiring predetermined information; determining means for determining whether or not the user is in the condition where the user may feel stress, using the acquired information; and execution means for executing a predetermined stress reduction action when the determining means determines that the user is in the condition where the user may feel stress.

Description

  The present invention relates to a determination device.

  Patent Document 1 discloses an in-vehicle navigation device that outputs predetermined voice guidance in consideration of user fatigue.

JP 2011-75395 A

  The in-vehicle navigation device described in the above document outputs a predetermined voice guidance according to the driving distance and driving time. However, with such a conventional technique, it cannot be determined whether or not the user who is driving is in a situation where the user feels stress.

  Therefore, an object of the present invention is to provide a determination apparatus that can more appropriately determine whether or not the user feels stress.

  In order to solve the above problems, a determination device according to the present invention includes an acquisition unit that acquires predetermined information, a determination unit that determines whether or not the user feels stress using the acquired information. And an execution means for executing a predetermined stress mitigation action when the determination means determines that the situation is such that the user feels stress.

  According to the determination apparatus according to the present invention, it is possible to more appropriately determine whether or not the user feels stress.

It is a figure which shows schematic structure of one Embodiment of this invention. It is a figure which shows schematic structure of the determination apparatus which concerns on one Embodiment of this invention. It is a figure which shows the area | region information which concerns on one Embodiment of this invention. It is a figure which shows the probe data which concern on one Embodiment of this invention. It is a figure which shows the imaging area of the vehicle-mounted camera which concerns on one Embodiment of this invention. It is a figure which shows the functional block of the determination apparatus which concerns on one Embodiment of this invention. It is a figure which shows the flow of the stress determination process A which concerns on one Embodiment of this invention. It is a figure which shows the flow of the stress determination process B which concerns on one Embodiment of this invention. It is a figure which shows the flow of the stress determination process C which concerns on one Embodiment of this invention. It is a figure which shows the flow of the detailed determination process a which concerns on one Embodiment of this invention. It is a figure which shows the flow of the detailed determination process b which concerns on one Embodiment of this invention. It is a figure which shows the flow of the detailed determination process c which concerns on one Embodiment of this invention. It is a figure which shows the flow of the detailed determination process d which concerns on one Embodiment of this invention. It is a figure which shows the flow of the detailed determination process e which concerns on one Embodiment of this invention. It is a figure which shows the flow of the stress reduction action process which concerns on one Embodiment of this invention.

  Hereinafter, a determination apparatus according to an embodiment of the present invention will be described.

  FIG. 1 is a diagram showing a schematic configuration of the present embodiment. As shown in the figure, the determination device 100 according to the present embodiment is connected to the vehicle control device 200 and determines whether or not the driving user feels stress.

  FIG. 2 is a diagram illustrating a schematic configuration of the determination apparatus 100. Here, the determination device 100 can be realized by a navigation device having a so-called navigation function such as searching for a recommended route or displaying traffic information.

  The determination device 100 includes an arithmetic processing device 1, a display 10, a storage device 11, a voice input / output device 13, an input device 16, a ROM device 20, a vehicle speed sensor 21, a gyro sensor 22, and a GPS receiver. 23, an FM multiplex broadcast receiving device 24, and a beacon receiving device 25. These devices and sensors are connected to each other via a bus 6 so that data can be exchanged.

  The arithmetic processing device 1 is a central unit that performs various processes of the determination device 100. The arithmetic processing device 1 specifies the current location of the user using information output from various sensors such as the vehicle speed sensor 21 and the gyro sensor 22, the GPS receiver 23, and the like.

  In addition, the arithmetic processing device 1 searches for a recommended route connecting the departure place and the destination using the map information 12 stored in the storage device 11.

  In addition, the arithmetic processing device 1 performs graphics conversion on the map information 12, traffic information, guidance route information, and the like, and outputs them to the display 10.

  In addition, the arithmetic processing device 1 generates voice information for performing route guidance and outputs this to the speaker 15.

  In addition, the arithmetic processing device 1 generates probe data at a predetermined timing (for example, every second) using predetermined information acquired from the vehicle control device 200. Details of the probe data will be described later.

  In addition, the arithmetic processing device 1 analyzes image information captured by the in-vehicle camera and determines whether or not a predetermined subject is captured.

  The arithmetic processing unit 1 includes a CPU 2 (Central Processing Unit) that executes various processes such as numerical calculations and control of each device and sensor, a RAM 3 that temporarily stores programs, data, calculation results, and the like. ROM 4 (Read Only Memory) for storing data and data, and an I / F (interface) 5 for connecting various types of hardware to the arithmetic processing unit. The CPU 2, RAM 3, and ROM 4 are connected to each other by a bus 6.

  The display 10 is a unit that displays graphics information generated by the arithmetic processing device 1 in a display area. The display 10 is composed of, for example, a liquid crystal display, an organic EL display, or the like.

  The storage device 11 is composed of at least a readable / writable recording medium such as an HDD (Hard Disk Drive) or a nonvolatile memory card. The storage device 11 stores, for example, map information 12, traffic information, route information, section information, dictionary information, and the like used for the navigation function.

  For example, the map information 12 stores area information including link information that is information related to roads on the map. FIG. 3 is a diagram showing the region information 300. The area information 300 is information including link information 303 included in each area on the map. The link means, for example, a road connecting nodes such as an intersection, and the link information 303 stores information on the road.

  The area information 300 includes, for each mesh ID 301 for identifying an area on the map, a road link ID 302 included in each mesh and link information 303 associated with each link ID 302. The link information 303 stores start point and end node point coordinates 304 indicating both ends of a road, road type information 305 indicating a road type such as a general road, a toll road, a national road, and a prefectural road, and a road name. Road name information 306, link length information 307 indicating the length of the road, travel time information 308 indicating the time required to pass the road, and other roads connected to each of the start node and end node of the road Start link / end link information 309 in which the link ID is stored, and speed limit information 310 in which the speed limit of the link is stored.

  Further, the storage device 11 stores, for example, probe data generated by the arithmetic processing device 1. FIG. 4 is a diagram showing the probe data 400. The probe data 400 includes, for example, predetermined information related to vehicle operations such as a steering wheel and an accelerator pedal, vehicle speed, and the like. Specifically, the probe data 400 includes a time field 401 in which the generation time of the probe data 400 is stored, a vehicle speed field 402 in which the vehicle speed is stored, an accelerator field 403 in which information on accelerator pedal operation is stored, a brake A brake field 404 that stores information related to pedal operation, an alarm field 405 that stores information related to operation of an alarm indicator (horn), a winker field 406 that stores information related to operation of a direction indicator, and a steering wheel A predetermined number of records (for example, a maximum of 1000 records) including a steering angle field 407 in which a steering angle corresponding to the amount of rotation is stored is provided. When the maximum number of accumulated records reaches, the oldest time is deleted in order.

  The accelerator field 403, the brake field 404, and the alarm field 405 store information such as “ON” or “OFF” as illustrated. For example, “ON” is stored in these fields in a record generated when the accelerator pedal and the brake pedal are depressed. Further, “ON” is stored in the alarm field 405 of the record generated when the alarm indicator is pressed (when the alarm is sounded). It should be noted that “ON” is continuously stored in the accelerator field 403 and the brake field 404 of the record generated while the accelerator pedal and the brake pedal are depressed.

  Returning to FIG. The voice input / output device 13 includes a microphone 14 as a voice input device 16 and a speaker 15 as a voice output device. The microphone 14 collects an external sound of the determination apparatus 100 such as a voice uttered by the user. The speaker 15 outputs a message to the user generated by the arithmetic processing device 1 as an audio signal.

  The input device 16 is a device for the determination device 100 to receive a predetermined instruction from the user. Specifically, it is composed of a direction key 17, a dial switch 18, a touch panel 19, a scale change key that is another hard switch (not shown), and the like.

  The direction key 17 includes, for example, eight hard switches indicating up / down / left / right and diagonal directions, and is used when selecting a menu item displayed on the display 10 or determining a scroll direction of a map image. Each direction indicated by the direction key 17 indicates the moving direction of the menu item to be selected and the moving direction of the display area of the display 10.

  The dial switch 18 is configured to be rotatable clockwise and counterclockwise, generates a pulse signal for every rotation of a predetermined angle, and outputs the pulse signal to the arithmetic processing device 1. The rotation angle of the dial switch 18 is obtained from the number of pulse signals input to the arithmetic processing unit 1.

  The touch panel 19 is mounted on the display surface side of the display 10 and can see through the display screen. The touch panel 19 detects a touch with a human finger or a touch with a dedicated touch pen. The touch position by the user is specified based on, for example, XY coordinates set on the touch panel 19. Such a touch panel 19 is configured by, for example, an input detection element using a capacitance method.

  The ROM device 20 includes at least a readable recording medium such as a ROM (Read Only Memory) such as a CD-ROM or a DVD-ROM, or an IC (Integrated Circuit) card. For example, moving image information, audio information, music information, and the like are recorded on the recording medium.

  The vehicle speed sensor 21, the gyro sensor 22, and the GPS receiver 23 are used to detect the current location of the vehicle on which the determination device 100 is mounted.

  The vehicle speed sensor 21 outputs information used for calculating the vehicle speed. Specifically, the vehicle speed sensor 21 converts the detected rotation speed of the wheel into a pulse signal, and outputs predetermined information such as the number of pulse signals within a predetermined time.

  The gyro sensor 22 is configured by an optical fiber gyro, a vibration gyro, or the like, and detects an angular velocity due to the rotation of the moving body.

  The GPS receiver 23 receives a signal from a GPS satellite, and measures the distance between the vehicle and the GPS satellite and the rate of change of the distance with respect to three or more satellites. Measure the heading.

  The FM multiplex broadcast receiver 24 receives an FM multiplex broadcast signal sent from an FM broadcast station. FM multiplex broadcasting includes VICS (Vehicle Information Communication System) information outline current traffic information, regulatory information, SA / PA (service area / parking area) information, parking lot information, weather information, etc. Information includes text information provided by radio stations.

  The beacon receiving device 25 receives rough current traffic information such as VICS information, regulation information, SA / PA (service area / parking area) information, parking lot information, weather information, emergency alerts, and the like. For example, it is a receiving device such as an optical beacon that communicates by light and a radio beacon that communicates by radio waves.

  Returning to FIG. 1 again, the vehicle control device 200 connected to the determination device 100 and each control unit of the vehicle will be described.

  The vehicle control device 200 is a control device that comprehensively controls the operation of the vehicle and the like. Specifically, vehicle control device 200 receives predetermined signals indicating that accelerator pedal 202 and brake pedal 204 have been depressed from ECU 201 and brake control unit 203, respectively. Further, the vehicle control device 200 receives a signal indicating the rotation amount of the handle 206 and a signal indicating that the alarm indicator 208 and the direction indicator 207 are operated from the handle control unit 205. Further, the vehicle control device 200 receives image information captured by the in-vehicle camera 209 from the in-vehicle camera 209.

  The ECU 201 (Engine Control Unit) performs predetermined control regarding the operation of the engine. For example, when receiving an engine start instruction, the ECU 201 starts the engine by the rotation of the cell motor. Further, the ECU 201 detects that the accelerator pedal 202 has been depressed, and controls the engine speed in accordance with the amount of depression of the pedal 202. Further, the ECU 201 outputs a vehicle speed signal received from a vehicle speed sensor (not shown) mounted on the vehicle to the vehicle control device 200. When ECU 201 detects that accelerator pedal 202 has been depressed, ECU 201 generates a signal indicating that and outputs the signal to vehicle control device 200.

  The brake control unit 203 performs predetermined control related to tire braking. For example, the brake control unit 203 detects that the brake pedal 204 has been depressed, and performs control such as increasing the braking force of the rear wheels so as not to cause understeer. In addition, when the brake control unit 203 detects that the brake pedal 204 has been depressed, the brake control unit 203 generates a signal indicating that and outputs the signal to the vehicle control device 200.

  The handle control unit 205 performs predetermined control by detecting that the handle 206, the direction indicator 207, and the alarm indicator 208 are operated. Specifically, the handle control unit 205 detects the amount of rotation of the handle 206 and calculates the steering angle from the amount of rotation. Further, the steering wheel control unit 205 outputs information regarding the calculated steering angle to the vehicle control device 200. Further, when the handle control unit 205 detects an operation on the direction indicator 207, the handle control unit 205 performs control to blink the blinker in the operation direction. In addition, the handle control unit 205 generates a signal indicating that the operation to the direction indicator 207 has been performed, and outputs the signal to the vehicle control device 200. Further, when the handle control unit 205 detects that the alarm indicator 208 has been pressed, it continues to output an alarm at a predetermined volume while the indicator is being pressed. In addition, the handle control unit 205 generates a signal indicating that the alarm indicator 208 has been pressed and outputs the signal to the vehicle control device 200.

  As shown in FIG. 5, the in-vehicle camera 209 is installed at a predetermined position of the vehicle, images a subject around the vehicle, and generates image information. Specifically, the in-vehicle camera 209 includes in-vehicle cameras O, P, Q, and R, and each of the vehicles capable of imaging the imaging areas o, p, q, and r at the front of the vehicle, the right side of the vehicle, the left side of the vehicle, and the rear of the vehicle. Installed in place. Note that the imaging areas o, p, q, and r are set to have a range of 3 m from the vehicle at a predetermined angle of view, for example.

  Further, each of the in-vehicle cameras O, P, Q, and R is synchronized with the arithmetic processing device 1 of the determination device 100, and is predetermined at a time interval (for example, 1 second) at which the probe data 400 is generated, for example Image information including the number of frames (for example, 5 frames) is generated. The in-vehicle camera 209 uses, for example, an image sensor such as a CCD (Charge-Coupled Device) or a CMOS (Complementary Metal Oxide Semiconductor) image sensor. The in-vehicle camera 209 outputs the generated image information to the vehicle control device 200.

  Next, functional blocks of the determination apparatus 100 according to this embodiment will be described. Note that the functional block of the determination apparatus 100 is constructed by executing a predetermined program read by the CPU 2 mounted on the arithmetic processing apparatus 1. Therefore, the ROM 4 stores a program for executing processing of each functional unit.

  Further, the functional blocks of the determination apparatus 100 are classified according to the main processing contents in order to facilitate understanding of the functions of the determination apparatus 100 realized in the present embodiment. Further, the present invention is not limited by the classification method of each function or its name. In addition, each structure of the determination apparatus 100 can also be classified into more structural elements according to the processing content. Moreover, it can also classify | categorize so that one component may perform more processes.

  Further, the functional unit of the determination apparatus 100 may be constructed by hardware (ASIC or the like). Further, the processing of each functional unit may be executed by one hardware or may be executed by a plurality of hardware.

  FIG. 6 is a diagram illustrating functional blocks of the determination apparatus 100. The determination apparatus 100 includes an overall control unit 501, a route search unit 502, a stress determination unit 503, and a stress reduction processing unit 504.

  The overall control unit 501 is a central functional unit that performs various processes of the determination apparatus 100. The overall control unit 501 receives predetermined information and instructions from other functional units, other devices built in the determination apparatus 100, sensors, and external devices. In addition, the overall control unit 501 outputs the acquired information and the received instruction to a predetermined sensor, device, or function unit according to the type or content of the information or instruction.

  The route search unit 502 uses the predetermined information output from the GPS receiver 23, the vehicle speed sensor 21, and the gyro sensor 22 to identify coordinate information indicating the current location of the vehicle. The route search unit 502 is a functional unit that searches for a route that connects a current location or a specified departure location to a destination set by the user. For example, the route search unit 502 uses a Dijkstra method or the like to search for a recommended route with a minimum cost that connects a current location or a departure location received from a user and a destination. In addition, the route search unit 502 outputs information related to the searched recommended route to the overall control unit 501.

  The stress determination unit 503 is a functional unit that determines whether or not the user is in a stress situation. Specifically, the stress determination unit 503 performs stress determination using image information and stress determination using the probe data 400.

  The stress reduction processing unit 504 is a functional unit that performs a predetermined stress reduction process preset by the user. For example, the stress reduction processing unit reproduces a CD-ROM accommodated in the ROM device 20 or outputs an FM broadcast program received by the FM multiplex broadcast receiving device 24 from the speaker 15.

  [Description of Operation] Next, the stress determination process executed by the determination apparatus 100 will be described. The stress determination processing according to the present embodiment includes stress determination processing A and B performed using image information, and stress determination processing C performed using probe data 400. The determination apparatus 100 executes each of the stress determination processes A to C in parallel.

  FIG. 7 is a flowchart of the stress determination process A. In the stress determination process A, since the situation that the same vehicle is running side by side for more than a predetermined time on the four sides of the vehicle is considered to be a factor that causes the user to feel stress, in order to determine whether or not this is the situation This is a process to be performed. Note that the stress determination process A is started when the determination apparatus 100 is activated.

  When the determination apparatus 100 is activated, the stress determination unit 503 outputs the vehicle surrounding image information generated by each of the in-vehicle cameras O, P, Q, and R at a predetermined timing (for example, every second). (Step S001).

  When the image information is acquired (step S001), the stress determination unit 503 generates overhead image information (step S002). Specifically, the stress determination unit 503 generates an overhead image using image information of the imaging areas o, p, q, and r around the vehicle. The bird's-eye view image is generated by converting the viewpoint of the image captured by each vehicle-mounted camera 209. For such viewpoint conversion, for example, a well-known technique for generating a bird's-eye view image by rearranging pixels of each image using a conversion formula that defines pixel arrangement before and after viewpoint conversion may be used. Note that the conversion formula or the like may be stored in advance in the storage device, for example.

  When the bird's-eye view image is generated (step S002), the stress determination unit 503 determines whether the same vehicle is running side by side in the four directions around the host vehicle for a predetermined time or longer (for example, 3 minutes or longer) (step S003). ). Specifically, the stress determination unit 503 specifies the feature points of the vehicle in each imaging area using an overhead image, and the feature points are included in each imaging area for a predetermined time or more (for example, 3 minutes or more). By tracking whether or not the same vehicle is running in parallel for each imaging area, it is determined.

  When it is determined that the same vehicle is running side by side for a predetermined time or more in each of the imaging areas o, p, q, r set in the four directions of the own vehicle (Yes in step S003), the stress determination unit 503 An instruction for executing the stress reduction action is generated and output to the stress reduction processing unit (step S004), and the process returns to step S001.

  Here, FIG. 15 is a flowchart showing the processing of the stress reduction action. When the stress reduction processing unit 504 receives an instruction to execute a stress reduction action, the stress reduction processing unit 504 starts such processing.

  When receiving the instruction, the stress reduction processing unit 504 determines whether or not the stress reduction action flag is ON (step S101). The stress reduction action flag is set to ON when the stress reduction action is executed. In addition, when the stress reduction processing unit 504 ends the stress reduction action, the stress reduction processing unit 504 sets the flag to OFF.

  As a result of the determination, if the flag is ON (Yes in step S101), the stress reduction processing unit 504 ends the stress reduction action process. That is, the stress reduction processing unit 504 does not execute the stress reduction action. This is to prevent duplicate stress reduction actions.

  On the other hand, when the flag is OFF (No in step S101), the stress reduction processing unit 504 sets the flag to ON (step S102) and executes a predetermined stress reduction action (step S103). The stress reduction action may be set in advance by the user. For example, the stress reduction processing unit 504 reproduces a CD-ROM accommodated in the ROM device 20 according to a user setting. For example, when a music CD is accommodated in the ROM device 20, the user's stress is reduced by outputting predetermined music from a speaker.

  Also, the stress reduction processing unit 504 outputs the FM broadcast program received by the FM multiplex broadcast receiving device 24 from the speaker according to the user setting. Note that the stress reduction action is not limited to such processing, and for example, processing for opening a door window may be executed in accordance with user settings. By taking outside air into the vehicle, the user's stress is reduced.

  After executing the stress reduction action for a predetermined time (for example, 5 minutes), the stress reduction processing unit 504 ends the action (step S104), sets the flag to OFF (step S105), and performs the stress reduction action process. finish.

  Even in the stress determination processes B and C described later, even when a stress reduction action start instruction is received, the stress reduction processing unit 504 executes the same stress reduction action process as described above. Therefore, in the description of the stress determination processes B and C, the description of the stress reduction action process executed by the stress reduction processing unit 504 is omitted.

  Next, the stress determination process B will be described. FIG. 8 is a flowchart showing the stress determination process B. Whether the stress determination process B is in such a situation because the user feels the stress that the driver needs to drive more carefully when driving on a road with a warning sign such as popping out warning or falling rock warning This is done to determine whether or not. The stress determination process B is started when the determination apparatus 100 is activated.

  When the determination device 100 is activated, the stress determination unit 503 acquires image information obtained by imaging the imaging area o ahead of the vehicle with the vehicle-mounted camera o from the vehicle control device 200 (step S011).

  When the image information is acquired (step S011), the stress determination unit 503 determines whether a warning sign is detected (step S012). Specifically, the stress determination unit 503 performs determination processing based on whether or not a warning sign is included in the acquired image information. The determination as to whether or not the warning sign is reflected in the image may be detected using a conventional technique such as pattern matching processing using warning sign information stored in advance in the storage device.

  As a result of the determination, when a warning sign is detected from the acquired image information (Yes in step S012), the stress determination unit 503 outputs a stress reduction action start instruction (step S013). On the other hand, when a warning sign is not detected from the acquired image information (No in step S012), the stress determination unit 503 returns the process to step S011.

  Next, the stress determination process C performed using the probe data 400 will be described. FIG. 9 is a flowchart showing such processing. The stress determination process C is started when the determination apparatus 100 is activated.

  When the determination device 100 is activated, the stress determination unit 503 acquires the probe data 400 from the vehicle control device 200 (step S021). Specifically, the stress determination unit 503 acquires a record of the probe data 400 in which the latest time is stored from the storage device 11.

  When the probe data 400 is acquired (step S021), the stress determination unit 503 extracts the vehicle speed from the vehicle speed field 402 of the probe data 400 (step S022). And the stress determination part 503 determines whether the extracted vehicle speed is 0.1 km / h or more and less than 10.0 km / h (step S023).

  As a result of the determination, when the extracted vehicle speed is included in the above speed range (Yes in step S023), the stress determination unit proceeds to the detailed determination process a. On the other hand, when the vehicle speed is not included in the range (No in step S023), the stress determination unit 503 moves the process to step S024.

  Here, the detailed determination process a will be described. FIG. 10 is a flowchart showing the detailed determination process a. As illustrated, the stress determination unit 503 determines whether the steering angle stored in the steering angle field 407 of the handle 206 is larger than a predetermined angle (for example, 45 °) (step S031). Information indicating the predetermined angle used for the determination may be stored in a recording medium such as the storage device 11 in advance.

  As a result of the determination, when the extracted rudder angle is larger than the predetermined angle (Yes in step S031), the stress determination unit 503 moves the process to step S032. On the other hand, when the rudder angle is smaller than the predetermined angle, the stress determination unit 503 ends the detailed determination process a, and the process proceeds to step S026 (FIG. 9).

  When the rudder angle is larger than the predetermined angle (Yes in Step S031), the stress determination unit 503 determines whether or not the user has turned on the direction indicator 207 (Step S032). Specifically, the stress determination unit 503 determines whether or not the information stored in the blinker field 406 of the probe data 400 is “ON”.

  As a result of the determination, if the information in the winker field 406 is “ON”, that is, if the winker of the host vehicle is lit (Yes in step S032), the stress determination unit 503 moves the process to step S033. On the other hand, when the information of the winker field 406 is “OFF”, that is, when the winker of the own vehicle is not lit (No in step S032), the stress determination unit 503 ends the detailed determination process a, Goes to step S026 (FIG. 9).

  When the blinker is turned on (Yes in step S032), the stress determination unit 503 determines whether the current location is in the middle of the link, that is, whether the current location is not located on the node (intersection). (Step S033). Specifically, the stress determination unit 503 compares the distance between the coordinate information indicating the current location specified by the route search unit 502 and the coordinate information of the nodes around the current location, and the two are determined to be a predetermined distance (for example, 50 m ) To determine whether it is further away.

  As a result of the determination, if the current location and the nodes around the current location are more than a predetermined distance (for example, 50 m), the stress determination unit 503 determines that the current location is in the middle of the link (Yes in step S033), and stress A mitigation action start instruction is output (step S034). On the other hand, when both are not separated by a predetermined distance or more, the stress determination unit 503 ends the detailed determination process a, and proceeds to step S026 (FIG. 9).

  For example, when there is a vehicle or an obstacle that is stopped in front of the host vehicle, the stress determination process a can determine whether or not an operation for detouring the vehicle is performed. If it is determined that such an operation has been performed, it is considered that the user feels a stress of avoiding an obstacle. Therefore, the user's stress can be reduced by executing a predetermined stress reduction action. .

  Returning to the flowchart of FIG. 9, the description will be continued. When the vehicle speed stored in the vehicle speed field 402 of the probe data 400 is not 0.1 km / h or more and less than 10.0 km / h (No in step S023), the stress determination unit 503 determines that the vehicle speed is 0.0 km / h (stopped). State).

  As a result of the determination, when the vehicle speed is 0.0 km / h, the stress determination unit 503 proceeds to the detailed determination process b. On the other hand, when the vehicle speed is not 0.0 km / h, the stress determination unit 503 moves the process to step S025.

  Here, the detailed determination process b will be described. FIG. 11 is a flowchart showing the detailed determination process b. As illustrated, the stress determination unit 503 determines whether or not the current location is within a predetermined distance (for example, within 50 m) from the node (step S041). Specifically, the stress determination unit 503 uses the coordinate information indicating the current location specified by the route search unit 502 to determine whether or not the distance to a node around the current location is within a predetermined distance. .

  As a result of the determination, if the current location is within a predetermined distance from the node (Yes in step S041), the stress determination unit 503 moves the process to step S042. On the other hand, when the distance between the current location and the node is larger than the predetermined distance (No in step S041), the stress determination unit 503 moves the process to step S043.

  If the current location is within a predetermined distance from nodes around the current location (Yes in step S041), the stress determination unit 503 determines whether a blue signal is detected from the image information (step S042). Specifically, the stress determination unit 503 acquires image information generated at the timing when the probe data 400 is acquired, and image information obtained by imaging the imaging area o in front of the vehicle from the vehicle control device 200.

  In addition, the stress determination unit 503 performs processing for specifying a circular subject having a blue color and a predetermined size or larger in the acquired image information. Note that the subject may be identified by using, for example, a conventional technique for identifying an object by recognizing a luminance difference or a color. If a blue signal is detected from the image information (Yes in step S042), the stress determination unit 503 moves the process to step S043. On the other hand, when a blue signal is not detected from the image information (No in step S042), the stress determination unit 503 ends the detailed determination process b, and the process proceeds to step S026 (FIG. 9).

  In step S043, the stress determination unit 503 determines whether or not the direction indicator 207 of the preceding vehicle is lit. Specifically, the stress determination unit 503 acquires image information obtained by imaging the imaging area o in front of the vehicle from the vehicle control device 200 and analyzes the image information, similarly to the detection of the green light. Then, when it is detected from the image information that the direction indicator 207 of the preceding vehicle is turned on (Yes in step S043), the stress determination unit 503 outputs a stress reduction action start instruction (step S044). On the other hand, when it is not detected that the direction indicator 207 of the preceding vehicle is lit (No in step S043), the stress determination unit 503 ends the detailed determination process b, and the process proceeds to step S026 (FIG. 9). Transition.

  Such a stress determination process b can determine, for example, whether or not the vehicle ahead is stopped to turn right at a place where there is no intersection or traffic light. If it is determined that the vehicle is to stop for a right turn, it is considered that the user feels the stress of waiting for a right turn. Therefore, the user's stress can be reduced by executing a predetermined stress reduction action. Can do.

  Returning to the flowchart of FIG. 9, the description will be continued. When the vehicle speed stored in the vehicle speed field 402 of the probe data 400 is not 0.0 km / h (No in step S024), the stress determination unit 503 determines that the vehicle speed that is 20 km / h or more lower than the speed limit is in the vehicle speed field 402. It is determined whether it is stored. When the speed limit of the link with the current location is 30 km / h or less, the stress determination unit 503 determines whether the vehicle speed in the vehicle speed field 402 is a speed included in the range of 30% to 50% of the speed limit. judge.

  As a result of determination, when the vehicle speed is 20 km / h or more lower than the speed limit, or when the speed limit is 30 km / h or less, the speed is within the range of 30% to 50% of the speed limit. (Yes in step S025), the stress determination unit 503 proceeds to the detailed determination process c. On the other hand, when it does not correspond to these (No in Step S025), the stress determination unit 503 moves the process to Step S026.

  Here, the detailed determination process c will be described. FIG. 12 is a flowchart showing the detailed determination process c. As shown in the figure, the stress determination unit 503 determines whether or not the distance from the preceding vehicle is within a predetermined distance (for example, within 3 m) (step S051). Specifically, the stress determination unit 503 calculates the inter-vehicle distance between the host vehicle and the preceding vehicle using image information obtained by imaging the imaging area o, and determines the distance. Note that the inter-vehicle distance may be a conventional technique that is calculated from adjustment of focal length, luminance difference between subjects, tone difference, and the like.

  As a result of the determination, when the inter-vehicle distance with the preceding vehicle is within a predetermined distance (for example, 3 m) (Yes in Step S051), the stress determination unit 503 moves the process to Step S052. On the other hand, when the inter-vehicle distance between the host vehicle and the preceding vehicle is greater than or equal to a predetermined distance, the stress determination unit 503 ends the detailed determination process c, and the process proceeds to step S026 (FIG. 9).

  When the inter-vehicle distance is within the predetermined distance (Yes in Step S051), the stress determination unit 503 determines whether or not the road where the current location is is a congested road (Step S052). Specifically, the stress determination unit 503 acquires coordinate information indicating the current location from the route search unit, and identifies a link with the current location from the coordinate information. Then, the stress determination unit 503 specifies from the VICS information whether or not there is a traffic jam on the road where the current location is.

  As a result of the determination, when the road with the current location is not congested (No in step S052), the stress determination unit 503 outputs an instruction to start the stress reduction action. On the other hand, when there is a traffic jam (Yes in step S052), the stress determination unit 503 ends the detailed determination process c and shifts the process to step S026 (FIG. 9).

  Such a stress determination process c can determine whether or not the factor of low-speed traveling is a forward traveling vehicle. When it is determined that the low-speed driving factor is a forward-traveling vehicle, it is considered that the user feels stressed by low-speed driving. Therefore, the user's stress is reduced by executing a predetermined stress reduction action. Can be made. Such an example can be considered when traveling behind a bus vehicle or a vehicle with a beginner mark.

  Returning to the flowchart of FIG. 9, the description will be continued. The stress determination unit 503 determines whether or not the information stored in the accelerator field 403 or the brake field 404 of the probe data 400 is “ON” (step S026). If the information stored in any field is “ON”, the stress determination unit shifts the process to the detailed determination process d. On the other hand, when the information stored in both the accelerator field 403 and the brake field 404 is “OFF”, the stress determination unit 503 moves the process to step S027.

  Here, the detailed determination process d will be described. FIG. 13 is a flowchart showing the detailed determination process d. If it is determined in step S026 described above that the information in the accelerator field 403 is “ON”, the stress determination unit determines whether “OFF” is stored in the accelerator field 403 of the record immediately before the record having the field. Is determined (step S061). Similarly, when it is determined in step S026 that the information in the brake field 404 is “ON”, the stress determination unit 503 similarly sets “OFF” in the brake field 404 of the record immediately before the record having the field. It is determined whether it is stored (step S061).

  “ON” is continuously stored in the accelerator field 403 and the brake field 404 of the record generated while the accelerator pedal 202 and the brake pedal 204 are kept depressed. Therefore, the stress determination unit 503 determines whether “OFF” is stored in the corresponding field of the immediately preceding record in order to determine that the accelerator pedal 202 or the brake pedal 204 has been stepped on once.

  When “OFF” is stored in the accelerator field 403 or the brake field 404 of the immediately preceding record (Yes in step S061), the stress determination unit 503 moves the process to step S062. On the other hand, if “ON” is stored in the accelerator field 403 or the brake field 404 of the immediately preceding record (No in step S061), the stress determination unit 503 ends the detailed determination process d, and the process proceeds to step S027 (FIG. Move to 9).

  In step S062, the stress determination unit 503 performs the accelerator pedal 202 operation and the brake pedal operation a predetermined number of times or more within a predetermined time (for example, within 60 seconds) (for example, the accelerator pedal 202 operation and the brake pedal operation each 10 times). ) Determine whether it was done. Specifically, the stress determination unit 503 refers to the accelerator field 403 and the brake field 404 of the latest record of the probe data 400 and a predetermined number of records (for example, 60 records) older than the latest record, for a predetermined time. The number of pedal operations performed within (for example, within 60 seconds) is calculated.

  It should be noted that the stress determination unit 503 adds one pedal operation count only when “OFF” is stored in the field corresponding to the record immediately before the record storing “ON”. That is, the stress determination unit 503 stores “ON” stored in each record continuously when the pedal is continuously depressed, and stores “ON” in the first “ON”, that is, “OFF” in the immediately preceding record. Add what you have as one time.

  As a result of the determination, when the accelerator pedal 202 and the brake pedal are operated a predetermined number of times (for example, 10 times each of the accelerator pedal 202 operation and the brake pedal operation) within a predetermined time (for example, within 60 seconds) (step S062). In step S063, the stress determination unit 503 outputs a stress reduction action start instruction. On the other hand, when the total of both pedal operations is not more than the predetermined number of times within the predetermined time (No in step S062), the stress determination unit 503 ends the detailed determination process d, and the process proceeds to step S027 (FIG. 9). To do.

  Such a stress determination process d can determine whether or not the user has stepped on the accelerator pedal and the brake pedal many times in a short time. When many steps are taken, it is considered that the user is in a situation where he / she feels stress on the traveling vehicle ahead. Therefore, the user's stress can be reduced by executing a predetermined stress reduction action. Such an example can be considered when traveling behind a bus vehicle or a vehicle with a beginner mark.

  Returning again to FIG. 9, the description will be continued. In step S 027, the stress determination unit 503 determines whether “ON” is stored in the alarm field 405. If “ON” is stored as a result of the determination, the stress determination unit 503 proceeds to the detailed determination process e. On the other hand, when “OFF” is stored in the alarm field 405, the stress determination unit 503 shifts the processing to step S021.

  Here, the detailed determination process e will be described. FIG. 14 is a flowchart showing the detailed determination process e. If it is determined in step S027 (FIG. 9) that the information in the alarm field 405 is “ON”, the stress determination unit 503 stores “OFF” in the alarm field 405 of the record immediately before the record having the field. It is determined whether or not it has been done.

  “ON” is continuously stored in the alarm field 405 of the record generated while the alarm indicator 208 is kept pressed. Therefore, in order to determine that the alarm indicator 208 has been pressed once, the stress determination unit 503 determines whether “OFF” is stored in the corresponding field of the immediately preceding record.

  When “OFF” is stored in the alarm field 405 of the immediately preceding record (Yes in step S071), the stress determination unit 503 moves the process to step S072. On the other hand, when “ON” is stored in the alarm field 405 of the immediately preceding record (No in step S071), the stress determination unit 503 ends the detailed determination process e and proceeds to step S021 (FIG. 9). To do.

  In step S072, the stress determination unit 503 determines whether or not the alarm indicator 208 has been pressed a predetermined number of times (for example, 10 times or more) within a predetermined time (for example, within 60 seconds). Specifically, the stress determination unit 503 includes the latest record of the probe data 400 and a predetermined number of records older than the latest record (for example, 60 records) within a predetermined time (for example, within 60 seconds). ) To calculate the number of operations of the alarm indicator.

  Note that the stress determination unit 503 adds one operation number of the alarm indicator only when “OFF” is stored in the corresponding field of the record immediately before the record storing “ON”. That is, when the alarm indicator 208 is continuously pressed, the stress determination unit 503 continuously stores “ON” in each record as the first “ON”, that is, “OFF” in the immediately preceding record. Is added as one time.

  As a result of the determination, when the alarm indicator 208 is operated a predetermined number of times (for example, 10 times or more) within a predetermined time (for example, within 60 seconds) (Yes in step S072), the stress determination unit 503 reduces the stress. An action start instruction is output (step S073). On the other hand, when the operation of the alarm indicator 208 has not been performed more than a predetermined number of times within a predetermined time (No in step S072), the stress determination unit 503 ends the detailed determination process e and performs the process in step S021 (FIG. 9). Migrate to

  Such a stress determination process e can determine whether or not the user has pressed the alarm indicator many times in a short time. And when pushing many times, since it is thought that the user is in a situation where he / she feels stress on the traveling vehicle ahead, the user's stress can be reduced by executing a predetermined stress reduction action. Examples of such cases include a vehicle that is unfamiliar with driving and a case where the vehicle travels behind a vehicle that does not follow traffic rules.

  According to the invention according to this embodiment, it is possible to more appropriately determine whether or not the user feels stress.

  In the above-described embodiment, the predetermined stress reduction action is executed when a predetermined condition is satisfied in any one of the determination processes A and B and the detailed determination processes a to e. However, the present invention is not limited to this embodiment. It is not something that can be done. For example, as a modification of the present embodiment, a predetermined stress reduction action is executed only when a predetermined condition is satisfied in a plurality of determination processes. For example, a predetermined stress reduction action is executed only when it is determined that the user feels stress in three or more determination processes among the determination processes A and B and the detailed determination processes a to e.

  According to the invention according to such a modification, it is possible to more appropriately determine whether or not the user feels stress. In particular, the stress reduction action is not executed unless it is determined that there is a situation in which stress is felt by a plurality of determination processes, so that frequent execution of the stress reduction action can be avoided.

  In the above-described embodiment, the determination device is realized as an in-vehicle navigation device, but the present invention is not limited to such an embodiment. For example, a determination device may be mounted on a ship and a predetermined determination may be made to determine whether or not the user feels stressed. At that time, it is determined whether or not the user feels stress by applying a traffic rule at sea.

100: determination device, 1 ... arithmetic processing device,
10 ... display, 11 ... storage device,
13 ... voice input / output device, 16 ... input device,
20 ... ROM device, 21 ... vehicle speed sensor,
22 ... Gyro sensor, 23 ... GPS receiver,
24 ... FM multiplex broadcast receiver, 25 ... beacon receiver

Claims (10)

Obtaining means for obtaining predetermined information;
A determination means for determining whether or not the user feels stress using the acquired information;
An execution means for executing a predetermined stress reduction action when it is determined by the determination means that the situation is stressful;
A determination apparatus comprising: The determination apparatus according to claim 1, wherein:
The acquisition means acquires image information obtained by imaging the vehicle periphery,
The determination means includes
A determination apparatus characterized by determining that the user feels stress when detecting from the image information that the same vehicle is running around the vehicle for a predetermined time or more. The determination device according to claim 2,
The acquisition means acquires probe data in which information on vehicle speed and vehicle operation is stored,
The determination means includes
The determination apparatus characterized by determining that the user feels stress when information indicating a predetermined vehicle speed and a predetermined vehicle operation is stored in the probe data. The determination device according to claim 2,
The acquisition means acquires image information obtained by imaging a subject in an imaging area that is set on each of four sides of the vehicle,
The determination means includes
A determination apparatus characterized by determining that a user feels stress when it is detected that the same vehicle exists for a predetermined time or more for each imaging area. The determination device according to claim 1,
The acquisition means acquires image information obtained by imaging a subject in an imaging area set in front of the vehicle,
The determination means includes
A determination apparatus characterized by determining that a user feels stress when a predetermined subject is detected from the image information. The determination device according to claim 3,
The determination means includes
The determination apparatus characterized by determining that it is in a situation where the user feels stress when the vehicle speed, the steering angle, the information on the winker stored in the probe data, and the vehicle position on the map satisfy predetermined conditions. The determination device according to claim 3,
The determination means includes
When the vehicle speed stored in the probe data, the information about the blinker, and the vehicle position on the map satisfy a predetermined condition, and when a green signal is detected from the image information, it is determined that the user feels stressed. Characteristic determination device. The determination device according to claim 7, wherein
The acquisition means includes
If the vehicle position on the map does not satisfy a predetermined condition, obtain information on whether or not there is a traffic jam on a link where the vehicle is,
The determination means includes
A determination device that determines that the user feels stress when the link is not congested. The determination device according to claim 3,
The determination means includes
The determination apparatus characterized by determining that the user feels stress when information on the accelerator and brake stored in the probe data satisfies a predetermined condition. The determination device according to claim 3,
The determination means includes
The determination apparatus characterized by determining that the user feels stress when the information regarding the alarm stored in the probe data satisfies a predetermined condition.

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