JP6606952B2 - In-vehicle device control apparatus and in-vehicle device control method - Google Patents

Description

  The present invention relates to a vehicle-mounted device control apparatus and a vehicle-mounted device control method for controlling a device mounted on a vehicle.

  As a device that reduces the operational load on in-vehicle devices, recommends operations related to operations performed on in-vehicle devices to users using a probabilistic model such as Bayesian theory, and controls in-vehicle devices according to user responses An apparatus has been proposed (see Patent Document 1).

JP 2009-173182 A

  However, since the technique described in Patent Document 1 applies multiple individual probability models to in-vehicle devices and multiple types of operations of in-vehicle devices, the control is optimized when controlling a plurality of in-vehicle devices. A considerable number of responses (learning times) are required until then.

  An object of this invention is to provide the vehicle equipment control apparatus and vehicle equipment control method which can reduce operation of various vehicle equipment simply and efficiently in view of the said problem.

The in-vehicle device control apparatus stores operation patterns of a plurality of in-vehicle devices that are control targets associated in advance for each predetermined control point in the map information, determines an operation pattern to be executed from the stored operation patterns, and While the travel position is within the control region, the control target is controlled so as to execute the determined operation pattern, and when the vehicle is separated from the control region, the control target is returned to the previous state. The operation pattern has a plurality of stages that shift from the first stage to the time series within the control region, and the operation to be controlled is set for each of the plurality of stages.

  According to the present invention, the operation of various in-vehicle devices can be easily and efficiently reduced by executing the operation patterns of a plurality of in-vehicle devices associated in advance for each predetermined control point in the map information. A device control apparatus and a vehicle-mounted device control method can be provided.

FIG. 1 is a block diagram illustrating an example of a configuration of an in-vehicle device control apparatus according to an embodiment of the present invention. FIG. 2 is a flowchart for explaining an example of a vehicle-mounted device control method using the vehicle-mounted device control apparatus according to the embodiment of the present invention. FIG. 3 is a flowchart for explaining an example of a vehicle-mounted device control method using the vehicle-mounted device control apparatus according to the embodiment of the present invention. FIG. 4 is a flowchart for explaining an example of a vehicle-mounted device control method using the vehicle-mounted device control apparatus according to the embodiment of the present invention. FIG. 5 is a diagram illustrating an operation pattern in the first example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 6 is a diagram for explaining an operation pattern in the second example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 7 is a diagram illustrating an operation pattern in the third example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 8 is a diagram for explaining an operation pattern in the fourth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 9 is a diagram for explaining an operation pattern in the fifth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 10 is a diagram for explaining an operation pattern in the sixth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 11 is a diagram for explaining an operation pattern in the seventh example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 12 is a diagram illustrating an operation pattern in the eighth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 13 is a diagram for explaining an operation pattern in the ninth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 14 is a diagram for explaining an operation pattern in the tenth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 15 is a diagram for explaining an operation pattern in the eleventh example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 16 is a diagram for explaining an operation pattern in the twelfth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 17 is a diagram for explaining an operation pattern in the twelfth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 18 is a diagram for explaining an operation pattern in the thirteenth example of the in-vehicle device control apparatus according to the embodiment of the present invention. FIG. 19 is a diagram for explaining an operation pattern in the thirteenth example of the in-vehicle device control device according to the embodiment of the present invention. FIG. 20 is an example illustrating a display screen in a fourteenth example of the in-vehicle device control apparatus according to another embodiment of the present invention. FIG. 21 is an example illustrating a display screen in a fourteenth example of the in-vehicle device control apparatus according to another embodiment of the present invention. FIG. 22 is an example illustrating a display screen in a fourteenth example of the in-vehicle device control apparatus according to another embodiment of the present invention. FIG. 23 is an example illustrating a display screen in a fourteenth example of the in-vehicle device control apparatus according to another embodiment of the present invention. FIG. 24 is an example illustrating a display screen in a fourteenth example of the in-vehicle device control apparatus according to another embodiment of the present invention.

  Embodiments of the present invention will be described with reference to the drawings. In the description of the drawings, the same or similar parts are denoted by the same or similar reference numerals, and redundant description is omitted.

(In-vehicle device controller)
As shown in FIG. 1, the in-vehicle device control device according to the present embodiment includes a positioning device 10, a communication interface (I / F) 20, a sensor group 30, a storage device 40, a controller 50, and an input I. / F60 and a plurality of in-vehicle devices 8-1, 8-2, ..., 8-n. The in-vehicle device control apparatus according to the embodiment of the present invention is mounted on a vehicle, and various in-vehicle devices 8-1, 8-2,..., 8-n (hereinafter collectively referred to as “in-vehicle device 8”). To control.

  The in-vehicle device 8 includes, for example, a power window, a door mirror, a back view monitor, a side view monitor, an idling stop control device, a headlamp, a direction indicator, a room lamp, a door lock, a trunk lock, a sliding door, a buzzer, a display, and a speaker. Audio equipment, car navigation systems, various actuators, etc. are installed in vehicles and can be electronically controlled.

  The positioning device 10 measures the current position of the vehicle on the earth by a positioning system such as a global positioning system (GPS). The positioning device 10 is composed of, for example, a GPS receiver. The positioning device 10 sequentially outputs the measured current position to the controller 50.

  The communication I / F 20 is, for example, a communication device that transmits and receives signals to and from the outside wirelessly. The communication I / F 20 receives various information from the outside by an intelligent road traffic system (ITS) that transmits traffic information such as traffic jam information and traffic regulations, weather information, and the like in real time. ITS includes VICS (Vehicle Information and Communication System: registered trademark), telematics, and the like. The communication I / F 20 sequentially outputs the received information to the controller 50.

  The sensor group 30 includes, for example, a vehicle sensor that detects a running state of the vehicle such as a speed sensor, an acceleration sensor, an angular velocity sensor, a steering angle sensor, a bearing sensor, and a gear position sensor, a camera, a laser range finder (LRF), and an ultrasonic wave. It can be composed of ambient sensors that detect the ambient environment of the vehicle, such as sensors, millimeter wave sensors, infrared sensors, raindrop sensors, illuminance sensors, and watches. The vehicle sensors of the sensor group 30 detect the vehicle speed, the three-axis acceleration, the angular velocity, and the like in the three-dimensional orthogonal coordinate system by each sensor, and sequentially output the detection results to the controller 50. Driving of the surrounding sensors of the sensor group 30 is controlled by the controller 50, and the detection results are sequentially output to the controller 50.

  The storage device 40 includes a map information storage unit 41, an operation pattern storage unit 42, and an area storage unit 43. The storage device 40 can be composed of a semiconductor memory, a magnetic disk, or the like. In addition, the storage device 40 may store a program necessary for processing performed in the controller 50. Each unit constituting the storage device 40 may be constituted by one piece of hardware or a plurality of pieces of hardware.

  The map information storage unit 41 stores map information including, for example, roads, road types, facility information, and the like. The map information storage unit 41 stores a control point indicating a point where a predetermined in-vehicle device 8 is controlled. The map information storage unit 41 may include detailed information such as lanes for each road, roads, and features around the roads.

  The operation pattern storage unit 42 stores various operation patterns of the plurality of in-vehicle devices 8 that are control targets associated in advance for each control point in the map information. In the operation pattern, the operation of the in-vehicle device 8 for each of the first to third stages in the time series is set. For example, the first stage is a preparation stage, the second stage is an implementation stage, and the third stage is a post-processing stage. The operation pattern is set with a transition condition for transitioning between a plurality of stages. The transition condition can be a condition based on at least one of the travel position of the vehicle, the surrounding environment, and the travel state.

  The area storage unit 43 stores a control area that is an area for controlling the in-vehicle device 8 to be controlled based on the control point in the map information. The area storage unit 43 may store a function for calculating a control area corresponding to the control point. The function for calculating the control region may be set according to the type of the in-vehicle device 8 to be controlled, or may be set according to the speed of the vehicle.

  For example, the input I / F 60 receives a user operation and outputs a signal corresponding to the operation to the controller 50. The input I / F 60 may be integrally configured with one display of the in-vehicle device 8 as a touch panel display. The input I / F 60 can control the in-vehicle device 8 by outputting a signal corresponding to a user operation to the controller 50. The input I / F 60 includes a switch for operating the plurality of in-vehicle devices 8.

  The controller 50 includes a travel position acquisition unit 51, an information acquisition unit 52, a pattern determination unit 53, a control region calculation unit 54, a device control unit 55, and a learning processing unit 56. The controller 50 can be configured by, for example, a microcontroller that is an integrated circuit including a central processing unit (CPU), a memory, an input / output I / F, and the like. In this case, the CPU executes a computer program preinstalled in the microcontroller, thereby realizing a plurality of information processing units (51 to 56) constituting the controller 50. Each part which comprises the controller 50 may be comprised from integral hardware, and may be comprised from separate hardware. The microcontroller may also be used as an electronic control unit (ECU) used for other control related to the vehicle such as automatic driving control.

  The travel position acquisition unit 51 acquires the travel position of the vehicle in the map information based on the current position measured by the positioning device 10 and the momentum of the vehicle detected by the sensor group 30. The traveling position acquisition unit 51 further calculates the relative position of the vehicle with respect to the feature stored in the map information storage unit 41 from the position of the feature detected by the sensor group 30, You may make it acquire the detailed driving | running | working position of the vehicle in map information.

  The information acquisition unit 52 acquires various types of information from at least one of the communication I / F 20, the sensor group 30, the travel position acquisition unit 51, and the input I / F 60. The information acquired by the information acquisition unit 52 includes traffic information, weather information, information specified by the user via the input I / F 60, and the like in addition to the driving state of the vehicle, the surrounding environment, and the driving position. The information acquisition unit 52 may acquire information in response to the distance from the travel position to the control point being less than a predetermined threshold.

  The pattern determination unit 53 determines an operation pattern to be executed from the operation patterns stored in the operation pattern storage unit 42 based on the travel position and control region of the vehicle. The pattern determination unit 53 determines the vehicle status based on the information acquired by the information acquisition unit 52. The pattern determination unit 53 determines an operation pattern according to the vehicle situation from a plurality of operation patterns associated with one control point stored in the operation pattern storage unit 42 according to the determined vehicle situation. It may be.

  For example, the pattern determining unit 53 determines the vehicle pattern and determines the operation pattern in accordance with, for example, the distance from the travel position to the control point being less than a predetermined threshold. When there are a plurality of operation patterns associated with one control point, the pattern determination unit 53 may prompt the user to select using the input I / F 60 by displaying options indicating the operation pattern on the display.

  The control region calculation unit 54 calculates a control region in the map information as a region for controlling the control target based on the travel position and control point of the vehicle by a preset calculation method. The control area calculated by the control area calculation unit 54 is stored in the area storage unit 43. The control region calculation unit 54 may calculate the control region by reading the control region or the control region calculation function stored in the region storage unit 43. Further, the control area calculation unit 54 may be calculated according to the type of the in-vehicle device 8 to be controlled.

  The control area calculation unit 54 calculates a control area for each control point when the traveling position of the vehicle is a predetermined distance to the control point. At the time when the control region calculation unit 54 calculates the control region, the distance from the vehicle to the boundary of the control region is shorter than the distance from the vehicle to the control point.

  The device control unit 55 simultaneously controls the plurality of in-vehicle devices 8 such that the control target executes the operation pattern determined by the pattern determination unit 53 while the traveling position of the vehicle is within the control region. That is, the device control unit 55 reads the operation pattern determined by the pattern determination unit 53 from the operation pattern storage unit 42 so that the plurality of in-vehicle devices 8 to be controlled perform the operation pattern according to the vehicle situation. A plurality of in-vehicle devices 8 are controlled.

  The learning processing unit 56 includes an operation pattern stored in the operation pattern storage unit 42, a control region calculated by the control region calculation unit 54, and a control region stored in the region storage unit 43 by a user operation on the input I / F 60. When there is an input to change at least one of the above, each value is changed according to the input content. In addition, the learning processing unit 56, based on the travel history and the input from the input I / F 60, the storage contents of the operation pattern storage unit 42 and the region storage unit 43, functions and thresholds used for the processing of the control region calculation unit 54, and the like May be changed.

(In-vehicle device control method)
A vehicle-mounted device control method using the vehicle-mounted device control apparatus according to the embodiment of the present invention will be described with reference to the flowcharts of FIGS. The series of tasks shown in the flowcharts of FIGS. 2 to 4 are examples of the in-vehicle device control method, and each step may be omitted, changed in order, contents, or the like according to various conditions. The series of tasks shown in the flowcharts of FIGS. 2 to 4 may be processed in parallel with tasks that execute other operation patterns.

  First, in step S <b> 101, the travel position acquisition unit 51 acquires the travel position of the vehicle in the map information based on the current position measured by the positioning device 10 and the detection result of the sensor group 30.

  In step S <b> 102, the control region calculation unit 54 refers to the map information storage unit 41 and searches for a control point that exists in the traveling direction of the vehicle.

  In step S103, the control area calculation unit 54 refers to the operation pattern storage unit 42 and determines whether there is an operation pattern corresponding to the searched control point. If there is an operation pattern, the process proceeds to step S104. If there is no control point or operation pattern, the process is repeated from step S101.

  In step S104, the control region calculation unit 54 calculates a control region in the map information as a region for controlling the control target based on at least a control point by a preset calculation method.

  In step S105, the device control unit 55 determines whether or not the vehicle travel position acquired by the travel position acquisition unit 51 has reached the control region calculated in step S104. The device control unit 55 repeats the process of step S105 until the traveling position of the vehicle reaches the control region.

  In step S106, the information acquisition unit 52 acquires various types of information as information indicating the vehicle status from the communication I / F 20, the sensor group 30, and the like. The information indicating the state of the vehicle is, for example, at least one of the traveling position of the vehicle, the surrounding environment, and the traveling state.

  In step S107, the pattern determination unit 53 determines the state of the vehicle based on the information acquired in step S106, and executes from the operation pattern of the operation pattern storage unit 42 corresponding to the control point searched in step S102. The operation pattern to be determined is determined.

  In step S108, the device control unit 55 reads the control target and the operation end timing for each control target in the first stage from the operation pattern determined in step S107. The operation end timing means a stage at which the control object whose operation has been started in the first stage ends the operation.

  In step S109, the device control unit 55 reads a first transition condition, which is a condition for transitioning from the first stage to the second stage, from the operation pattern determined in step S107.

  In step S110, the device control unit 55 stores the current state of each in-vehicle device 8 to be controlled in the first stage.

  In step S111, the device control unit 55 controls each in-vehicle device 8 that is a control target in the first stage so as to start the first-stage operation among the operation patterns determined in step S107.

  In step S112, the device control unit 55 determines whether or not to shift to the second stage by determining whether or not the first shift condition read in S109 is satisfied. The device control unit 55 repeats the process of step S112 until it is determined that the first condition is satisfied and the process proceeds to the second stage.

  In step S113, the device control unit 55 determines whether there is an in-vehicle device 8 that is not the control target in the second stage among the control targets in the first stage, based on the operation end timing read in step S108. . If there is an in-vehicle device 8 that is not a control target in the second stage, the process proceeds to step S114, and if not, the process proceeds to step S115.

  In step S114, the device control unit 55 stops the operation of the in-vehicle device 8 that is not the control target in the second stage among the control targets in the first stage, and returns to the state stored in step S110.

  In step S115, the device control unit 55 reads the control target and the operation end timing for each control target in the second stage from the operation pattern determined in step S107. The operation end timing means a stage at which the control object whose operation has been started in the second stage ends the operation.

  In step S116, the device control unit 55 reads a second transition condition, which is a condition for shifting from the second stage to the third stage, from the operation pattern determined in step S107.

  In step S117, the device control unit 55 stores the current state of each in-vehicle device 8 to be controlled in the second stage.

  In step S118, the device control unit 55 controls each in-vehicle device 8 to be controlled in the second stage so as to start the second-stage operation among the operation patterns determined in step S107.

  In step S119, the device control unit 55 determines whether or not to shift to the third stage by determining whether or not the second transition condition read in S116 is satisfied. The device control unit 55 repeats the process of step S119 until it is determined that the second condition is satisfied and the process proceeds to the third stage.

  In step S120, the device control unit 55 determines whether there is an in-vehicle device 8 that is not the control target in the third stage among the control targets in the second stage, based on the operation end timing read in step S115. . If there is an in-vehicle device 8 that is not a control target in the third stage, the process proceeds to step S121, and if not, the process proceeds to step S122.

  In step S121, the device control unit 55 stops the operation of the in-vehicle device 8 that is not the control target in the third stage among the control targets in the second stage, and returns to the state stored in step S117.

  In step S122, the device control unit 55 reads the control target in the third stage from the operation pattern determined in step S107.

  In step S123, the device control unit 55 stores the current state of each in-vehicle device 8 to be controlled in the third stage.

  In step S124, the device control unit 55 controls each in-vehicle device 8 that is a control target in the third stage so as to start the third-stage operation in the operation pattern determined in step S107.

  In step S125, the device control unit 55 determines whether the traveling position of the vehicle has left the control region calculated in step S104. If it has left, the process proceeds to step S130. If it has not left, the process proceeds to step S126.

  In step S126, the device control unit 55 determines whether or not to end the operation in the third stage, for example, based on whether or not the ignition switch is turned off. If the operation ends, the process proceeds to step S127. If the operation does not end, the process returns to step S125.

  In step S127, the device control unit 55 controls each in-vehicle device 8 that is a control target in the third step so as to stop the operation in the third step.

  In step S128, the learning processing unit 56 performs the first operation or the second operation stored in the operation pattern storage unit 42 by the user's operation on the input I / F 60 between steps S108 to S126, and the control region calculation unit 54. It is determined whether or not there is an input for changing at least one of the control region calculated by the above and the control region stored in the region storage unit 43. If there is an input, the process proceeds to step S129. If there is no input, the process ends.

  In step S129, the learning processing unit 56 changes the control region calculated by the control region calculating unit 54 and the control region stored in the region storage unit 43 according to the input content from the input I / F 60, and performs processing. finish.

  In step S130, the device control unit 55 controls each in-vehicle device 8 that is a control target in the third step so as to stop the operation in the third step.

  In step S131, the device control unit 55 returns each in-vehicle device 8 to be controlled in the operation pattern determined in step S107 to the state stored in step S110.

  In step S132, the learning processing unit 56 performs the first operation or the second operation stored in the operation pattern storage unit 42 by the user's operation on the input I / F 60 between steps S108 to S126, and the control region calculation unit 54. It is determined whether or not there is an input for changing at least one of the control region calculated by the above and the control region stored in the region storage unit 43. If there is an input, the process proceeds to step S133. If there is no input, the process returns to step S101.

  In step S133, the learning processing unit 56 changes the control region calculated by the control region calculating unit 54 and the control region stored in the region storage unit 43 in accordance with the input content from the input I / F 60, and step S101. Return processing to.

(First embodiment)
FIG. 5 is a diagram showing an operation pattern in the first example according to the embodiment of the present invention. In the first embodiment, the operation pattern when the user's home is a house with a garage and the garage is a control point will be described as parking a. Note that configurations, operations, effects, and the like that are not described in the following examples are substantially the same as those in the above-described embodiment, and are not described here. The same applies to the embodiments.

  When the travel position of the vehicle reaches the control region calculated by the control region calculation unit 54 or the control region stored in the region storage unit 43, the device control unit 55 blinks the hazard lamp that is the control target in the first stage. And start the parking monitor. The parking monitor is an in-vehicle device that assists parking by presenting a surrounding image captured by a camera having a wide-angle lens to a driver by correcting distortion and the like on a display.

  In response to the gear position being shifted to the R range, which is the first transition condition, the device control unit 55 proceeds to the second stage, which is the implementation stage, to mute or reduce the audio sound, and the idling stop function Set to off. The driving of the hazard lamp and the parking monitor is continued from the first stage. During this time, the vehicle is parked in the garage. By muting the audio device, the driver can improve concentration in parking operation. By turning off the idling stop function, the inconvenience of idling stop during parking work is eliminated.

  In the second stage, the device control unit 55 may unlock the driver's seat or open the driver's seat window according to the driver's preference. As a result, the driver can check the surroundings of the vehicle by looking out from the vehicle without any operation on the power window or the door.

  In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 proceeds to the third stage, which is the post-processing stage, as a determination that the parking work in the parking space has been completed. . In response to the transition to the third stage, the device control unit 55 stops the operation of the in-vehicle device 8 that is the control target in the second stage. In the third stage, the device control unit 55 turns on the room lamp, stores the door mirror, and turns on the buzzer during locking and unlocking.

(Second embodiment)
FIG. 6 is a diagram showing an operation pattern in the second embodiment. In the second embodiment, an operation pattern in the case where the user's home is an apartment house with a three-dimensional parking lot such as a mechanical parking lot and a parking space for reversing and parking as a control point will be described as parking b.

  When the travel position of the vehicle reaches the entrance of the multistory parking area, the device control unit 55 causes the hazard lamp to be controlled in the first stage to blink. If a remote control for parking is required, a room lamp for creating the remote control may be turned on in the first stage.

  The device control unit 55 proceeds to the second stage in response to the vehicle travel position reaching the vicinity of the parking space, which is the first transition condition, and turns off the room lamp while continuing to blink the hazard lamp. . In the second stage, the device control unit 55 mutes the audio and sets the idling stop function to off. The driving of the hazard lamp and the parking monitor is continued from the first stage. During this time, the vehicle is parked in the garage. In the second stage, the device control unit 55 may unlock the driver's seat or open the driver's seat window according to the driver's preference.

  In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 determines that the parking work in the parking space has been completed, and enters the third stage, which is the post-processing stage. Transition. In response to the transition to the third stage, the device control unit 55 stops the operation of the in-vehicle device that is the control target in the second stage. In the third stage, the device control unit 55 turns on the room lamp, stores the door mirror, and turns on the buzzer during locking and unlocking.

(Third embodiment)
FIG. 7 is a diagram showing an operation pattern in the third embodiment. In the third embodiment, an operation pattern in the case where a family rides at night with a parking lot at a user's home as a control point will be described as parking c. The parking c is determined by the pattern determination unit 53 according to the vehicle status based on, for example, the time zone, day of the week, user operation on the input I / F 60, and the like.

  When the travel position of the vehicle reaches the road in front of the home, which is the control area calculated by the control area calculation unit 54 or the control area stored in the area storage unit 43, the device control unit 55 The position of the headlight is small. Thereby, the operation with respect to the headlamp of a user is not required, the amount of light irradiated to the surroundings of a home is reduced, and the influence on the surroundings of the home at night can be reduced.

  In response to the gear position being shifted to the R range, which is the first transition condition, the device control unit 55 proceeds to the second stage, which is the implementation stage, mutes the audio sound, and turns off the idling stop function. Set to. Further, in the second stage, the device control unit 55 tilts the door mirror downward and fixes the back view monitor to the on state. The back view monitor is an in-vehicle device that displays an image of the rear of the vehicle photographed by the camera on a display. The back view monitor is normally turned on only when the gear position is in the R range. The state where the position of the headlamp is small is continued from the first stage. During this time, the vehicle is parked in the garage.

  By tilting the door mirror downward, the driver can easily confirm the side lower side of the vehicle during parking. Further, by fixing the back view monitor on, the troublesomeness can be eliminated by repeating the on / off every time the gear position is shifted to the R range when the vehicle is parked.

  In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 proceeds to the third stage, which is the post-processing stage, as a determination that the parking work in the parking space has been completed. . In response to the transition to the third stage, the device control unit 55 stops the operation of the in-vehicle device that is the control target in the second stage. In the third stage, the device control unit 55 stores the door mirror, opens the slide door of the rear seat, and sets the buzzer at the time of locking and unlocking to OFF. The operation pattern is determined according to the vehicle situation, and the buzzer is turned off, so that the user's operation on each in-vehicle device 8 is not required, and the influence on the surroundings of the home at night can be reduced.

(Fourth embodiment)
FIG. 8 is a diagram showing an operation pattern in the fourth embodiment. In the fourth embodiment, an operation pattern in a case where a predetermined parking lot on the go is a control point will be described as parking d. The parking d is determined by the pattern determination unit 53 by entering a parking lot set as a control point, for example.

  The device control unit 55 determines that the traveling position of the vehicle has reached the control area by reaching a predetermined distance range from the entrance gate of the parking lot, for example, and proceeds to the first stage of parking d, Open the power window. As a result, the driver can operate the gate without operating the power window.

  The device control unit 55 shifts to the second stage in response to the vehicle speed being less than a predetermined threshold (for example, 4 km / h), which is the first transition condition. In the second stage, the device control unit 55 blinks the hazard lamp, mutes the audio device, sets the idling stop function to off, and fixes the back view monitor in the on state. As the first transition condition, a steering angle, an operation on a hazard lamp, a detection result of a parking frame, or the like may be used.

  In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 proceeds to the third stage as a determination that the parking work in the parking space has been completed. In response to the transition to the third stage, the device control unit 55 stops the operation of the in-vehicle device that is the control target in the second stage. In the third stage, the device control unit 55 turns on the room lamp, stores the door mirror, and turns on the buzzer at the time of locking and unlocking.

(5th Example)
FIG. 9 is a diagram showing an operation pattern in the fifth embodiment. In the fifth embodiment, the operation pattern when the child sitting on the rear seat gets on and off is described as parking e with the road near the kindergarten where the child passes as a control point.

  The equipment control unit 55 proceeds to the first stage of parking e in response to the traveling position of the vehicle reaching a control area that is a predetermined distance range from the control point. In the first stage, the device control unit 55 blinks the hazard lamp, turns on the side blind monitor, and tilts the door mirror downward. The side blind monitor is an in-vehicle device that displays an image of a blind spot on the side of the vehicle photographed by a camera on a display.

  The device control unit 55 shifts to the second stage in response to the first shift condition, that is, the travel position of the vehicle moves a predetermined distance to the control point side. In the second stage, the device control unit 55 mutes the audio device, sets the idling stop function to OFF, unlocks the driver's door lock, or opens the driver's seat power window. The blinking of the hazard lamp, the side blind monitor on, and the door mirror tilt are continued from the first stage. During the second phase, the vehicle is brought close to the shoulder.

  In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 proceeds to the third stage as a determination that the parking work on the road shoulder has been completed. In response to the transition to the third stage, the device control unit 55 stops the operation of the in-vehicle device that is the control target in the second stage. In the third stage, the device control unit 55 stores the door mirror, opens the slide door of the rear seat, and sets the buzzer at the time of locking and unlocking to ON.

(Sixth embodiment)
FIG. 10 is a diagram showing an operation pattern in the sixth embodiment. In the sixth embodiment, the operation pattern when reversing and parking with a three-dimensional parking lot as a control point will be described as parking f.

  The device control unit 55 determines that the traveling position of the vehicle has reached the control region by reaching a predetermined distance range from the entrance gate of the parking lot, and proceeds to the first stage of parking f, and the power of the driver seat Open the window.

  The device control unit 55 shifts to the second stage in response to the first transition condition, that is, when the traveling position of the vehicle changes by a predetermined distance (for example, 30 m) from the transition to the first stage. In the second stage, the device control unit 55 mutes the audio device, sets the idling stop function to OFF, tilts the door mirror downward, and sets the side blind monitor to ON.

  In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 proceeds to the third stage as a determination that the parking work in the parking space has been completed. In response to the transition to the third stage, the device control unit 55 stops the operation of the in-vehicle device that is the control target in the second stage. In the third stage, the device control unit 55 turns on the room lamp, stores the door mirror, and turns on the buzzer at the time of locking and unlocking.

(Seventh embodiment)
FIG. 11 is a diagram showing an operation pattern in the seventh embodiment. In the seventh embodiment, a highway is assumed to be a control point and a control area, and an operation pattern determined according to the traveling state of the vehicle is assumed to be a highway a.

  In response to the vehicle entering the highway, the pattern determining unit 53 determines the highway a, and the device control unit 55 proceeds to the first stage. In this case, the first stage is not a stage for controlling the in-vehicle device 8 but a stage for waiting for the transition to the second stage. The device control unit 55 continues the state of the first transition condition where the vehicle speed is within a predetermined speed range and the distance between the preceding vehicle and the preceding vehicle is within a predetermined distance range for a predetermined time (for example, 5 seconds). As a result, the second stage is entered.

  In the second stage, the device control unit 55 turns on the cruise control system. The cruise control system is a system that automatically controls acceleration / deceleration and torque of a vehicle by controlling an engine, an electric motor, a transmission, and the like independently of a driver's accelerator operation. The cruise control system maintains, for example, an ASCD (Auto Speed Control Device) that controls the vehicle speed at a constant level, a vehicle speed that is set when there is no preceding vehicle ahead, and a vehicle speed that is set in advance when there is a preceding vehicle ahead. ICC (Intelligent Cruise Control) etc. for controlling the inter-vehicle distance to be constant according to the above.

  For example, the device control unit 55 proceeds to the third stage in response to the lane change by the driver's operation, and turns off the cruise control system. Lane change may be detected by steering angle, lane detection, or the like. For example, when the vehicle changes lanes to the right lane, the device control unit 55 outputs a voice such as “please accelerate” from the speaker or displays characters on the display in the third stage. Encourage manual operation. Thereby, it is possible to reduce the shortage of the vehicle speed in the overtaking lane.

(Eighth embodiment)
FIG. 12 is a diagram showing an operation pattern in the eighth embodiment. In the eighth embodiment, an operation pattern in the case of executing a function for preventing a driver from falling asleep while driving for a long time with an expressway as a control point and a control area will be described as an expressway b.

  In response to the cruise control system being set to ON on the expressway, the pattern determining unit 53 determines the expressway b, and the device control unit 55 proceeds to the first stage. The device control unit 55 continues the state where the vehicle speed is within a predetermined speed range and the distance between the preceding vehicle and the preceding vehicle is within a predetermined distance range, which is the first transition condition, for a predetermined time (for example, 2 hours). As a result, the second stage is entered.

  In the second stage, the device control unit 55 turns on the massage function, turns on the aroma diffuser, and jets cold air to the air conditioner. When the massage function is turned on, the massage device in the driver's seat, which is an in-vehicle device, is driven to massage the driver's body. The state where the cruise control system is on is continued from the first stage. The aroma diffuser is an in-vehicle device that diffuses the fragrance of the filled fragrance, and the driver can wake up the driver's drowsiness by using oil or the like having the effect of waking up sleepiness as the fragrance.

  For example, the device control unit 55 shifts to the third stage when a predetermined time elapses from the shift to the second stage. The device control unit 55 stops the operation of the in-vehicle device that is the control target in the second stage. The state where the cruise control system is on is continued from the first stage. In the third stage, the device control unit 55 outputs a voice such as “Would you like to take a break?” From the speaker, and proposes a driving plan such as a break to the driver. The first transition condition and the second transition condition may be conditions based on the output of a sensor that detects the driver's biological information.

(Ninth embodiment)
FIG. 13 is a diagram for explaining an operation pattern in the ninth embodiment. In the ninth embodiment, an operation pattern when a highway is a control point and a control area and a vehicle travels on a long downhill will be described as a highway c.

  In response to the vehicle entering the highway, the pattern determining unit 53 determines the highway c, and the device control unit 55 proceeds to the first stage. The first stage is not a stage for controlling the in-vehicle device 8 but a stage for waiting for the transition to the second stage. The device control unit 55 shifts to the second stage in response to the traveling position of the vehicle, which is the first transition condition, entering a downhill section having a predetermined length or more in the highway. The downhill section may be detected from the map information or may be detected from the angular velocity sensor.

  The device control unit 55 sets the overdrive to OFF in the second stage. By setting the overdrive to OFF, the gear ratio of the transmission is not less than 1: 1, and it is possible to reduce the excessive increase in vehicle speed.

  In response to the traveling position of the vehicle leaving the downhill section, the device control unit 55 proceeds to the third stage and cancels the overdrive OFF setting. In the third stage, the device control unit 55 outputs a voice such as “Do you want to set the function?” From the speaker or displays characters on the display to turn off the overdrive for the driver executed in the second stage. We propose whether to set the function to The driver selects whether or not to set the function in the future by operating the input I / F 60. In response to an operation performed on the input I / F 60 by the driver, the operation pattern storage unit 42 changes the corresponding operation pattern.

(Tenth embodiment)
14 and 15 are diagrams for explaining an operation pattern in the tenth embodiment. In the tenth embodiment, the operation pattern when the operation of the cruise control system is stopped according to the shape of the road will be described as an expressway d or an expressway e.

  In response to the vehicle entering the highway, the pattern determining unit 53 determines the highway d, and the device control unit 55 proceeds to the first stage. The first stage is not a stage for controlling the in-vehicle device 8 but a stage for waiting for the transition to the second stage. The device control unit 55 continues the state of the first transition condition where the vehicle speed is within a predetermined speed range and the distance between the preceding vehicle and the preceding vehicle is within a predetermined distance range for a predetermined time (for example, 5 seconds). As a result, the second stage is entered.

  In the second stage, the device control unit 55 turns on the cruise control system. The device control unit 55 shifts to the third stage in response to the traveling position of the vehicle entering a winding region where the curvature R exceeds a predetermined threshold or a curve continues. The equipment control unit 55 turns off the cruise control system in the third stage. In the third stage, the device control unit 55 prompts the driver to perform a manual operation by outputting a sound such as “ASCD is not available” from the speaker or displaying characters on the display. Accordingly, it is possible to prompt the driver to perform a manual operation in an area where proper driving of the cruise control system is difficult.

(Eleventh embodiment)
16 and 17 are diagrams for explaining an operation pattern in the eleventh embodiment. In the eleventh embodiment, the operation pattern when the user's home is a house with a garage and the garage is a control point will be described as parking a.

  When the current time is daytime, the pattern determining unit 53 determines the operation pattern for executing the parking a shown in FIG. When the traveling position of the vehicle reaches the road in front of the house, the device control unit 55 blinks the hazard lamp that is the control target in the first stage and mutes the audio device. The device control unit 55 proceeds to the second stage in response to the gear position being shifted to the R range, which is the first transition condition.

  In the second stage, the device control unit 55 sets the idling stop function to OFF and unlocks the door of the driver's seat. The blinking of the hazard lamp and the mute of the audio device are continued from the first stage. In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 proceeds to the third stage as a determination that the parking work in the parking space has been completed.

  In the third stage, the device control unit 55 stops the operation of the in-vehicle device 8 that is the control target in the second stage. In the third stage, the device control unit 55 turns on the room lamp and sets the buzzer at the time of locking / unlocking to on.

  On the other hand, when the current time is night, the pattern determining unit 53 changes the parking a shown in FIG. 16 as shown in FIG. 17 and determines the operation pattern for executing the changed parking a. When the traveling position of the vehicle reaches the road in front of the house, the device control unit 55 makes the position of the headlamp that is the control target in the first stage small, and mutes the audio device. The device control unit 55 proceeds to the second stage in response to the gear position being shifted to the R range, which is the first transition condition.

  In the second stage, the device control unit 55 sets the idling stop function to OFF and unlocks the door of the driver's seat. Headlamp position and audio device mute continue from the first stage. In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 proceeds to the third stage as a determination that the parking work in the parking space has been completed.

  In the third stage, the device control unit 55 stops the operation of the in-vehicle device 8 that is the control target in the second stage. In the third stage, the device control unit 55 turns on the room lamp, stores the door mirror, and turns off the buzzer at the time of locking and unlocking.

  The pattern determining unit 53 can reduce the influence on the surroundings of the home at night by changing the operation pattern so that the position of the headlamp is set to small at night and the buzzer at the time of locking and unlocking is set to off. . As described above, the pattern determining unit 53 may change the operation pattern according to the situation of the vehicle, and the device control unit 55 may execute the changed operation pattern.

(Twelfth embodiment)
18 and 19 are diagrams for explaining an operation pattern used in the twelfth embodiment. In the in-vehicle device control apparatus according to the embodiment of the present invention, the operation pattern storage unit 42 stores the operation of the in-vehicle device 8 performed in the past at a specific location associated with a specific control point, and the device control unit 55. May be configured to control the in-vehicle device 8 so that an operation associated with an operation performed in the past is executed in the control region. In the twelfth embodiment, a specific place will be described as an example of a golf course.

  The operation pattern storage unit 42 may store, for example, the in-vehicle device 8 and a blank operation pattern for which no operation is set. For example, when the vehicle sensor detects that the trunk has been opened in a parking lot of a golf course, the movement pattern storage unit 42 has opened the trunk in the first stage of the blank movement pattern as shown in FIG. Record that. The user places a load on the trunk of the vehicle and starts driving toward the home.

  The device control unit 55 shifts to the second step in response to the gear position being shifted to the D range, and shifts to the third step in response to leaving the golf course site. Moreover, the action pattern memory | storage part 42 associates a golf course with a corresponding action pattern as a specific departure place linked | related with a home according to having shifted to the 3rd step.

  FIG. 19 is a diagram illustrating an operation pattern when parking is performed using the garage at the user's home as a control point. As shown in FIG. 19, the pattern determination unit 53 changes the operation pattern to include unlocking the trunk as an operation associated with opening the trunk, which is an operation performed at the departure place. .

  When the traveling position of the vehicle reaches the road in front of the house, the device control unit 55 blinks the hazard lamp that is the control target in the first stage and mutes the audio device. The device control unit 55 proceeds to the second stage in response to the gear position being shifted to the R range, which is the first transition condition.

  In the second stage, the device control unit 55 sets the idling stop function to OFF and unlocks the door of the driver's seat. The blinking of the hazard lamp and the mute of the audio device are continued from the first stage. In response to the gear position being shifted to the P range, which is the second transition condition, the device control unit 55 proceeds to the third stage as a determination that the parking work in the parking space has been completed.

  In the third stage, the device control unit 55 stops the operation of the in-vehicle device 8 that is the control target in the second stage. In the third stage, the device control unit 55 turns on the room lamp, sets the buzzer at the time of unlocking to on, and unlocks the trunk lock.

(Thirteenth embodiment)
20-24 is a figure which shows the screen displayed on the touchscreen display in 13th Example. The in-vehicle device control apparatus according to the embodiment of the present invention edits an operation pattern by displaying at least a part of the operation pattern determined by the pattern determination unit 53 on a touch panel display that is one of the in-vehicle devices 8. It may be possible.

  FIG. 20 is an example of a display screen by a car navigation system that guides a travel route to a destination. A travel route with a thick black line, and an arrow on the travel route indicate the travel position and direction of the vehicle. The pattern determining unit 53 determines an operation pattern in response to the distance to the parking lot being the control point being less than a predetermined distance. When the operation pattern is determined, the pattern determination unit 53 displays, for example, a window labeled “parking” on the display, as shown in FIG. Displays the setting operation.

  The five items shown in FIG. 20 are turned on only when the door mirror is tilted 3/4 downward, the power window of the driver's seat is opened 1/2, the door lock is unlocked, and the back view monitor is in the R range. Means that the audio device is muted. The buttons “Yes”, “No”, and “Hide” are buttons for instructing to accept or reject the execution of the displayed operation pattern and to hide the window, respectively.

  Here, it is assumed that the user desires to always turn on the back view monitor regardless of the gear position in the parking scene. At this time, as shown in FIG. 21, the user touches an item of the back view monitor displayed in the window. Then, as shown in FIG. 22, the display displays a value indicating the operation of the back view monitor and a button for designating the value. As shown in FIG. 23, when the value of “always on” is selected by the user, the window changes the item of the back view monitor in the operation pattern as shown in FIG. The operation pattern storage unit 42 overwrites the operation pattern according to the change.

  In this way, by displaying the operation pattern scheduled to be executed, the user can cause the plurality of in-vehicle devices 8 to execute the operation pattern that matches the preference even in the case where the control point is visited for the first time. . In addition, the operation pattern storage unit 42 overwrites the operation pattern stored in accordance with the change, so that the subsequent operation pattern matches the user's preference by a simple operation.

  As described above, according to the in-vehicle device control apparatus according to the embodiment of the present invention, by executing the operation patterns of a plurality of in-vehicle devices that are associated in advance for each control point, the user can Operation can be reduced easily and efficiently.

  In addition, according to the in-vehicle device control apparatus according to the embodiment of the present invention, the operation pattern has a plurality of stages in time series and is set for each of the plurality of stages. Can be practically controlled, and the user's operation on the in-vehicle device 8 can be reduced easily and efficiently.

  In addition, according to the in-vehicle device control apparatus according to the embodiment of the present invention, a plurality of in-vehicle devices 8 are set in the operation pattern by setting a condition based on the vehicle status as a transition condition for shifting a plurality of stages. Can be practically controlled, and user operations on the in-vehicle device 8 can be easily and efficiently reduced.

  Moreover, according to the vehicle equipment control apparatus which concerns on embodiment of this invention, operation | movement of the vehicle equipment 8 is practically performed according to a user's action by performing the operation | movement linked | related with the operation | movement performed in the past. It is possible to control the user operation on the in-vehicle device 8 easily and efficiently.

  Further, according to the in-vehicle device control apparatus according to the embodiment of the present invention, the operation of the in-vehicle device 8 can be practically controlled by determining the operation pattern to be executed according to the situation of the vehicle. User operations on the in-vehicle device 8 can be easily and efficiently reduced.

  In addition, according to the in-vehicle device control apparatus according to the embodiment of the present invention, the operation pattern is changed to the user's preference by changing the operation pattern to be stored in response to the operation of the in-vehicle device being changed by the user. Can be customized accordingly.

  In addition, according to the in-vehicle device control apparatus according to the embodiment of the present invention, the operation pattern can be edited by the user, so that the operation pattern according to the user's preference can be stored. This operation can be reduced easily and efficiently.

(Other embodiments)
As described above, the present invention has been described according to the above-described embodiments. However, it should not be understood that the description and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  For example, in the embodiment already described, the control area calculation unit 54 may calculate the control area according to the speed of the vehicle. For example, the control area calculation unit 54 calculates the vehicle speed and the point at which the time to reach the control point is a predetermined time (for example, 3 seconds) as the point reaching the control area. The control area calculation unit 54 may calculate the control area using a preset speed profile during deceleration or a speed profile based on past travel history.

  Further, the control region calculation unit 54 may calculate the control region based on the time during which the vehicle travels while reaching the control point, according to the type of the in-vehicle device 8 to be controlled. The in-vehicle device 8 includes devices having a transition time from the start to the completion of the operation, such as a power window and a door mirror. When the in-vehicle device 8 having such a transition time is a control target, the operation is surely completed by the time the vehicle reaches the control point by calculating the control region based on the time during which the vehicle travels. The operation can be completed efficiently after passing through the control point.

  The transition conditions include various conditions such as a change in the gear position, a change in the travel position, a lane change, a duration of the travel state, a vehicle speed, etc., for example, an operation on the input I / F 60 after a predetermined time has elapsed. Can be adopted.

  Further, in the above-described embodiment, the operation pattern stored in the operation pattern storage unit 42 is an example illustrating a configuration that is changed using the touch panel display that is the in-vehicle device 8. For example, the operation pattern may be configured to be editable using an external PC, a smartphone, or the like via a network.

  Each function described in the above-described embodiments and examples can be executed by one or a plurality of processing circuits. The processing circuit includes a programmed processing device such as a processing device including an electrical circuit. The processing circuitry may include devices such as application specific integrated circuits (ASICs) and circuit components arranged to perform the described functions.

  In addition to the above, the present invention includes various embodiments that are not described here, such as configurations in which the configurations described in the above embodiments and examples are arbitrarily applied. Therefore, the technical scope of the present invention is defined only by the invention specifying matters according to the scope of claims reasonable from the above description.

8 In-vehicle device 41 Map information storage unit 42 Operation pattern storage unit 51 Travel position acquisition unit 53 Pattern determination unit 54 Control region calculation unit 55 Device control unit

Claims (7)

A map information storage unit for storing map information;
A travel position acquisition unit that acquires the travel position of the vehicle in the map information;
An operation pattern storage unit that stores operation patterns of a plurality of in-vehicle devices that are control targets associated in advance for each predetermined control point in the map information;
Based on the control point, a control area calculation unit that calculates a control area for controlling the control target in the map information;
A pattern determining unit that determines an operation pattern to be executed from an operation pattern stored in the operation pattern storage unit, based on a travel position of the vehicle and the control region;
An apparatus control unit that controls the control target so as to execute the operation pattern determined by the pattern determination unit while the travel position of the vehicle is within the control region;
The operation pattern has a plurality of stages that shift in a time series from the first stage between the control areas, and the operation of the control target is set for each of the plurality of stages .
The on-vehicle device control device, wherein the device control unit returns the control target to the state before the first stage when the traveling position of the vehicle leaves the control region . The operation pattern storage unit stores the operation pattern in which a condition based on at least one of a traveling position, an ambient environment, and a traveling state of the vehicle is set as a transition condition for shifting the plurality of stages.
The in-vehicle device control device according to claim 1, wherein the device control unit controls the control target by shifting the plurality of stages in response to the transition condition being satisfied. The operation pattern storage unit stores the operation of the in-vehicle device performed in the past at a specific location associated with the specific control point,
The said apparatus control part controls the said vehicle equipment so that the operation | movement linked | related with the operation | movement performed in the past may be performed in the control area | region calculated based on the said specific control point. Item 3. The vehicle-mounted device control device according to Item 1 or 2. The operation pattern storage unit stores, for each control point, a plurality of operation patterns according to the situation of the vehicle,
The said pattern determination part determines the operation pattern to perform according to the condition of the said vehicle from the several operation pattern for every said control point, The any one of Claims 1-3 characterized by the above-mentioned. In-vehicle device control device.   The said operation pattern memory | storage part changes the said operation pattern according to the operation | movement of the said vehicle equipment in the said control area being changed by the user of the said vehicle, The any one of Claims 1-4 characterized by the above-mentioned. The in-vehicle device control device according to item.   The in-vehicle device control device according to claim 1, wherein the operation pattern stored by the operation pattern storage unit can be edited by a user of the vehicle. Acquiring the vehicle travel position in the map information;
Storing operation patterns of a plurality of in-vehicle devices, which are control targets associated in advance for each predetermined control point in the map information, in an operation pattern storage unit;
Calculating a control region for controlling the control target in the map information based on the control point;
Determining an operation pattern to be executed from an operation pattern stored in the operation pattern storage unit based on the travel position of the vehicle and the control region;
Controlling the controlled object to execute the determined operation pattern while the travel position of the vehicle is within the control region ,
The operation pattern has a plurality of stages that transition from the first stage to the time series within the control region, and the operation of the control target is set for each of the plurality of stages.
The vehicle- mounted device control method further comprising returning the control target to the state before the first stage when the traveling position of the vehicle leaves the control region .

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