JP2007062559A - On-vehicle switch system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To simplify design of a vehicle cockpit, and to improve convenience when a user operates a switch. <P>SOLUTION: The on-vehicle switch system 1 estimates (predicts) operation which is most probably executed by a user, by using at least any one of a vehicle position, a state around the vehicle, date and time information, and weather information as judging material. The estimated operation is set as a function of a touch switch 8a defining an operating position of the user in a range of a display device 8, thereby sharing a touch switch 8a as a switch using at least one of the vehicle position, the state around the vehicle, the date and time information, and the weather information as judging material and materializing a plurality of functions corresponding to various situations. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an in-vehicle switch system mounted on a vehicle.

  In recent years, with the advancement of vehicle travel control, information communication, IT technology, etc., the number of switches mounted on a vehicle tends to increase. However, as the number of switches mounted on the vehicle increases, there is a problem that the design of the vehicle cockpit becomes complicated, and the opportunity for the user to move their eyes and search for a desired switch from a large number of switches increases. However, there is a problem that convenience when the user operates the switch is lowered.

On the other hand, in Patent Document 1 below, when an emergency occurs, when a user operates any emergency button, an emergency is made to a contact address set in advance corresponding to the operated emergency button. A configuration for transmitting a notification signal is described. Further, Patent Document 2 below describes a configuration for displaying on the display device of the navigation device whether the fuel filler opening is arranged on the left or right when the vehicle approaches the fueling station. Further, Patent Document 3 below describes a configuration in which a user's line-of-sight movement is detected, a matter of interest of the user is predicted, and information desired by the user is output at an appropriate timing.
JP 2004-90721 A JP 2003-121174 A JP 2001-194161 A

  However, Patent Documents 1 to 3 described above do not solve the problem that the design of the vehicle cockpit becomes complicated and the problem that the convenience when the user operates the switch is lowered.

  The present invention has been made in view of the above-described circumstances, and a purpose thereof is to simplify the design of a vehicle cockpit and to improve convenience when a user operates a switch. To provide a switch system.

  According to the first aspect of the present invention, the predictive operation detecting means includes the vehicle position obtained by the vehicle position obtaining means, the vehicle surrounding situation obtained by the vehicle surrounding situation obtaining means, and the date obtained by the date / time information obtaining means. An operation that is likely to be performed by the user using at least one of the information and the weather information acquired by the weather information acquisition means as a judgment material is detected as a prediction operation, and the control means is an operation that is likely to be performed by the user. Is predicted by the predictive operation detecting means, the predictive operation is set to the function of the switch and notified from the notifying means, and the control of the in-vehicle control device to be controlled by the predictive operation is enabled, and the predictive operation is functioned. When the switch set to is operated by the user, the vehicle-mounted control device is controlled according to the prediction operation.

  As a result, an operation that is likely to be performed by the user is predicted (prefetched) using at least one of the vehicle position, the vehicle surrounding situation, date / time information, and weather information as a judgment material, and the predicted operation is performed by the user's operation position. Is set to the function of a switch that is fixed within a predetermined range, so that the switch can be a plurality of functions according to various situations using at least one of vehicle position, vehicle surroundings, date and time information, and weather information as judgment materials Since it is configured to be shared as a switch for realizing, the number of switches can be reduced, the design of the vehicle cockpit can be simplified, and the user can move the line of sight and Therefore, the opportunity to search for a desired switch can be reduced, and convenience when the user operates the switch can be improved.

  According to the second aspect of the present invention, the control means sets the prediction operation detected by the prediction operation detection means as being likely to be performed by the user to the function of the switch and notifies the notification means, and the prediction means When the control of the vehicle-mounted control device to be controlled is validated, the control point is stored in the control point storage unit and the prediction operation is stored in the prediction operation storage unit. Thereby, it is possible to store the control point where the prediction operation detected as having a high possibility of being performed by the user is set to the function of the switch and the prediction operation.

  According to the invention described in claim 3, the control means sets the prediction operation detected by the prediction operation detection means as being likely to be performed by the user to the function of the switch, notifies the notification means and notifies the prediction operation. After enabling the control of the in-vehicle control device to be controlled by the operation, when the user operates the switch having the predicted operation set as a function, the operation history indicating that the operation is performed by the user is stored in the operation history storage unit. Remember.

  As a result, it is possible to store an operation history indicating that a switch that has been set as a function of a predicted operation detected as being likely to be performed by the user has been operated by the user, and the next time the same situation occurs In addition, the prediction operation detected as having a high possibility of being performed by the user based on the stored operation history is set again in the function of the switch, and the control of the in-vehicle control device to be controlled by the prediction operation is controlled. The learning function can be realized by re-enabling, and the process of setting the prediction operation to the function of the switch and the process of enabling the control of the in-vehicle control device to be controlled by the prediction operation based on the operation history It can be carried out efficiently.

  According to the invention described in claim 4, the control means sets the prediction operation detected by the prediction operation detection means as being highly likely to be performed by the user to the function of the switch and notifies the notification means, and the prediction means After enabling the control of the in-vehicle control device to be controlled by the operation, if the switch having the predicted operation set as a function is not operated by the user, an operation history indicating that the operation is not performed by the user is stored in the operation history storage unit. Remember.

  As a result, it is possible to store as an operation history that the switch that set a predictive operation detected as highly likely to be performed by the user was not operated by the user, and the same situation occurred next time. Sometimes, based on the stored operation history, the predicted operation detected as being highly likely to be performed by the user is not set as a switch function, and the control of the in-vehicle control device to be controlled by the predicted operation is controlled. The learning function can be realized by not enabling it, and the process of setting the prediction operation to the function of the switch and the process of enabling the control of the in-vehicle control device to be controlled by the prediction operation are efficiently performed based on the operation history. Can be implemented well.

  According to the fifth aspect of the invention, the control means sets the prediction operation detected by the prediction operation detection means as being likely to be performed by the user to the function of the switch and notifies the notification means, and the prediction means After enabling the control of the in-vehicle control device that the operation is to be controlled, if the user changes from a highly likely state to a predictive operation to a low state, the setting of the function to the switch for the predictive operation is canceled. Then, the notification from the notification means is stopped and the control of the in-vehicle control device to be controlled by the prediction operation is invalidated.

  As a result, when the user changes from a highly likely state to a low state, it is possible to invalidate the control of the in-vehicle control device to be controlled by the predictive operation, and the initial state (predictive operation is the control target). It is possible to quickly return to the state prior to enabling control of the in-vehicle control device.

  According to the sixth aspect of the present invention, the notification means is configured from a display device that visually notifies the function of the switch, and the switch is configured from a touch switch that is displayed on the display device. Thereby, the user can know the function of the switch by visually recognizing the display device, and the user can control the in-vehicle control device by operating the touch switch.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows the overall configuration of the in-vehicle switch system as a functional block diagram. The in-vehicle switch system 1 is mounted on a vehicle, and includes a control device 2 (predictive operation detection means and control means in the present invention), a communication device 3 and a navigation device 4 (vehicle position acquisition means and date and time information acquisition in the present invention). Means), infrared sensor 5 (vehicle ambient condition acquisition means in the present invention), rainfall sensor 6 (weather information acquisition means in the present invention), solar radiation sensor 7 (weather information acquisition means in the present invention), display device 8 (notifying means referred to in the present invention) and an interface device 9.

  The control device 2 controls the overall operation of the in-vehicle switch system 1. The communication device 3 communicates with the outside (server) via a network. The navigation device 4 includes a vehicle position detector 4a made of, for example, a GPS receiver, and outputs the vehicle position detected by the vehicle position detector 4a to the control device 2. The navigation device 4 also outputs the date and time information measured by its own time measuring function to the control device 2. The infrared sensor 5 detects a vehicle surrounding situation such as whether there is a preceding vehicle or an obstacle, for example, according to the infrared reception state, and outputs the detected vehicle surrounding situation to the control device 2. The rainfall amount sensor 6 and the solar radiation amount sensor 7 detect the rainfall amount and the solar radiation amount as weather information, and output the detected weather information to the control device 2.

  The display device 8 has a function of displaying the touch switch 8a in addition to a function of displaying an image. When a display signal is input from the control device 2, an image corresponding to the display signal or the touch switch 8a is displayed. When the touch switch 8a is operated, an operation signal corresponding to the operation is output to the control device 2. The interface device 9 is configured to have an interface function with the vehicle motion control device 10 (in-vehicle control device in the present invention), the body system control device 11 (in-vehicle control device in the present invention), and the storage device 12. Yes. In this case, the control device 2 outputs the validation signal or the invalidation signal to the vehicle motion system control device 10 and the body system control device 11 via the interface device 9, and the vehicle motion system control device 10 and the body system control device 11. Enable or disable control of.

  The various switches 13 are mechanically arranged at a place different from the place where the display device 8 is arranged, and act as switches operated by the user to control the vehicle motion system control device 10. In this case, the vehicle motion system control device 10 is controlled by operating various switches 13 by the user, and the display device 8 is operated by the user under the condition that the control is enabled by the control device 2. Control is also performed by operating the touch switch 8a displayed on the screen. That is, the user can control the vehicle motion system control device 10 by operating the various switches 13, and under the condition that the control device 2 validates the control of the vehicle motion system control device 10. The vehicle motion control device 10 can also be controlled by operating the touch switch 8a.

  The various switches 14 are mechanically disposed in a location different from the location where the display device 8 is disposed in the same manner as the various switches 13 described above, so that the user can control the body system control device 11. Acts as a switch to operate. In this case, the body system control device 11 is controlled by operating various switches 14 by the user, and the user controls the display device 8 under the condition that the control is enabled by the control device 2. Control is also performed by operating the displayed touch switch 8a. That is, the user can control the body control device 11 by operating the various switches 14, and the touch switch under the condition that the control device 2 enables the control of the body control device 11. The body control device 11 can also be controlled by operating 8a.

  The storage device 12 includes a control point storage unit 12a (control point storage unit according to the present invention), a prediction operation storage unit 12b (predicted operation storage unit according to the present invention), and an operation history storage unit 12c (operation history storage according to the present invention). Means). In the above configuration, the communication device 3 and the display device 6 may also serve as the communication device and the display device of the navigation device 4.

  Next, the operation of the above configuration will be described with reference to FIGS. FIG. 2 shows a process performed by the control device 2 of the in-vehicle switch system 1 as a flowchart, and FIG. 3 shows a process flow of the entire system as a sequence diagram.

  The control device 2 comprehensively determines the vehicle position and date / time information input from the navigation device 4, the vehicle surroundings input from the infrared sensor 5, the weather information input from the rainfall sensor 6 and the solar radiation sensor 7. (Step S1), an operation that is likely to be performed by the user is predicted (Step S2).

  Next, the control device 2 sets an operation (predictive operation) predicted to be highly likely to be performed by the user to the function of the touch switch 8a, outputs a display signal to the display device 8, and displays the touch switch 8a. It is displayed on the device 8 (step S3). Then, the control device 2 outputs an activation signal to the vehicle motion system control device 10 or the body system control device 11, and controls the vehicle motion system control device 10 or the body system control device 11 that is controlled by the prediction operation. It is validated (step S4). Further, the control device 2 outputs the control point storage signal to the control point storage unit 12a, stores the control point in the control point storage unit 12a (step S5), and sends the predicted operation storage signal to the prediction operation storage unit 12b. The prediction operation is output and stored in the prediction operation storage unit 12b (step S6).

  Next, the control device 2 monitors whether or not the touch switch 8a has been operated (step S7), and is low from a state where the user is likely to perform the reservation operation (the user operates the touch switch 8a). It is monitored whether or not the state has changed (step S8).

  Here, the control device 2 detects that the operation signal is input from the display device 8 and the touch switch 8a is operated before the user changes from a highly likely state to a low state (step). "YES" in S7), a control signal is output to the vehicle motion system control device 10 or the body system control device 11 according to the predicted operation, and the vehicle motion system control device 10 or the body system control device 11 is controlled. (Step S9) Then, the control device 2 outputs an operation history storage signal to the operation history storage unit 12c, and stores an operation history indicating that the touch switch 8a has been operated in the operation history storage unit 12c (Step S9). S10).

  On the other hand, when the control device 2 detects that the user has changed from a highly likely state to a low state before the touch switch 8a is operated ("YES" in step S8), The function setting for the touch switch 8a is canceled and the touch switch 8a is erased (step S11). Then, the control device 2 outputs an invalidation signal to the vehicle motion system control device 10 or the body system control device 11, and controls the vehicle motion system control device 10 or the body system control device 11 to be controlled by the prediction operation. The operation history storage signal is output to the operation history storage unit 12c, and the operation history indicating that the touch switch 8a has not been operated is stored in the operation history storage unit 12c (step S13).

Here, as some specific examples of the series of processes described above,
(1) When the vehicle is refueling at a gas station (2) When the vehicle passes through the tunnel (3) The case where the vehicle encounters a traffic jam will be sequentially described with reference to FIGS.

(1) When vehicle refuels at a gas station First, the case where a vehicle refuels at a gas station will be described with reference to FIG.
In this case, for example, when detecting that the vehicle has stopped at the filling station from the vehicle position and the map information (step S21), the control device 2 predicts an operation for opening the filling port as an operation that is likely to be performed by the user. . Then, the control device 2 causes the display device 8 to display a fuel filler icon (indicated by “P1” in FIG. 4) as the touch switch 8a (see FIG. 4A) (step S22), and control to open the fuel filler. Activate.

  Here, when the control device 2 detects that the user has operated (touched) the fuel filler icon displayed on the display device 8 as the touch switch 8a ("YES" in step S23), the fuel filler port. The opening control is performed (step S24). Thus, the user can operate the fuel filler icon displayed on the display device 8 as the touch switch 8a without operating the fuel filler lever mechanically disposed below the driver seat, for example. I can open my mouth.

  Next, the control device 2 calculates the fuel consumption based on the amount of fuel injected and the travel distance (step S25), and displays a fuel consumption icon (indicated by “P2” in FIG. 4) indicating the fuel consumption on the display device 8. After the display (see FIG. 4B) (step S26), an operation for resetting the trip meter is predicted as an operation that is likely to be performed by the user. Then, the control device 2 displays a trip reset icon (indicated by “P3” in FIG. 4) on the display device 8 as the touch switch 8a (see FIG. 4C) (step S27), and trip meter reset control. Activate.

  Here, when the control device 2 detects that the trip reset icon displayed on the display device 8 as the touch switch 8a has been operated by the user ("YES" in step S28), the control device 2 performs trip meter reset control. (Step S29). Accordingly, the user can operate the trip meter by operating the trip reset icon displayed on the display device 8 as the touch switch 8a without operating the trip reset button mechanically disposed at the back of the meter panel, for example. Can be reset.

  Through the series of processes described above, the user sequentially operates the fuel filler icon and the trip reset icon that are sequentially displayed on the display device 8 as the touch switch 8a, thereby arranging the fuel filler lever and the trip reset button. It is possible to open the fuel filler and reset the trip meter without moving the line of sight. In this case, the user is not limited to predicting an operation of opening a fuel filler port or resetting a trip meter. In addition to these operations, a user predicts an operation of opening and closing a window to pay a fee, and opens the window. An icon or a window closing icon may be displayed, and the window opening / closing control may be performed when the window opening icon or the window closing icon is operated.

(2) When a vehicle passes through a tunnel Next, a case where a vehicle passes through a tunnel will be described with reference to FIG.
In this case, for example, when detecting that the vehicle enters the tunnel from the vehicle position and the map information (step S31), the control device 2 performs an operation of switching from the introduction of the outside air to the inside air circulation as an operation that is likely to be performed by the user. Predict. Then, the control device 2 causes the display device 8 to display the inside air circulation icon (indicated by “Q1” in FIG. 5) as the touch switch 8a (see FIG. 5A) (step S32), and from the outside air introduction to the inside air circulation. Enable switching control to.

  Here, when the control device 2 detects that the inside air circulation icon displayed on the display device 8 as the touch switch 8a is operated by the user (“YES” in step S33), the control device 2 changes from the introduction of the outside air to the inside air circulation. Switching control is performed (step S34). Thereby, the user operates the inside air circulation icon displayed on the display device 8 as the touch switch 8a without operating the switch button for switching from the introduction of outside air to the inside air circulation, which is mechanically arranged on the instrument panel, for example. By doing so, it is possible to switch from outside air introduction to inside air circulation.

  Next, when detecting that the vehicle has advanced from the tunnel from the vehicle position and the map information (step S35), the control device 2 predicts an operation for switching from the inside air circulation to the outside air introduction as an operation highly likely to be performed by the user. . Then, the control device 2 displays an outside air introduction icon (indicated by “Q2” in FIG. 5) on the display device 8 as the touch switch 8a (see FIG. 5B) (step S36), and introduces outside air from the inside air circulation. Enable switching control to.

  Here, when the control device 2 detects that the outside air introduction icon displayed on the display device 8 as the touch switch 8a has been operated by the user (“YES” in step S37), the control device 2 switches from the inside air circulation to the outside air introduction. Switching control is performed (step S38). Accordingly, the user operates the outside air introduction icon displayed on the display device 8 as the touch switch 8a without operating the switch button for switching from the inside air circulation to the outside air introduction mechanically arranged on the instrument panel, for example. By doing so, it is possible to switch from inside air circulation to outside air introduction.

  Through the series of processes described above, the user sequentially operates the inside air circulation icon and the outside air introduction icon that are sequentially displayed on the display device 8 as the touch switch 8a, so that a switch button between outside air introduction and inside air circulation is arranged. It is possible to switch from outside air introduction to inside air circulation or from inside air circulation to outside air introduction without moving the line of sight. In this case, the user is not limited to predicting the operation of switching from the introduction of the outside air to the circulation of the inside air or the operation of switching from the circulation of the inside air to the introduction of the outside air. An open icon or a window closing icon may be displayed, and the window opening / closing control may be performed when the window opening icon or the window closing icon is operated.

(3) When a vehicle encounters a traffic jam Next, a case where a vehicle encounters a traffic jam will be described with reference to FIG.
In this case, for example, when detecting that the vehicle has encountered a traffic jam from the situation around the vehicle (step S41), the control device 2 predicts an operation for blinking the hazard lamp as an operation that is likely to be performed by the user. Then, the control device 2 displays a hazard lamp icon (indicated by “R1” in FIG. 6) on the display device 8 as the touch switch 8a (step S42), and enables blinking control of the hazard lamp.

  Here, when the control device 2 detects that the hazard lamp icon displayed on the display device 8 as the touch switch 8a has been operated by the user (“YES” in step S43), the control device 2 performs blink control of the hazard lamp. (Step S44). Thereby, the user operates the hazard lamp icon displayed on the display device 8 as the touch switch 8a without operating the hazard lamp button mechanically arranged on the instrument panel, for example. Can be flashed.

  Next, the control device 2 predicts an operation that outputs the traffic information (highway radio program) as an operation that is likely to be performed by the user (turns on or selects a radio power). Then, the control device 2 displays a traffic information icon (indicated by “R2” in FIG. 6) on the display device 8 as the touch switch 8a (see FIG. 6B) (step S45), and outputs the traffic information as a voice. Enable control.

  Here, if the control device 2 detects that the traffic information icon displayed on the display device 8 as the touch switch 8a has been operated by the user (“YES” in step S46), the control device 2 performs voice output control of the traffic information. Implement (step S47). Thus, for example, the user operates the traffic information icon displayed on the display device 8 as the touch switch 8a without operating the radio power-on button or the channel selection button mechanically arranged on the instrument panel. By doing so, traffic information can be output as a voice.

  Through the series of processes described above, the user sequentially operates the hazard lamp icon and the traffic information icon sequentially displayed on the display device 8 as the touch switch 8a, so that the hazard lamp button, the radio power-on button, and the channel selection are selected. Without moving the line of sight to the place where the button is placed, the hazard lamps can be blinked and traffic information can be output as audio. In this case, the traffic information icon is displayed or the audio output circuit is disconnected only when the vehicle is traveling in an area where the traffic information can be reliably output by voice (the radio wave can be reliably received). By displaying the traffic information icon while waiting for voice output, the traffic information voice displayed immediately after the user operates the traffic information icon displayed on the display device 8 as the touch switch 8a. The configuration may be such that the output is started promptly. In this case, the hazard lamp icon and the traffic information icon may be displayed at the same time.

  By the way, the above describes the case where an operation that is highly likely to be performed by the user is predicted using the vehicle position and the surrounding situation of the vehicle as judgment materials. A configuration in which information is predicted as a judgment material may be used. As a specific example, for example, when a user listens to a radio program at a specified time every day, the time is set as a set time, and when the set time is detected, the user The display device 8 may be configured to display a radio switch icon operated to turn on the power or select a channel. Further, when it is detected that the rainfall amount is equal to or greater than a predetermined amount, a configuration in which a wiper icon operated by the user to operate the wiper may be displayed on the display device 8, or the amount of solar radiation is equal to or greater than a predetermined level When it is detected that the air conditioner is detected, an air conditioner icon operated by the user to operate the air conditioner may be displayed on the display device 8.

  Further, the control device 2 stores the control point in the control point storage unit 12a, stores the prediction operation in the prediction operation storage unit 12b, and stores the operation history in the operation history storage unit 12c, thereby performing the following processing. can do. That is, when the control device 2 predicts an operation that is likely to be performed by the user, the control device 2 determines whether or not the control point is stored in the control point storage unit 12a and the prediction operation is performed in the prediction operation storage unit. It is determined whether or not it is stored in 12b, the control point is stored in the control point storage unit 12a, and the prediction operation is stored in the prediction operation storage unit 12b. When the operation predicted to be high is the same as the operation predicted in the past, the operation history stored in the operation history storage unit 12c is referred to, and if the user has performed the operation last time, The touch switch 8a is displayed in the same manner as described above and the control of the vehicle motion control device 10 and the body control device 11 is enabled, while the user has performed the operation last time. , It is possible not to enable the control of the vehicle motion system control device 10 and the body system control device 11 together with the not displayed touch switch 8a.

  As described above, according to the present embodiment, in the in-vehicle switch system 1, an operation that is highly likely to be performed by the user using at least one of the vehicle position, the vehicle surroundings, the date / time information, and the weather information as a determination material. By predicting (prefetching) and setting the predicted operation to the function of the touch switch 8a in which the user's operation position is fixed within the range of the display device 8, the touch switch 8a is set to the vehicle position, vehicle surroundings, date and time. Since it is configured to be shared as a switch for realizing a plurality of functions according to various situations using at least one of information and weather information as a judgment material, the number of switches can be reduced, and the vehicle cockpit The design can be simplified, and the user has the opportunity to move the line of sight and search for a desired switch from a large number of switches. Can cause lack, user convenience can be improved when operating the switch.

The present invention is not limited to the above-described embodiment, and can be modified or expanded as follows.
When the vehicle is parked at home or at work, the operation for storing the door mirror is predicted as an operation that is likely to be performed by the user, and the door mirror icon that the user operates to store the door mirror is displayed. Also good. In addition, when the vehicle stops at the exit of a parking lot where automatic toll collection is not possible or stops at a toll gate on a highway, an operation that opens and closes the window is likely to be performed by the user. The window opening icon that the user operates to open the window and the window closing icon that the user operates to close the window may be displayed.

The mode of notifying the user of the function of the switch is not limited to the configuration in which the touch switch is displayed to visually notify the user of the function of the switch, but the function of the switch is audibly informed to the user by using an audio output. It may be configured to do so.
The timing at which the icon displayed as the touch switch is deleted may be the timing at which the icon is operated, or the timing at which a predetermined time has elapsed since the icon was displayed. In this case, the time from when the icon is displayed to when it is deleted may be optimized by statistically learning the time from when the icon is displayed until it is operated.

Functional block diagram showing an embodiment of the present invention flowchart Sequence Diagram The figure which shows an example of the transition of a display screen when a vehicle refuels at a gas station The figure which shows an example of the transition of a display screen when a vehicle passes a tunnel The figure which shows an example of the transition of the display screen when the vehicle encounters a traffic jam

Explanation of symbols

  In the drawings, 1 is an in-vehicle switch system, 2 is a control device (prediction operation detection means, control means), 4 is a navigation device (vehicle position acquisition means, date / time information acquisition means), and 5 is an infrared sensor (vehicle ambient condition acquisition means). , 6 is a rainfall sensor (weather information acquisition means), 7 is a solar radiation sensor (weather information acquisition means), 8 is a display device (notification means), 8a is a touch switch (switch), 10 is a vehicle motion system control device ( In-vehicle control device), 11 is a body system control device (in-vehicle control device), 12a is a control point storage unit (control point storage unit), 12b is a prediction operation storage unit (prediction operation storage unit), and 12c is an operation history storage unit ( Operation history storage means).

Claims (6)

A switch in which the user's operation position is fixed within a predetermined range;
An informing means for informing the function of the switch;
At least one of vehicle position acquisition means for acquiring a vehicle position, vehicle surrounding condition acquisition means for acquiring vehicle surrounding conditions, date information acquisition means for acquiring date information, and weather information acquisition means for acquiring weather information;
The vehicle position acquired by the vehicle position acquisition means, the vehicle surrounding condition acquired by the vehicle surrounding condition acquisition means, the date / time information acquired by the date / time information acquisition means, and the weather information acquired by the weather information acquisition means A predictive operation detecting means for detecting, as a predictive operation, an operation that is likely to be performed by a user using at least one of them as judgment material;
When an operation that is highly likely to be performed by the user is detected by the predictive operation detecting unit as a predictive operation, the predictive operation is set as a function of a switch and is notified from the notifying unit, and the predictive operation is controlled. Control means for enabling the control of the in-vehicle control device to perform control of the in-vehicle control device in accordance with the prediction operation when the user operates the switch that sets the prediction operation as a function. A featured on-board switch system. In the on-vehicle switch system according to claim 1,
The control means sets the predictive operation detected by the predictive operation detection means as being likely to be performed by the user to the function of the switch, notifies the informing means, and controls the in-vehicle control to be controlled by the predictive operation An on-vehicle switch system characterized in that when control of a device is validated, the control point is stored in a control point storage unit and the prediction operation is stored in a prediction operation storage unit. In the in-vehicle switch system according to claim 1 or 2,
The control means sets the predictive operation detected by the predictive operation detection means as being likely to be performed by the user to the function of the switch, notifies the informing means, and controls the in-vehicle control to be controlled by the predictive operation After the device control is validated, an operation history indicating that the operation is performed by the user is stored in the operation history storage unit when a switch having the predicted operation set as a function is operated by the user. In-vehicle switch system. In the on-vehicle switch system according to any one of claims 1 to 3,
The control means sets the predictive operation detected by the predictive operation detection means as being likely to be performed by the user to the function of the switch, notifies the informing means, and controls the in-vehicle control to be controlled by the predictive operation After the device control is validated, if the switch that has set the predicted operation as a function is not operated by the user, an operation history indicating that the switch has not been operated by the user is stored in the operation history storage unit In-vehicle switch system. In the on-vehicle switch system according to any one of claims 1 to 4,
The control means sets the predictive operation detected by the predictive operation detection means as being likely to be performed by the user to the function of the switch, notifies the informing means, and controls the in-vehicle control to be controlled by the predictive operation After enabling the control of the device, when the prediction operation is changed from a state that is likely to be performed by the user to a low state, the function setting to the switch of the prediction operation is canceled and the notification means A vehicle-mounted switch system characterized by stopping notification and invalidating control of a vehicle-mounted control device to be controlled by the prediction operation. In the on-vehicle switch system according to any one of claims 1 to 5,
The in-vehicle switch system, wherein the notification means is configured from a display device that visually notifies the function of the switch, and the switch is configured from a touch switch displayed on the display device.

Images