JP2007160981A - Onboard information system, and onboard information processing program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an onboard information system capable of automatically changing the function allocated to each operation of an operation input device without adding any hardware. <P>SOLUTION: The onboard information system comprises an operation input device 1 for generating an input signal according to the operation, a control means 21 for receiving the input signal from the operation input device and generating an operation signal for realizing the function allocated to the input signal, and an execution means 23 for receiving the operation signal from the control means and executing a program according to the operation signal; and further comprises an execution state determination means 24 for determining the execution state of the program executed by the execution means, and transmitting the result of determination to the control means. The control means has an operation input allocation changing means 25 which changes the function to be allocated to the input signal from the operation input device according to the result of determination to be transmitted from the execution state determination means, and generates the corresponding operation signal and transmits it to the execution means. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an in-vehicle information system and an in-vehicle information processing program that are mounted on an automobile and process various types of information, and more particularly to a technique for assigning a function to an operation of an operation input device.

  A recent automobile is equipped with a plurality of devices such as a navigation device, an audio device, and an air conditioner, and each device includes a group of switches for operation. As a technique for facilitating the operation of the plurality of devices, for example, Patent Document 1 discloses a vehicle in which a plurality of control target devices can be operated and the operability is improved while minimizing the number of switches operated by the user. A switch system is disclosed.

  This vehicle switch system is provided with a switch unit having a number of switches that can be operated with one hand, and selects a function that can be used from a plurality of operation functions of a plurality of control target devices. Is provided with a controller that assigns the function to be accessible by each switch of the switch unit. Thereby, since the number of switches operated by the user is reduced, the operability of the switches is improved, and the switches can be operated even during driving.

  Patent Document 2 discloses a multi-function switch for a vehicle that can perform a switch operation in which the adjustment operation in the driving posture is desirable in the driving posture. This multi-function switch for a vehicle operates a plurality of in-vehicle devices, and assigns operations of other in-vehicle devices related to the driving posture to an auto-cruise operation switch group provided on the steering wheel of the vehicle. A mode changeover switch for switching between a cruise operation mode and another operation mode is provided. Then, the function is switched to the switch when the user presses the mode switch or travels at a certain speed or higher.

JP-A-8-58493 JP 2005-96656 A

  However, since the vehicle switch system disclosed in Patent Document 1 described above requires a new switch device, there is a problem that the hardware cost is increased. The multi-function switch for a vehicle disclosed in Patent Document 2 can automatically switch functions depending on traveling speed, but can switch to predetermined functions such as door mirror adjustment, driving position adjustment, and tilt adjustment. However, the function assignment switching rule cannot be added or changed.

  On the other hand, in recent years, automobiles in which an operation input device dedicated to vehicles capable of sliding operation and rotating operation is attached to an instrumental panel have appeared. A program installed in a vehicle on which such an operation input device is mounted needs to be customized according to the operation input device of each vehicle.

  The present invention has been made to solve the above-described problems, and the problem is that, for example, in a car equipped with a dedicated operation input device for a car, a function assigned to each operation of the operation input device is added to hardware. An object of the present invention is to provide an in-vehicle information system and an in-vehicle information processing program that can be switched automatically without being performed.

  An in-vehicle information system according to the present invention generates an operation signal for realizing an operation input device that generates an input signal corresponding to an operation and an input signal from the operation input device and realizing a function assigned to the input signal. Determining the execution state of the program executed by the execution means in the in-vehicle information system comprising the control means for performing the operation and the execution means for receiving the operation signal from the control means and executing the program according to the operation signal; An execution state determination unit that sends the determination result to the control unit is provided, and the control unit changes a function assigned to the input signal from the operation input device according to the determination result sent from the execution state determination unit. Operation input assignment changing means for generating an operation signal and sending it to the execution means is provided.

  The in-vehicle information processing program according to the present invention receives an input signal generated according to an operation of the operation input device, generates an operation signal for realizing a function assigned to the input signal, and generates the generated operation signal. In the in-vehicle information processing program that executes the program according to the function, the execution state of the program to be executed is determined, and the function assigned to the input signal from the operation input device is changed according to the determination result. Generate an operation signal.

  According to the present invention, since the function assigned to each operation of the operation input device can be changed according to the execution state of the program, the function switching can be performed without adding hardware such as a mode switch. Is possible. Moreover, according to the vehicle-mounted information processing program which concerns on this invention, there exists an effect similar to the vehicle-mounted information system mentioned above.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Hereinafter, a case where the in-vehicle information system according to the present invention is realized using a car navigation device will be described as an example.
Embodiment 1 FIG.
1 is a block diagram showing a schematic configuration of an in-vehicle information system according to Embodiment 1 of the present invention. This in-vehicle information system includes an operation input device 1, a car navigation device 2, a display device 3, an in-vehicle LAN (Local Area Network) 4, an audio device 5 and an air conditioner device 6.

  The operation input device 1 is composed of, for example, a vehicle-specific input device that is pre-installed in advance on an instrument panel (front panel) of a vehicle. 2A and 2B are diagrams illustrating the structure of the operation input device 1, in which FIG. 2A is a diagram viewed from the upper side, and FIG. 2B is a diagram viewed from the side. As shown in FIG. 2A, the operation input device 1 is configured so that it can be slid up and down, left and right and rotated, and can be pressed down as shown in FIG. 2B. Has been.

  The car navigation device 2 includes a CPU that performs arithmetic processing, a ROM that stores map data, a navigation program, and the like, a RAM (not shown) that is used as a temporary memory during program execution, and the like. Processing according to the input signal sent from the device 1 is performed, and the processing result is displayed on the display device 3. The car navigation device 2 is connected to the in-vehicle LAN 4 and can communicate with external devices such as the audio device 5 and the air conditioner device 6.

  The display device 3 is composed of a liquid crystal display device, for example, and is installed in the front seat of the automobile. The display device 3 receives the processing result from the car navigation device 2 and displays it.

  FIG. 3 is a diagram illustrating a functional configuration of the car navigation apparatus 2. The car navigation device 2 includes a control unit 21, an allocation rule setting unit 22, an execution unit 23, and an execution state determination unit 24. The control means 21 includes an operation input assignment change means 25.

  The control means 21 activates the operation input assignment changing means 25 in response to the input signal sent from the operation input device 1. The assignment rule setting means 22 sets a function assignment rule for assigning a function to the input signal sent from the operation input device 1. The function allocation rule set by the allocation rule setting unit 22 is sent to the operation input allocation changing unit 25.

  The execution unit 23 executes a program corresponding to the operation signal generated by the operation input allocation change unit 25. As will be described in detail later, the execution means 23 executes a navigation program or a Java application program (hereinafter abbreviated as “Java application”). Further, the execution means 23 generates execution state information representing the execution state of the program and sends it to the execution state determination means 24. The execution state determination unit 24 determines the execution state of the program based on the execution state information sent from the execution unit 23, and sends the result of this determination to the operation input allocation change unit 25.

  The operation input allocation changing unit 25 is activated by the control unit 21 that receives the input signal sent from the operation input device 1, and is sent from the function allocation rule and execution state determination unit 24 set by the allocation rule setting unit 22. Based on the determination result, the function assigned to the operation input device 1 is changed, and a corresponding operation signal is generated and sent to the execution means 23.

  Assume that the Java application A is a program that displays a plurality of menu tabs arranged in the left-right direction as shown in the screen 3a of FIG. In this case, when the execution of the Java application A is started, the execution unit 23 sends execution state information indicating the fact to the execution state determination unit 24. When the execution state determination unit 24 determines that the Java application A is being executed based on the execution state information sent from the execution unit 23, the execution state determination unit 24 sends information indicating the fact to the operation input allocation change unit 25. The operation input allocation changing unit 25 receives this information, acquires a function allocation rule corresponding to the Java application A from the allocation rule setting unit 22, and the function of the operation input device 1 can be moved left and right according to the rotation operation. Change to be made. Thus, in a state where the Java application A is being executed, when the operation input device 1 is rotated, tabs of menus displayed side by side in the horizontal direction as shown in the screen 3a are sequentially selected.

  Similarly, assuming that the Java application B is a program that displays a plurality of menu tabs arranged in the vertical direction as shown in the screen 3b, the execution means 23, when the execution of the Java application B is started, Execution state information indicating that is sent to the execution state determination means 24. When the execution state determination unit 24 determines that the Java application B is being executed based on the execution state information transmitted from the execution unit 23, the execution state determination unit 24 transmits information indicating the fact to the operation input allocation change unit 25. The operation input allocation changing unit 25 receives this information, acquires a function allocation rule corresponding to the Java application B from the allocation rule setting unit 22, and moves the function of the operation input device 1 up and down according to the rotation operation. Change to be made. Thus, in a state where the Java application B is being executed, when the operation input device 1 is rotated, tabs of menus displayed side by side in the vertical direction as shown in the screen 3b are sequentially selected.

  FIG. 4 is a diagram illustrating a configuration of software installed in the car navigation apparatus 2. The operating system of the car navigation device 2 (hereinafter, abbreviated as “car navigation OS”) is based on various device drivers for operating the hardware of the car navigation device 2 (hereinafter referred to as “car navigation hardware”). Is formed. A library and an application program interface (hereinafter referred to as “API: Application Program Interface”) are provided above the car navigation OS, and further, a navigation service 10, a Java application 11, and a Java application that are configured by programs are provided above the car navigation OS. An execution unit (Java VM; Java Virtual Machine) 12, a Java application reception unit 13, and a Java application management unit 14 are provided.

  The navigation service 10 includes a navigation program that provides a basic service of car navigation such as displaying a current location or setting a destination and performing route guidance. This navigation program is called a basic service program, and a portion of the execution means 23 that executes the basic service program is called a basic service execution means 23a as shown in FIG.

  The Java application 11 includes a plurality of Java applications, and provides an extended car navigation service such as a game or a driving support program. A program that implements the Java application 11 is called an extended service program, and a portion of the execution means 23 that executes the extended service program is called an extended service execution means 23b as shown in FIG. The extended service execution unit 23 b sends the execution state information to the execution state determination unit 24.

  The Java application execution unit 12 is a part of the execution unit 23 illustrated in FIG. 3, assigns functions to input signals sent from the operation input device 1, and provides an execution environment for the Java application 11. The Java application receiving unit 13 receives the Java application 11 from a communication device such as the Internet or a storage device such as a compact disk or an SD card. The Java application management unit 14 manages the entire Java application 11 received by the Java application reception unit 13.

  The navigation service 10 includes a Java VM interface module 10a. In addition, the Java application execution unit 12 includes a navigation service interface module 12a. When the Java VM interface module 10a and the navigation service interface module 12a communicate with each other, the navigation service 10 and the Java application execution unit 12 operate in cooperation with each other.

  FIG. 6 shows the car navigation device 2 shown in FIG. 5 with the output means 27 added and described again. The output means 27 corresponds to the display device 3 and outputs the processing results based on the output signals sent from the basic service execution means 23a and the extended service execution means 23b.

  Next, the operation of the in-vehicle information system configured as described above according to Embodiment 1 of the present invention will be described focusing on the operation of the car navigation device 2. FIG. 7 is a flowchart illustrating processing when the Java application is executed in the car navigation device 2.

  When executing a Java application, first, a Java application reception process is performed (step ST11). That is, the Java application receiving unit 13 downloads the Java application from the Internet or a storage device. Next, a function assignment determination process is performed on the Java application downloaded in step ST11 (step ST12). That is, the Java application management unit 14 operates as the execution state determination unit 24, refers to the information file attached to the Java application, and uses the function assignment rule described therein as the determination result as the operation input assignment execution process ( To step ST13).

  For example, in the case of a Java application of a type called MIDlet, a function allocation rule as shown in FIG. 8 is added to a Jad (Java Application Descriptor) file, which is a text file in which MIDlet information is described. Is done. In the following description, the Java application is a type called MIDlet, and the information file is a Jad file.

  In the example illustrated in FIG. 8, by adding a line “XXX-RotateOperation: KEY_RIGHT and KEY_LEFT” to the Jad file, the right rotation of the rotation operation of the operation input device 1 is moved to the right and the left rotation is performed. Are assigned to the leftward movements, respectively. Similarly, by adding one line of “xxx-RotateOperation: KEY_UP and KEY_DOWN” to the Jad file, it is possible to assign the right rotation to the downward movement and the left rotation to the upward movement, respectively.

  Next, an operation input assignment execution process is performed (step ST13). In other words, the Java application execution unit 12 operates as the operation input assignment changing unit 25 and can interpret the input signal input from the operation input device 1 in the Java application based on the determination result of the function assignment determination process in step ST12. It is converted into an operation signal and sent to the Java application execution process (step ST14). Next, a Java application execution process is performed (step ST14). In other words, the Java application execution unit 12 operates as the execution unit 23, receives an operation signal that is a result of the operation input assignment execution process in step ST13, and executes the Java application in the provided Java execution environment. Thus, in the case of the Java application corresponding to the Jad file shown in FIG. 8, the processing is performed assuming that the right rotation operation of the operation input device 1 is a rightward movement and the left rotation operation is a leftward movement.

  With the above processing, it is possible to realize function assignment suitable for the operation for each Java application with respect to the rotation operation of the operation input device 1. When the screen of the Java application is designed as shown in FIG. 9A, by assigning the rotation operation of the operation input device 1 to the left / right movement, the cursor is moved to “menu 1” → “menu 2” → “ It is possible to move the menu 3 ”→... In the case of the screen as shown in FIG. 9B, by assigning the rotation operation to the vertical movement, the cursor is moved to the“ menu 1 ”by the rotation operation. It becomes possible to move “Menu 2” → “Menu 3” →...

  In the above-described example, the left / right movement is assigned to the rotation operation of the operation input device 1, but a function can be assigned to the rotation direction of the operation input device 1. For example, by assigning “xxx-RotateLeft: KEY_SOFT1” to the Jad file, a press of soft key 1 (key code defined in the Mobile Information Device Profile (MIDP)) is assigned to the left rotation operation. Can do. In addition, by describing “XXX-RotateRight: KEY_SOFT2”, pressing of the soft key 2 (key code defined in MIDP) can be assigned to the clockwise rotation operation.

  Further, a function can be assigned to the rotation speed of the operation input device 1. For example, by describing “XXX-RotateFast: KEY_SELECT”, execution pressing can be assigned to a quick rotation operation. Further, a function can be assigned to the number of rotations of the operation input device 1. For example, one depression can be assigned to one rotation operation by describing “XXX-Rotate1time: KEY_1”. Furthermore, a function can be assigned to the rotation angle of the operation input device 1. For example, by describing “XXX-Rotate 90 deg: KEY — 3”, it is possible to assign 3 presses to the 90-degree rotation operation.

  That is, since Java does not have the concept of a rotation operation, it cannot directly interpret an input signal of a rotation operation generated by a special device such as an in-vehicle operation input device, but an input signal from the operation input device. Is assigned to a function that can be interpreted by Java, so that the Java application can be operated by the in-vehicle operation input device. In this case, it is not necessary to modify the conventional Java application program itself, and the Java application can be operated using an in-vehicle operation input device simply by adding a function assignment rule to the Jad file.

  As described above, according to the in-vehicle information system according to the first embodiment of the present invention, the function assigned to the operation input device is switched according to the execution state of the program, that is, the description of the Jad file corresponding to each Java application. Therefore, the user can perform an optimum operation for each program. In the first embodiment, the single operation of the Java application has been described. However, even when the extended service program can simultaneously start a plurality of Java applications, the function assignment can be changed for each program, so that the usability is improved. In addition, since functions can be assigned according to the rotation direction, rotation speed, number of rotations, or rotation angle of the operation input device, the comfort of user operations can be improved.

Embodiment 2. FIG.
In the in-vehicle information system according to the first embodiment, the function allocation rule is set for each Java application by the description in the Jad file. However, in the in-vehicle information system according to the second embodiment, the Java application is displayed. The function allocation rule is set for each screen to be executed.

  The configuration of the in-vehicle information system according to Embodiment 2 is the same as the configuration of the in-vehicle information system according to Embodiment 1 described above.

  Next, the operation of the in-vehicle information system according to the second embodiment will be described focusing on the operation of the car navigation device 2. FIG. 10 is a flowchart showing a process when the Java application is executed in the car navigation device 2. In the following, the same parts as those in the in-vehicle information system according to Embodiment 1 shown in the flowchart of FIG. 7 are denoted by the same reference numerals as those in Embodiment 1 to simplify the description.

  When executing a Java application, first, a Java application reception process is performed (step ST11). Next, a function assignment determination process is performed (step ST12). That is, as in the first embodiment, the Java application management unit 14 operates as the execution state determination unit 24, refers to the Jad file attached to the Java application, and has a function assignment rule for each screen described therein. Is sent to the operation input allocation execution process (step ST13) as a determination result. In the Jad file, as shown in FIG. 11, function assignment rules are described in association with the screen of the Java application.

  Next, an operation input assignment execution process is performed (step ST21). In other words, the Java application execution unit 12 operates as the operation input assignment changing unit 25 and can interpret the input signal input from the operation input device 1 in the Java application based on the determination result of the function assignment determination process in step ST12. It is converted into an operation signal and sent to the Java application execution process (step ST14). In this operation input assignment execution process, the operation input assignment execution process is performed in response to a display screen notification from the Java application execution process. Next, a Java application execution process is performed (step ST22). In other words, the Java application execution unit 12 operates as the execution unit 23, receives an operation signal that is a result of the operation input assignment execution process in step ST13, and executes the Java application in the provided Java execution environment. In addition, when the display screen is switched, a display screen notification is given to the operation input assignment execution process.

  As described above, according to the in-vehicle information system according to Embodiment 2 of the present invention, the function assignment can be changed for each screen in the extended service program that simultaneously activates a plurality of Java applications. As a result, even when one Java application displays a plurality of screens, it is possible to realize function assignment suitable for the operation for each screen, and thus the user can perform an optimal operation for each screen. .

  Note that an API for setting a function assignment rule can be implemented in the Java execution environment of the car navigation device 2 so that the function assignment rule can be set directly from the Java application to the operation input assignment changing means 25. In this case, an API for setting a function assignment rule is added to the API layer shown in FIG.

  The operation of the in-vehicle information system according to this modification will be described focusing on the operation of the car navigation device 2. FIG. 12 is a flowchart showing a process when the Java application is executed in the car navigation device 2. In the following, the same parts as those in the in-vehicle information system according to Embodiment 1 shown in the flowchart of FIG. 7 are denoted by the same reference numerals as those in Embodiment 1 to simplify the description.

  When executing a Java application, first, a Java application reception process is performed (step ST11). Next, a Java application execution process is performed (step ST32). That is, the Java application execution unit 12 operates as the execution unit 23, and the Java application being executed calls an API that sets a function assignment rule for the operation input assignment execution process (step ST31). A code for setting a function assignment rule as shown in FIG. 13 is added to the program code of the Java application. In this example, an API for setting a function assignment rule, “com.mitsubishi.OperationRule.setRotateOperation” method is called to assign a rotation operation to left and right inputs.

  Next, an operation input assignment execution process is performed in response to an input signal from the operation input device 1 (step ST31). In other words, the Java application execution unit 12 operates as the operation input allocation changing unit 25, and converts the input signal input from the operation input device 1 into an operation signal that can be interpreted by the Java application execution process based on the setting from the API. Then, the Java application execution process is notified. As a result, the Java application execution unit 12 operating as the execution unit 23 receives the operation signal that is the result of the operation input assignment execution process in step ST31, and executes the Java application in the provided Java execution environment.

  With the above processing, the function assignment for the operation input device 1 can be dynamically changed from the Java application itself at the time of execution, so that the structure of the program is simplified.

Embodiment 3 FIG.
In Embodiment 1 and Embodiment 2 described above, the function allocation for the operation input device 1 is changed according to the state of the Java application execution unit 12, but the in-vehicle information system according to Embodiment 3 of the present invention. Then, the function allocation is changed based on the vehicle information.

  The configuration of the in-vehicle information system according to the third embodiment is the same as the configuration of the in-vehicle information system according to the first embodiment.

  FIG. 14 is a diagram illustrating a functional configuration of the car navigation apparatus 2. The car navigation device 2 is configured by removing the execution state determination unit 24 and adding an external state determination unit 26 from the car navigation device of the third embodiment shown in FIG. The external state determination means 26 determines the state of the vehicle and sends the result of this determination to the operation input assignment change means 25.

  Next, the operation of the in-vehicle information system according to Embodiment 3 of the present invention will be described focusing on the operation of the car navigation device 2. FIG. 15 is a flowchart showing a process when a Java application is executed in the car navigation device 2. In the following, the same parts as those in the in-vehicle information system according to Embodiment 1 shown in the flowchart of FIG. 7 are denoted by the same reference numerals as those in Embodiment 1 to simplify the description.

  When executing a Java application, first, a Java application reception process is performed (step ST11). On the other hand, a vehicle state notification process is performed in parallel with the Java application reception process (step ST41). That is, the navigation service 10 operates as the external state determination unit 26, periodically monitors the vehicle state, and notifies the operation input allocation execution process of the vehicle information at that time when the vehicle state changes. Specifically, the vehicle status is monitored in the navigation service 10 in FIG. 4, and the current location, steering wheel steering angle, shift lever position, traveling road type, position where the operation input device 1 is installed, or the number of operation input devices 1 When any of the above changes, the fact is notified to the Java execution environment through the JavaVM interface module 10a in the navigation service 10.

  Next, an operation input assignment execution process is performed (step ST42). In other words, the Java application executing unit 12 operates as the operation input allocation changing unit 25, and can interpret the input signal input from the operation input device 1 in the Java application based on the vehicle information from the vehicle state notification process in step ST41. Is converted into an operation signal and sent to the Java application execution process (step ST14). In this case, for example, when the steering angle is large, the road that is currently running is an expressway, the shift lever is set to the back, or the current location approaches a preset accident occurrence point, Therefore, an operation signal is not notified to the Java application execution unit 12 so that the operation input device 1 cannot be operated.

  Next, a Java application execution process is performed (step ST14). In other words, the Java application operates as the execution unit 23, receives the operation signal that is the result of the operation input assignment execution process in step ST42, and executes the Java application in the provided Java execution environment.

  It should be noted that the function assignment rule can be set by being described in a Jad file attached to the Java application as in the first embodiment. Alternatively, as in the second embodiment, an API for setting function allocation corresponding to the vehicle state may be implemented and configured to be performed by an API call from a Java application.

  As described above, according to the in-vehicle information system according to Embodiment 3 of the present invention, the function assignment for the operation input device 1 can be changed according to the operation state of the external device or vehicle connected to the in-vehicle information system.

  In addition, in combination with the above-described in-vehicle information system according to the third embodiment and the in-vehicle information system according to the first embodiment, the operation is performed according to the execution state of the program and the operation state of the external device or vehicle connected to the in-vehicle information system. The function allocation for the input device 1 can be changed. FIG. 16 is a diagram showing a functional configuration of the car navigation device 2 in this case. The operation input allocation changing unit 25 is activated by the control unit 21 that has received an input signal sent from the operation input device 1, and is sent from the function allocation rule set by the allocation rule setting unit 22 and the execution state determination unit 24. Based on the determination result received and the determination result sent from the external state determination means 26, an operation signal for changing the function assigned to the operation input device 1 is generated and sent to the execution means 23. Although detailed description is omitted, the operation of the in-vehicle information system is an operation in which the operation of the in-vehicle information system according to Embodiment 1 described above and the operation of the in-vehicle information system according to Embodiment 3 are combined.

Embodiment 4 FIG.
The in-vehicle information system according to Embodiment 4 of the present invention includes a plurality of operation input devices.

  FIG. 17 is a diagram illustrating a schematic configuration of the in-vehicle information system according to the fourth embodiment. This in-vehicle information system is configured by adding a rear window switch 7 as a second operation input device and a rear display device 8 to the in-vehicle information system according to the first embodiment. For example, as shown in FIGS. 23 and 24, the rear window switch 7 includes a left seat side rear window switch 7a arranged in the rear left seat and a right seat side rear window switch 7b arranged in the rear right seat. Each of them is connected to the car navigation device 2 by an in-vehicle LAN 4. The rear display device 8 is provided in the approximate center of the rear seat and is connected to the car navigation device 2 by the in-vehicle LAN 4.

  Next, the operation of the in-vehicle information system according to the fourth embodiment will be described focusing on the operation of the car navigation device 2. FIG. 18 is a flowchart showing a process when a Java application is executed in the car navigation device 2. In the following, the same parts as those of the processing steps in the in-vehicle information system according to the first embodiment shown in the flowchart of FIG.

  When executing a Java application, first, a Java application reception process is performed (step ST11). Next, a function assignment determination process is performed on the Java application downloaded in step ST11 (step ST12). That is, the Java application management unit 14 operates as the execution state determination unit 24, refers to the Jad file attached to the Java application, and uses the function assignment rule described therein as the operation result assignment execution process ( To step ST13).

  For example, a function assignment rule as shown in FIG. 19 is added to the Jad file. In the example shown in FIG. 19, by adding a line “XXX-RearWindow Operation: KEY_LEFT and KEY_RIGHT” to the Jad file, the window close 7 is provided when the rear seat window switch 7 has left and right buttons. Is assigned to the left button, and window open is assigned to the right button. Similarly, by adding a line “XXX-RearWindow Operation: KEY_UP and KEY_DOWN”, when the rear seat window switch 7 has front and rear buttons as shown in FIGS. 23 and 24, the window is opened. Can be assigned to the back button and window close can be assigned to the front button.

  On the other hand, a vehicle state notification process is performed in parallel with the Java application reception process and the function assignment determination process (step ST41). That is, the navigation service 10 periodically monitors the vehicle state, and when the vehicle state changes, notifies the vehicle information at that time to the operation input allocation execution unit. Specifically, the vehicle status is monitored in the navigation service 10 in FIG. 4, and the current location, steering wheel steering angle, shift lever position, traveling road type, position where the operation input device 1 is installed, or the number of operation input devices 1 When any of the above changes, the Java execution environment is notified to the Java execution environment through the JavaVM interface module in the navigation service 10.

  Next, an operation input assignment execution process is performed (step ST51). In other words, the Java application execution unit 12 operates as the operation input assignment changing unit 25 and changes the function assignment based on the notified vehicle information and the function assignment rule. For example, when the steering wheel steering angle is large or the currently running road is an expressway, the operation from the operation input device 1 on the instrument panel is not notified to the Java application execution unit 12 for safety. An input signal from the window switch 7 at the rear seat is converted into an operation signal that can be interpreted by the Java application execution unit 12 and notified to the Java application execution unit 12. Next, a Java application execution process is performed (step ST14). In other words, the Java application operates as the execution unit 23, receives the operation signal that is the result of the operation input assignment execution process in step ST42, and executes the Java application in the provided Java execution environment.

  As described above, according to the in-vehicle information system according to Embodiment 4 of the present invention, when there are a plurality of operation input devices, it is possible to set function allocation for each operation input device.

  In the fourth embodiment, the function assignment rule is described in the Jad file. However, as in the second embodiment, the function assignment of the API for setting the function assignment corresponding to the vehicle state and the window switch for the rear seat is set. An API can be implemented and configured to be set by an API call from a Java application.

  Further, when the function assignment of the operation input device 1 installed on the instrumental panel or the window switch 7 in the rear seat is changed, the function set for each operation can be notified to the user. FIG. 20 is a diagram showing a functional configuration of the car navigation device 2 in this case. This car navigation device 2 is configured by adding an operation allocation status notification means 28 to the car navigation device according to the second embodiment. For example, if the operation input device 1 or the rear seat window switch 7 has a lamp, the operation allocation status notifying unit 28 corresponds to the lamp, and the function allocation is changed by lighting or blinking the lamp. Can be notified.

  In addition, icons are displayed so that the correspondence between the operation and the function can be understood as in the display example on the front seat display device 3 shown in FIG. 21 and the display example on the rear display device 8 in the rear seat shown in FIG. It can also be configured to notify the user. In this case, the operation allocation status notification means 28 of the present invention corresponds to the display device 3 and / or the rear display device 8. At this time, when displaying on the display device 3 in the front seat, an icon simulating the operation input device 1 installed on the instrument panel is arranged on the rear seat when displaying on the rear display device 8 in the rear seat. An icon simulating the existing window switch 7 can be displayed. In this way, by displaying the icon, the configuration is such that the function currently assigned to each input operation is notified, so that the user can easily know the operation method and the usability is improved.

  It should be noted that separate function assignments can be set for the left seat rear window switch 7a and the right seat rear window switch 7b for the rear seat. Assume a state as shown in FIG. FIG. 23 is a conceptual diagram when the rear seat space is viewed from above, and the rear display device 8 of the rear seat can be rotated in the left and right seat directions.

  As shown in FIG. 23, when the screen shown in FIG. 9A is displayed when the rear display device 8 is facing the left seat side, the window for the left seat side rear window switch 7a is displayed. Set Close to the front button and Window Open to the rear button. As shown in FIG. 24, when the screen as shown in FIG. 9A is displayed when the rear display device 8 is facing the right seat side, the window closing is performed for the right seat side rear window switch 7b. Is set to the back button, and window open is set to the front button.

  As a function allocation setting method, the left seat side rear window switch 7a and the right seat side rear window switch 7b are respectively set when the function allocation rule is described in the Jad file. This can be realized by receiving information indicating the direction in which the display device 8 is facing (whether it is the right seat side or the left seat side) and switching the target on which the function assignment is performed based on the information.

  A rear seat rear display device 8 that can be rotated in the left and right seat directions is used, and is assigned to the left seat rear window switch 7a and the right seat rear window switch 7b in accordance with the direction of rotation. When the display device is configured so that different images can be seen when viewed from the left side and when viewed from the right side, the left seat side rear window switch 7a and the right seat side are configured. The function assigned to the rear window switch 7b can be switched.

  In the first to fourth embodiments described above, the case where the present invention is applied to the Java application that operates on the car navigation apparatus has been described. However, the application target is not limited to the Java application, and the CD playback application It can also be applied to DVD playback applications and navigation applications.

  In addition, an operation input device that can be rotated is used as the operation input device installed on the instrumental panel, but an operation input that generates an input signal similar to the rotation operation by tracing the surface of a person in a circle. An apparatus can also be used.

It is a block diagram which shows schematic structure of the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of the operation input apparatus of the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is a figure which shows the functional structure of the car navigation apparatus of the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of the software installed in the car navigation apparatus of the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is a figure which shows in detail the functional structure of the car navigation apparatus of the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is a figure which shows further in detail the functional structure of the car navigation apparatus of the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is a flowchart which shows the process at the time of performing a Java application in the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is a figure which shows the example of the Jad file attached to the Java application performed in the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is an example of the screen displayed by the Java application performed in the vehicle-mounted information system which concerns on Embodiment 1 of this invention. It is a flowchart which shows the process at the time of performing a Java application in the vehicle-mounted information system which concerns on Embodiment 2 of this invention. It is a figure which shows the example of the Jad file attached to the Java application performed in the vehicle-mounted information system which concerns on Embodiment 2 of this invention. It is a flowchart which shows the process at the time of performing a Java application in the vehicle-mounted information system which concerns on the modification of Embodiment 2 of this invention. It is a figure which shows the example of the Jad file attached to the Java application performed in the vehicle-mounted information system which concerns on the modification of Embodiment 2 of this invention. It is a figure which shows the functional structure of the car navigation apparatus of the vehicle-mounted information system which concerns on Embodiment 3 of this invention. It is a flowchart which shows the process at the time of performing a Java application in the vehicle-mounted information system which concerns on Embodiment 3 of this invention. It is a figure which shows the other structure of the car navigation apparatus of the vehicle-mounted information system which concerns on Embodiment 3 of this invention. It is a block diagram which shows schematic structure of the vehicle-mounted information system which concerns on Embodiment 4 of this invention. It is a flowchart which shows the process at the time of performing a Java application in the vehicle-mounted information system which concerns on Embodiment 4 of this invention. It is a figure which shows the example of the Jad file attached to the Java application performed in the vehicle-mounted information system which concerns on Embodiment 4 of this invention. It is a figure which shows the other structure of the car navigation apparatus of the vehicle-mounted information system which concerns on Embodiment 4 of this invention. It is a figure which shows the example of the screen displayed by the Java application performed in the vehicle-mounted information system which concerns on Embodiment 4 of this invention. It is a figure which shows the other example of the screen displayed by the Java application performed in the vehicle-mounted information system which concerns on Embodiment 4 of this invention. It is a figure for demonstrating the example of the function allocation with respect to the rear window switch performed in the vehicle-mounted information system which concerns on Embodiment 4 of this invention. It is a figure for demonstrating the other example of the function allocation with respect to the rear window switch performed in the vehicle-mounted information system which concerns on Embodiment 4 of this invention.

Explanation of symbols

1 operation input device, 2 car navigation device, 3 display device (output means), 4 in-vehicle LAN, 5 audio device, 6 air conditioner device, 7 rear window switch, 7a left seat side rear window switch, 7b right seat side rear window switch , 8 Rear display device, 10 Navigation service, 10a JavaVM interface module, 11 Java application, 12 Java application execution unit, 12a Navigation service interface module, 13 Java application reception unit, 14 Java application management unit, 21 control means, 22 allocation rule Setting means, 23 execution means, 23a basic service execution means, 23b extended service execution means, 24 execution state determination means, 25 operation input allocation change means, 26 external state determination means, 27 Means, operation assignment status notification means.

Claims (12)

An operation input device for generating an input signal corresponding to the operation;
Control means for receiving an input signal from the operation input device and generating an operation signal for realizing a function assigned to the input signal;
In an in-vehicle information system comprising an execution means for receiving an operation signal from the control means and executing a program according to the operation signal,
An execution state determination unit that determines an execution state of a program executed by the execution unit and sends the determination result to the control unit;
The control means includes
According to the determination result sent from the execution state determination means, the function assigned to the input signal from the operation input device is changed, and the operation input assignment change is generated and the corresponding operation signal is generated and sent to the execution means. In-vehicle information system comprising means. An operation input device for generating an input signal corresponding to the operation;
Control means for receiving an input signal from the operation input device and generating an operation signal for realizing a function assigned to the input signal;
In an in-vehicle information system comprising an execution means for receiving an operation signal from the control means and executing a program according to the operation signal,
An external state determination unit that determines an operation state of a vehicle on which the in-vehicle information system is mounted and sends the determination result to the control unit;
The control means includes
According to the determination result sent from the external state determination means, the function assigned to the input signal from the operation input device is changed, and the corresponding operation signal is generated and sent to the execution means. An in-vehicle information system equipped with a changing means. An external state determination unit that determines an operation state of a vehicle on which the in-vehicle information system is mounted and sends the determination result to a control unit;
The control means includes
Based on the determination result sent from the external state determination means and the determination result sent from the execution state determination means, the function assigned to the input signal from the operation input device is changed to generate a corresponding operation signal. The in-vehicle information system according to claim 1, further comprising: an operation input assignment changing unit that sends the input to the execution unit. The external state determination means determines an operation state based on a current location, a steering angle, a shift lever position, a traveling road type, a position where an operation input device is installed, or the number of the operation input devices. Or the vehicle-mounted information system of Claim 3. Execution means is
Basic service execution means for executing a basic service program;
Extended service execution means for executing the extended service program,
The execution state determination means determines an execution state for each program executed by the extended service execution means,
The operation input allocation change means provided in the control means changes the function assigned to the input signal from the operation input device based on the determination result for each program sent from the execution state determination means, and corresponds The in-vehicle information system according to claim 1 or 3, wherein an operation signal is generated and sent to the execution means. An output means for outputting the execution result of the basic service program executed by the basic service execution means and the execution result of the extended service program executed by the extended service execution means to the screen;
The execution state determination unit determines an execution state for each screen output to the output unit, and sends the determination result to the control unit.
The operation input assignment changing means provided in the control means changes the function assigned to the input signal from the operation input device on the basis of the determination result for each screen sent from the execution state determination means. The in-vehicle information system according to claim 5, wherein the operation signal is generated and sent to the execution means. The program executed by the execution means comprises an application program interface for setting a change in function assigned to an input signal from the operation input device in the operation input assignment change means. The in-vehicle information system according to claim 6. The in-vehicle information according to any one of claims 5 to 7, wherein the extended service execution means is a Java (registered trademark; hereinafter omitted) execution environment and executes a Java application as an extended service program. system. The in-vehicle information system according to any one of claims 1 to 8, further comprising operation assignment status notifying means for notifying a function assigned to an input signal from the operation input device. The in-vehicle information system according to any one of claims 1 to 8, wherein the operation input device generates an input signal by a rotation operation. The operation input allocation changing means changes the function according to the rotation direction, rotation speed, number of rotations or rotation angle of the operation input device, generates a corresponding operation signal and sends it to the execution means. 10. The in-vehicle information system according to 10. In-vehicle information processing that receives an input signal generated in response to an operation of the operation input device, generates an operation signal for realizing a function assigned to the input signal, and executes a program according to the generated operation signal In the program
An in-vehicle information processing program that determines an execution state of the program to be executed, changes a function assigned to an input signal from the operation input device according to the determination result, and generates a corresponding operation signal.

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