JP2010190594A - Navigation apparatus and electronic instrument equipped with navigation function - Google Patents

Abstract

The present invention provides a navigation device capable of changing a user interface screen and an executable application in accordance with a user's usage environment.
A navigation device 1 detects a use environment of the navigation device 1 by using a GPS sensor 18 or detecting the presence / absence of power supply from a cradle 2, and performs navigation based on the detected use environment. A control circuit 11 for setting a user interface screen of the apparatus 1 and an executable application is provided.
[Selection] Figure 2

Description

  The present invention relates to a vehicle-mounted / portable navigation device and an electronic device with a navigation function.

  2. Description of the Related Art A navigation device that detects a connection state with a vehicle and executes a vehicle mode in a state where the release of the connection state is not detected and executes a portable mode in a state where the release of the connection state is detected is known as a related art. (For example, Patent Document 1). This navigation device changes an executable function or changes a button to be displayed between the vehicle mode and the portable mode.

JP 2003-166848 A

  When the navigation device is used in the portable mode, various usage forms and usage environments are assumed. The navigation device described in Patent Document 1 has a problem that the user interface and executable application cannot be changed in accordance with such various usage environments.

(1) A navigation device according to the first aspect of the present invention includes a usage environment detection unit that detects a usage environment of the navigation device, and a user who sets a user interface screen of the navigation device based on the usage environment detected by the usage environment detection unit. It comprises an interface setting means and an application setting means for setting an application to be executed in the navigation device based on the usage environment detected by the usage environment detection means.
(2) The invention according to claim 6 detects the moving speed of the navigation device in the in-vehicle navigation device that can be used when mounted on the cradle and the portable navigation device that can be removed from the cradle. Movement speed detection means, user interface setting means for setting a user interface screen of the navigation apparatus based on the detected movement speed, and application setting for setting an application to be executed on the navigation apparatus based on the detected movement speed Means.
(3) In the electronic device with a navigation function carried by the user and used by the user, the invention according to claim 8 is displayed on the display screen, a display device for displaying a map on the display screen, a current location detecting means for detecting the current location. Display control means for displaying the detected current location mark on the map, a moving speed detecting means for detecting the moving speed of the electronic device based on the detected temporal change amount of the current location, and the detected movement User interface setting means for setting a user interface screen of the electronic device based on the speed, and application setting means for setting an application to be executed on the electronic device based on the detected moving speed.
(4) According to the ninth aspect of the invention, in the electronic device with a navigation function, the moving speed detecting means for detecting the moving speed of the electronic device and the user who sets the user interface screen of the electronic device based on the detected moving speed An interface setting means and an application setting means for setting an application to be executed on the electronic device based on the detected moving speed.

  ADVANTAGE OF THE INVENTION According to this invention, in a navigation apparatus and an electronic device with a navigation function, a user interface screen and an executable application can be changed according to a user's use environment.

It is a figure for demonstrating the external appearance of the navigation apparatus and cradle in embodiment of this invention. It is a block diagram for demonstrating the structure of the navigation apparatus in embodiment of this invention. It is a block diagram for demonstrating the structure of the cradle in embodiment of this invention. It is a figure for demonstrating the mode set to the navigation apparatus in embodiment of this invention. It is a figure for demonstrating the setting conditions of the mode set to the navigation apparatus in embodiment of this invention. It is a figure for demonstrating a user interface screen when the navigation apparatus in embodiment of this invention is set to a home mode. It is a figure for demonstrating a user interface screen when the navigation apparatus in embodiment of this invention is set to park mode. It is a figure for demonstrating a user interface screen when the navigation apparatus in embodiment of this invention is set to drive mode. It is a figure for demonstrating a user interface screen when the navigation apparatus in embodiment of this invention is set to the car mobile mode. It is a figure for demonstrating a user interface screen when the navigation apparatus in embodiment of this invention is set to walk mobile mode. It is a flowchart for demonstrating the mode switching process of the navigation apparatus in embodiment of this invention. It is a flowchart for demonstrating the mode switching process of the navigation apparatus in embodiment of this invention. It is a flowchart for demonstrating the route guidance process in the modification of embodiment of this invention.

  The navigation device of the embodiment of the present invention includes a use environment A that is a use environment attached to a cradle (on-vehicle cradle) installed in a vehicle, and a use environment B that is a use environment removed from the on-vehicle cradle. It is assumed that it will be used. In the usage environment A, the navigation device is used as a vehicle-mounted navigation device, and in the usage environment B, it is used as a portable navigation device. The use environment A of the navigation device can be further divided into a use environment A1 that is the use environment in the vehicle of the stopped vehicle and a use environment A2 that is the use environment in the vehicle of the traveling vehicle. The navigation device usage environment B can be divided into a usage environment B1 that is a usage environment outside the vehicle and a usage environment B2 that is a usage environment inside the vehicle. The navigation device sets a predetermined mode according to these usage environments. Before describing the embodiment in detail, the usage environments A1, A2, B1, and B2 will be briefly described.

-Usage environment A1, A2-
Usage environments A1 and A2 are usage environments of the navigation device when mounted on the in-vehicle cradle. In the usage environments A1 and A2, the power of the navigation device is obtained from the in-vehicle battery. The use environment A1 is a use environment when the vehicle speed is below a predetermined value, and the use environment A2 is a use environment when the vehicle speed exceeds a predetermined value. A mode set in the navigation device under the use environment A1 is called a park mode, and a mode set under the use environment A2 is called a drive mode.

  There are two types of in-vehicle cradle: cradle simple and cradle station. As will be described later, the cradle station supplies the power of the in-vehicle battery to the navigation device 1 via the interface unit. Further, the cradle station can perform data communication with the vehicle control device. As will be described later, the cradle simple supplies the power of the in-vehicle battery to the navigation device 1 through the cigar socket. Unlike the cradle station, the cradle simple does not perform data communication with the vehicle control device.

-Usage environment B1, B2-
Usage environments B1 and B2 are usage environments of the navigation device when removed from the in-vehicle cradle, and the navigation device is driven by a built-in battery. The use environment B1 is a use environment when the moving speed of the navigation device is a predetermined value or less, that is, a use environment when used as a pedestrian navigation. A mode set in the navigation device under the usage environment B1 is referred to as a walk mobile mode. The use environment B2 is a use environment when the moving speed of the navigation device exceeds a predetermined value, that is, a use environment when used as a passenger navigation. A mode set in the navigation device under the usage environment B2 is referred to as a car mobile mode.

-Use environment C-
The usage environment C is a usage environment when the navigation device is detached from the in-vehicle cradle and attached to a cradle connected to a commercial power source. This cradle is called a cradle home. In the usage environment C, the navigation apparatus receives power from the cradle home. A mode set in the navigation device under the usage environment C is referred to as a home mode. In the home mode, the navigation device can perform data communication via the telecommunications line via the cradle home. Thereby, the navigation device can be connected to the Internet network via the cradle, and the user can browse various homepages using the navigation device.

  FIG. 1A is a perspective view of the navigation device 1 according to the embodiment of the present invention attached to the cradle 2. A display monitor 15 is provided on the front of the navigation device 1, and an input device 17 is provided on the side. FIG. 1B is a perspective view of the cradle 2. The cradle 2 is provided with a recess 21 for fitting the navigation device 1, and a terminal pin 22 is provided upright from the bottom surface of the recess 21 for fitting and electrically connecting to the navigation device 1. The cradle 2 supplies power to the navigation device 1 through the terminal pins 22 and outputs vehicle information, homepage information, and the like.

  In this embodiment, as described above, the cradle includes three types of cradle: cradle simple, cradle station, and cradle home. The cradle 2 in FIG. These three types are shown as representatives.

  FIG. 2 is a block diagram showing the configuration of the navigation device 1. The navigation device 1 of this embodiment is configured to be used as a portable navigation device by removing from the above three types of cradle. The navigation device 1 includes a control circuit 11, a ROM 12, a RAM 13, an image memory 14, a display monitor 15, a speaker 16, an input device 17, a GPS (Global Positioning System) sensor 18, a data storage device 19, a touch panel 110, a touch panel control unit 111, It has a one-segment receiving unit 112, a power supply unit 113, and a battery 114.

  The control circuit 11 includes a microprocessor and its peripheral circuits, and performs various controls by executing a control program stored in the ROM 12 using the RAM 13 as a work area. The control circuit 11 performs a predetermined route search process based on the map data stored in the data storage device 19 and displays the processing result on the display monitor 15 as a recommended route.

  The image memory 14 stores image data to be displayed on the display monitor 15. The image data includes road map drawing data and various graphic data, and is appropriately generated in the control circuit 11 based on the map data stored in the data storage device 19.

  The data storage device 19 is configured by a rewritable nonvolatile recording medium such as a flash memory or a hard disk, and stores map data. The map data includes map display data, route search data, and the like. The map display data and the route search data include road link information and node information stored in the map data. The link information includes a link travel time that is information on a required time when a pedestrian or a vehicle passes the link at a predetermined speed. The map display data includes map data at a plurality of scales from wide areas to details. Thereby, the navigation apparatus 1 can change the scale of a map according to a user's instruction | indication.

  The data storage device 19 also stores facility information, music data, etc. downloaded via the Internet. The facility information stored in the data storage device 19 is displayed on the display monitor 15, and the stored music data is reproduced by the control circuit 11 and output from the speaker 16.

  The display monitor 15 displays various types of information such as a map near the current location, and displays a broadcast received by the one-segment receiving unit 112. The speaker 16 outputs sound for instructing the user to perform various input operations and for route guidance. In addition, the speaker 16 outputs music reproduced by the control circuit 11, broadcast received by the one-segment receiving unit 112, and the like. The input device 17 includes an operation member that is operated by a user for setting various commands, and is realized by a button switch, a hard switch, or the like provided on a side surface of the navigation device 1.

  The GPS sensor 18 receives GPS signals transmitted from a plurality of GPS satellites, and detects the current location of the navigation device 1. Based on the current location detected by the GPS sensor 18, the display range of the map, the starting point of the route search, and the like are determined. In addition, the current location detected by the GPS sensor 18 is displayed on the map as a vehicle position mark. The control circuit 11 calculates the movement speed of the navigation device 1 from the movement amount per unit time of the current location detected by the GPS sensor 18.

  The touch panel 110 is a transparent touch switch laminated on the surface of the display monitor 15, and an image displayed on the display monitor 15 is displayed through the touch panel 110. The touch panel 110 sends a signal corresponding to the pressed position on the touch panel 110 to the touch panel control unit 111. The touch panel control unit 111 calculates the pressed position of the touch panel 110 and outputs the calculation result to the control circuit 11. When various buttons and display menus displayed on the display monitor 16 are pressed, the touch panel 19 is pressed, and processing defined in the pressed various buttons and display menu is executed.

  When the destination is set, the end point of the route search is set at the destination. Then, the control circuit 11 searches for a route from the start point to the end point using the route search data. The route thus obtained (hereinafter referred to as a recommended route) is displayed on the display monitor 15 so as to be distinguished from other roads by changing the display form, for example, the display color. Thereby, the user can recognize the recommended route on the map on the screen. The navigation device 1 provides a route guidance by instructing the user with a display screen, voice, or the like so that the vehicle travels according to the recommended route or the user can walk.

  The one seg receiving unit 112 receives a broadcast (one seg broadcast) transmitted using a part of the terrestrial digital broadcast wave, and selects a broadcast station to receive. Broadcast video and character data received by the one-segment receiver 112 are displayed on the display monitor 15, and audio is output from the speaker 16.

  The power supply unit 113 stabilizes the power supplied from the battery 114 built in the navigation device or converts it to a predetermined voltage value. Further, when power is supplied from the cradle 2, the power supply from the battery is cut off by a command from the control circuit 11. The battery 114 is, for example, a manganese dry battery or a lithium ion secondary battery.

  FIG. 3 is a block diagram showing a configuration of the cradle 2 of the present embodiment. The cradle 2 used in the navigation device 1 of the present embodiment is of three types: the cradle home 2A, the cradle simple 2B, and the cradle station 2C described above.

  FIG. 3A is a view for explaining the cradle home 2A. The cradle home 2A is a cradle provided in a room such as a home. The cradle home 2A includes a power supply unit 23A, a data communication interface (I / F) 24A, and a control circuit 25A. The power supply unit 23A converts AC power of commercial power supplied via a not-shown outlet into predetermined DC power, and outputs it to the control circuit 25A. The data communication interface 24A receives various information through an electric communication line connected to the Internet circuit network, and transmits information through the Internet. The control circuit 25A supplies the navigation apparatus 1 with DC power supplied from the power supply unit 23A, and outputs information received by the data communication interface 24A to the navigation apparatus 1. Further, the control circuit 25A transmits information output from the navigation device 1 via the data communication interface 24A.

  FIG. 3B is a view for explaining the cradle simple 2B. The cradle simple 2B is an in-vehicle cradle that is simply installed in a vehicle. The installation of the cradle simple 2B is easy, and the installation is completed by fixing the cradle simple 2B on the dashboard of the vehicle and inserting a power connection portion (not shown) into the power socket of the vehicle. The cradle simple 2B has a power supply unit 23B and a control circuit 25B. The power supply unit 23B converts the DC power supplied from the power socket of the vehicle into DC power of a predetermined voltage and outputs it to the control circuit 25B. The control circuit 25B supplies the power supplied from the power supply unit 23B to the navigation device 1.

  FIG. 3C is a view for explaining the cradle station 2C. The cradle station 2C is an in-vehicle cradle and is used by being connected to the interface unit 3 mounted on the vehicle.

  Here, the interface unit 3 will be described. The interface unit 3 is connected to a vehicle information output terminal, an audio output terminal, and a power supply terminal. The navigation device 1 can acquire an audio output signal and vehicle information of an audio device mounted on the vehicle through the interface unit 3 and can receive power supply from an in-vehicle battery. The vehicle information includes vehicle speed information output from the vehicle speed sensor, vehicle angular velocity information output from the vibration gyro, and the like. The vehicle information output terminal is an output terminal of a vehicle speed sensor, an output terminal of a vibration gyro, or the like. The navigation apparatus 1 can further increase the detection accuracy of the current location of the vehicle by using these pieces of vehicle information.

  The cradle station 2C includes a power supply unit 23C, a data communication interface (I / F) 24C, and a control circuit 25C. The power supply unit 23C converts the DC power supplied from the interface unit 3 into predetermined DC power and outputs it to the control circuit 25C. The data communication interface 24C receives vehicle information and audio output signals output from the interface unit 3, and outputs them to the control circuit 25C. The control circuit 25C supplies the power supplied from the power supply unit 23C to the navigation device 1, and outputs the vehicle information and the audio output signal output from the data communication interface 24C to the navigation device 1.

  Next, the user interface screen and application of the navigation device 1 in this embodiment will be described. As shown in FIG. 4, the navigation device 1 has five modes of a home mode, a park mode, a drive mode, a car mobile mode, and a walk mobile mode, and the user interface screen and executable applications are changed depending on the set mode. Is done. The mode set in the navigation device 1 is automatically switched based on the usage environments A1, A2, B1, B2, and C as described above. The conditions for mode switching will be described later.

  As shown in FIG. 4, the home mode can be switched to the walk mobile mode, and the walk mobile mode can be switched to the home mode. Further, the park mode, the drive mode, the car mobile mode, and the walk mobile mode can be switched to each other.

  The home mode is a mode that is set when the navigation device 1 is attached to the cradle home 2A. In the home mode, the navigation device 1 uses the power supplied from the cradle home 2A and does not use the power from the battery 114. The navigation device 1 can be connected to the Internet through the cradle home 2 </ b> A, and the user can browse a home page or send and receive e-mails using the navigation device 1. In addition, facility information, music information, and the like can be downloaded from a predetermined homepage and stored in the data storage device 19.

  The drive mode and the park mode are modes that are set when the navigation device is attached to the cradle simple 2B or the cradle station 2C. The navigation device 1 used in the drive mode and the park mode uses the power supplied from the cradle simple 2B or the cradle station 2C as in the home mode, and does not use the battery 114.

  The car mobile mode and the walk mobile mode are modes that are set when the navigation device is not attached to the cradle 2. The navigation device 1 used in the car mobile mode and the walk mobile mode uses electric power supplied from the battery 114.

  Next, with reference to FIG. 5, conditions for setting any one of the five modes described above to the navigation device 1 will be described. The mode set in the navigation device 1 is calculated from the presence / absence of power supply from the cradle 2, the current location of the navigation device 1 detected by the GPS sensor 18, and the amount of change per unit time of the detected current location of the navigation device 1. It switches automatically based on the moving speed.

  As shown in FIG. 5, the home mode is set when power is supplied from the cradle, the moving speed of the navigation device 1 is V1 (km / h) or less, and the current location of the navigation device is in a building. V1 is a speed faster than the speed at which the pedestrian walks, and is, for example, 10 km / h. The park mode is set when power is supplied from the cradle, the moving speed of the navigation device 1 is V1 or less, and the current location of the navigation device is on a road or a parking lot.

  As shown in FIG. 5, the drive mode is set when power is supplied from the cradle, the moving speed of the navigation device 1 is higher than V1, and the current location of the navigation device is on the road. The car mobile mode is set when there is no power supply from the cradle, the moving speed of the navigation device 1 is higher than V1, and the current location of the navigation device is on the road. The walk mobile mode is set when power is not supplied from the cradle and the moving speed of the navigation device 1 is V1 or less. In the case of the walk mobile mode, the current location of the navigation device is not considered.

  Next, user interface screens and executable applications in each mode will be described with reference to FIGS.

  FIG. 6A is a diagram for describing a home mode user interface screen and executable applications. On the user interface screen displayed on the display monitor 15, icons 31a to 31h for executing the application are displayed. In the home mode, it is assumed that the user uses the navigation device 1 attached to the cradle home 2A. In other words, the usage environment at home is assumed. Since the user can watch the display monitor 15, the number of applications 31a to 31h displayed on the user interface screen is increased to increase the number of executable applications. The icons 31a to 31h are arranged in a circle so that the icons 31a to 31h can be easily seen.

  Explaining each icon, the “navigation” icon 31a is an icon for performing a route search or displaying a recommended route on a map. The “setting” icon 31 b is an icon for performing various settings of the navigation device 1. The “video” icon 31 c is an icon for reproducing image data of a moving image stored in the data storage device 19. The “one seg” icon 31 d is an icon for outputting the one seg broadcast from the display monitor 15 and the speaker 16.

  The “picture” icon 31 e is an icon for reproducing image data of a still image stored in the data storage device 19. The “Internet” icon 31 f is an icon for connecting to the Internet and browsing a homepage. The “audio” icon 31 g is an icon for reproducing music data stored in the data storage device 19. The “mail” icon 31h is an icon for creating and sending an e-mail or receiving and browsing an e-mail.

  For example, when the user presses the “Internet” icon 31 f, a predetermined homepage is displayed on the display monitor 15 as shown in FIG. Various buttons 32a to 32k used for browsing the home page are displayed below the area where the home page is displayed. Since these buttons 32a to 32k are the same as the buttons displayed on a general browser, description of these buttons 32a to 32k is omitted.

  FIG. 7A is a diagram for explaining a user interface screen in park mode and an executable application. Icons 41 a to 41 h for executing applications are displayed on the user interface screen displayed on the display monitor 15. In the park mode, it is assumed that the user uses the navigation device 1 attached to the cradle simple 2B or the cradle station 2c when the vehicle is stopped. Also in this case, since the user can watch the display monitor 15, the number of applications that can be executed is increased by increasing the number of icons 41a to 41h displayed on the user interface screen. As in the case of the home mode, the icons 41a to 41h are arranged in a circle in order to make the icons 41a to 41h easy to see.

  Next, each icon displayed on the user interface screen will be described. "Navigation" icon 41a, "Setting" icon 41b, "Video" icon 41c, "One Seg" icon 41d, "Picture" icon 41e and "Audio" icon 41g are home mode icons 31a-31e, Since it is the same as 31g, description is abbreviate | omitted. The “parking” icon 41f is an icon for displaying detailed information around the parking lot. The “mail” icon 41h is an icon for viewing an email received in the home mode.

  For example, when the user presses the “parking” icon 41f, as shown in FIG. 7B, the parking spaces 43a and 43b around the current location 42 of the vehicle and the facilities 44a to 44d around the parking lot are displayed on the display monitor 15. Is done. That is, detailed information 44a to 44d around the parking lots 43a and 43b is displayed.

  FIG. 8A is a diagram for explaining a user interface screen in the drive mode and executable applications. Icons 51 a and 51 b for executing applications are displayed on the user interface screen displayed on the display monitor 15. In the drive mode, an environment in which the driver's user uses the navigation device 1 when the vehicle is running is assumed. Since the user cannot watch the display monitor 15, the executable application is limited and the number of icons 51a and 51b displayed on the user interface screen is reduced. The icons 51a and 51b are arranged in a line, and the size of the application icon 51a assumed to be used frequently is made larger than the size of the application icon 51b assumed to be used less frequently.

  Next, each icon displayed on the user interface screen will be described. The “navigation” icon 51 a is an icon for performing a route search or displaying a recommended route on a map. If the route search has already been completed in the home mode or the park mode, the route guidance is started when the user presses the “navigation” icon 51a. Since the “audio” icon 51b is the same as the home mode icon 31g, the description thereof is omitted.

  For example, after the route search is performed in the home mode, when the user presses the “navi” icon 51a, a screen for performing route guidance is displayed on the display monitor 15, as shown in FIG. A map 52 around the current location, a vehicle position mark 53, and a recommended route 54 are displayed on the screen. Further, an icon 55 indicating the estimated arrival time of the destination and the distance to the destination, an icon 56 indicating the direction of turning at the next guidance intersection and the distance to the guidance intersection, an icon 57 indicating the north direction, and a scale of the map 52 are displayed. An icon 58 is displayed. In addition, sound for route guidance is output from the speaker 16.

  FIG. 9A is a diagram for explaining a user interface screen and an executable application in the car mobile mode. On the user interface screen displayed on the display monitor 15, icons 61a to 61e for executing the application are displayed. In the car mobile mode, a usage environment is assumed in which a user other than the driver uses the navigation device 1 in a state where the user is not attached to the cradle 2 when the vehicle is traveling. The icons 61a to 61e are arranged in a line, and the size of an application icon assumed to be used frequently is made larger than the size of the application icon assumed to be used less frequently.

  Next, each icon displayed on the user interface screen will be described. The “one-segment” icon 61a, the “video” icon 61c, the “picture” icon 61d, and the “navigation” icon 61e are the same as in the home mode, and thus the description of the icons 61a, 61c to 61e is omitted. . The “audio” icon 61b is an icon for playing back music data stored in the data storage device 19 by a setting operation more detailed than in the home mode.

  When the user presses the “audio” icon 61b, as shown in FIG. 9B, buttons 63a to 63i for the user to perform a reproduction operation are displayed together with a music information screen 62 for displaying information of music to be reproduced. The The button 63a is a button for repeatedly playing music, and the button 63b is a button for randomly selecting and playing music. The button 63c is a button for reproducing the music being reproduced from the beginning, and the button 63d is a button for returning the music to be reproduced to the previous music. The button 63e is a button for starting the reproduction of music, the button 63f is a button for temporarily stopping the reproduction of music, and the button 63g is a button for switching the music being reproduced to the next music. The button 63h is a button for decreasing the volume of music, and the button 63i is a button for increasing the volume of music.

  FIG. 10A is a diagram for explaining a user interface screen and an executable application in the walk mobile mode. Icons 71 a to 71 f for executing applications are displayed on the user interface screen displayed on the display monitor 15. In the walk mobile mode, a use environment is assumed in which a pedestrian user uses the navigation device 1 in a state where the user is not attached to the cradle 2. The icons 71a to 71f are arranged in a line, and the size of an application icon that is assumed to be used frequently is made larger than the size of the application icon that is assumed to be used less frequently.

  Of the icons 71a to 71f displayed on the user interface screen, the icons 71b to 71f are the same as those in the home mode, and thus the description of the icons 71b to 71f is omitted. Since the “navigation” icon 71a is the same as the “navigation” icon 51a in the drive mode, the description of the “navigation” icon 71a is also omitted.

  After performing the route search in the home mode, when the user presses the “navi” icon 71a, a screen for performing route guidance is displayed on the display monitor 15, as shown in FIG. Similar to the drive mode, a map 72 around the current location, a vehicle position mark 73, and a recommended route 74 are displayed on the screen. Since the walking speed of the pedestrian is slower than that of the vehicle, the scale of the map 72 is closer to the detailed side than the map 52 in the drive mode. Further, as in the drive mode, an icon 75 indicating the estimated arrival time of the destination and the distance to the destination, an icon 76 indicating the direction to turn at the next guidance intersection and the distance to the guidance intersection, an icon 77 indicating the north direction, and An icon 78 indicating the scale of the map 72 is displayed. In addition, sound for route guidance is output from the speaker 16.

  Next, a mode switching process of the navigation device 1 according to the embodiment of the present invention will be described with reference to the flowcharts of FIGS. 11 and 12. The navigation device 1 detects the usage environment of the navigation device 1 by this mode switching process, and sets a mode according to the detected usage environment. 11 and 12 are executed in the control circuit 11 by a program that starts when a power switch (not shown) of the navigation device 1 is turned on.

  In step S101 of FIG. 11, it is determined whether there is an external power supply. This determination is performed by detecting the voltage of a power supply terminal (not shown) provided in the navigation device 1. This power supply terminal is fitted to the terminal pin 22 of the cradle 2 when the navigation device 1 is attached to the cradle 2. The navigation device 1 can be supplied with power from the cradle 2 via this power terminal. If there is an external power supply, an affirmative determination is made in step S101 and the process proceeds to step S102. If there is no external power supply, a negative determination is made in step S101, and the process proceeds to step S201 in FIG.

  In step S102, it is determined whether or not the moving speed of the navigation device 1 is greater than a predetermined speed V1. The moving speed of the navigation device 1 is calculated from the amount of change per unit time of the current location detected by the GPS sensor 18. Since the moving speed of the navigation device is detected from the current position signal from the GPS sensor 18, it is not necessary to receive a vehicle speed pulse from the vehicle when used as an in-vehicle navigation device. If the moving speed of the navigation device 1 is greater than the predetermined speed V1, an affirmative determination is made in step S102, and the process proceeds to step S103. If the moving speed of the navigation device 1 is equal to or lower than the predetermined speed V1, a negative determination is made in step S102 and the process proceeds to step S106.

  In step S103, the user interface (UI) is set to the drive mode. In step S104, the executable application (AP) is set to the drive mode. In step S105, the power supply unit 113 is controlled to use electric power supplied from the outside without using the battery 114. Then, the process proceeds to step S111.

  In step S106, it is determined whether or not the current location of the navigation device 1 is on a road or a parking lot. If the current location of the navigation device 1 is on a road or a parking lot, an affirmative determination is made in step S106, and the process proceeds to step S107. If the current location of the navigation device 1 is neither on the road nor on the parking lot, a negative determination is made in step S106 and the process proceeds to step S109.

  In step S107, the user interface (UI) is set to the park mode. In step S108, the executable application (AP) is set to the park mode. Then, the process proceeds to step S105.

  In step S109, the user interface (UI) is set to the home mode. In step S110, an executable application (AP) is set to the home mode. Then, the process proceeds to step S105.

  In step S111, it is determined whether a power switch (not shown) is turned off. If the power switch is turned off, an affirmative determination is made in step S111, and the mode switching process ends. If the power switch is on, a negative determination is made in step S111, and the process returns to step S101.

  In step S201 of FIG. 12, it is determined whether or not the moving speed of the navigation device 1 is greater than a predetermined speed V1. If the moving speed of the navigation device 1 is greater than the predetermined speed V1, an affirmative determination is made in step S201 and the process proceeds to step S202. When the moving speed of the navigation device 1 is equal to or lower than the predetermined speed V1, a negative determination is made in step S201 and the process proceeds to step S205.

  In step S202, the user interface (UI) is set to the car mobile mode. In step S203, an executable application (AP) is set to the car mobile mode. In step S204, the power supply unit 113 is controlled to use the power supplied from the battery 114. Then, the process proceeds to step S111 in FIG.

  In step S205, the user interface (UI) is set to the walk mobile mode. In step S206, an executable application (AP) is set to the walk mobile mode. Then, the process proceeds to step S204.

The navigation device 1 according to the above embodiment has the following effects.
(1) The usage environment of the navigation device 1 is detected, and a user interface screen of the navigation device is set based on the detected usage environment, and an application to be executed by the user navigation device 1 is set. Thereby, when a user changes the usage environment of the navigation apparatus 1, the user does not need to change a user interface screen or an application according to the usage environment.

(2) The moving speed of the navigation device 1 is detected from the amount of change per unit time of the current location of the navigation device 1. As a result, the movement speed of the navigation device 1 can be detected even when used as the portable navigation device 1, and the signal line connecting the vehicle speed pulse is not required when used as an on-vehicle navigation device. Become. Further, the use environment of the navigation device 1 is detected by detecting the presence or absence of external power supply to the navigation device 1. Thereby, the usage environment of the navigation apparatus 1 can be detected accurately without using a signal indicating the type of the cradle.

(3) The navigation device 1 itself has a built-in battery so that it can be used as a portable navigation device. And when the navigation apparatus 1 supplies electric power via the cradle 2, the power supply from the vehicle-mounted battery is cut off. Therefore, when switching and using as a portable navigation device, a vehicle-mounted navigation device, or a stationary navigation device at home, the user does not need to pay attention to the power supply connection, and the navigation device can be provided with ease of use.

(4) Based on the detected use environment of the navigation device 1, the user interface screen is switched, and the type of icons to be displayed and the arrangement of the icons are set. Thereby, even if a use environment changes, it is easy to operate the navigation apparatus 1 by icon pressing.

The above embodiment can be modified as follows.
(1) The means for detecting the usage environment of the navigation device 1 is not limited to the embodiment as long as the usage environment of the navigation device 1 can be detected.

(2) When the navigation device 1 is removed from the cradle 2, if it can be determined whether a pedestrian is using it or a vehicle occupant is using it, a means for detecting the usage environment of the navigation device 1 Is not limited to the embodiment. The mode setting screen may be displayed on the navigation device 1, and the user may set the use environment on the screen.

(3) In step S106 of FIG. 11, it is determined whether the mode of the navigation device 1 is set to the home mode or the park mode depending on whether the current location of navigation is on a road or a parking lot. However, the mode of the navigation device is set to the home mode depending on the type of the cradle 2 connected to the navigation device 1, for example, whether it is the cradle home 2A, or whether it is the cradle simple 2B or the cradle station 2C. Or the park mode may be determined. In this case, the type of the cradle 2 connected to the navigation device 1 can be recognized by the shape and number of the terminal pins 22 connected to the navigation device 1.

(4) When the navigation apparatus 1 uses the power supplied from the battery 114, the navigation apparatus 1 may be driven in the power saving mode in order to reduce power consumption. The power saving mode is a mode in which the luminance of the display monitor 15 is suppressed or the power consumption of the navigation device 1 is suppressed.

(5) The wireless communication device may be built in the navigation device 1 so that the navigation device can transmit and receive information to and from the outside using a wireless local area network (LAN) or the like in the park mode.

(6) After downloading the facility information from the homepage browsed in the home mode, when the park mode is entered, the facility related to the downloaded facility information is set as the destination, the route is searched, and then the drive mode is entered. Route guidance may be performed according to the searched route. Thus, if facility information is downloaded to the navigation device, it is convenient that the navigation device guides the facility only by attaching the navigation device to the cradle 2B, 2C installed in the vehicle. This process will be described below.

  With reference to the flowchart of FIG. 13, the route guidance process in the modification of embodiment of this invention is demonstrated. The process of FIG. 13 is executed in the control circuit 11 by a program that starts when the navigation device is set to the home mode.

  In step S301, the navigation apparatus determines whether or not the park mode is set. If the park mode is set, an affirmative determination is made in step S301 and the process proceeds to step S302. If the park mode is not set, step S301 is repeated. In step S302, it is determined whether or not the downloaded facility information is in the data storage device 19. If the downloaded facility information is in the data storage device 19, an affirmative determination is made in step S302 and the process proceeds to step S303. If the downloaded facility information is not in the data storage device 19, a negative determination is made in step S303, and the route guidance process is terminated.

  In step S303, the downloaded facility is set as the destination. In step S304, the GPS sensor 18 detects the current location and sets the current location as the departure location. In step S305, a route search is performed to search for a route between the departure point and the destination. In step S306, the navigation device determines whether or not the drive mode has been set. If the drive mode is set, an affirmative determination is made in step S306, and the process proceeds to step S307. If the drive mode is not set, step S306 is repeated.

  In step S307, route guidance is performed according to the route searched in step S305. In step S308, the GPS sensor 18 detects the current location and determines whether the destination has been reached. If the destination has been reached, an affirmative determination is made in step S308, and the route guidance process ends. If the destination has not been reached, a negative determination is made in step S308, and the process returns to step S307.

  (7) In the above-described embodiment, description has been made assuming the use environments A1, A2, B1, B2, and C. In the present invention, any one use environment (use mode) of use environment A used by being mounted on a vehicle and any use environment B (use mode) used without being mounted on a vehicle are used. It is good also as the assumed navigation apparatus. For example, the vehicle-mounted navigation device may be used only in the drive mode, and the portable navigation device may be used only in the walk mobile mode. In this case, the use environment can be determined only by whether or not power is supplied from the cradle. Furthermore, combinations of a plurality of modes, such as enabling use of three modes of drive mode, walk mobile mode, and car mobile mode, are not limited to the embodiments. This mode determination can be performed by combining the above-described determination conditions.

(8) Further, according to the present invention, the user interface screen and the application may be automatically switched and set according to the use environments A1 and A2 in the vehicle-mounted navigation device. Alternatively, the user interface screen and the application may be automatically switched and set according to any two of the use environments B1 and B2 in the portable navigation device.

(9) In the above embodiment, it has been described that the vehicle-mounted navigation device can be mounted on two types of cradle. However, one type of vehicle-mounted cradle may be used.

(10) The cradle home 2A may be connected to a personal computer so that information downloaded from the Internet using the personal computer can be output from the personal computer to the navigation device.

(11) In the above, a description has been given of an in-vehicle navigation device that is attached to a cradle, and a navigation device that can be used as a portable navigation device when detached from the cradle. However, the present invention can also be applied to an electronic device with a navigation function configured as follows.

  That is, the electronic device with a navigation function includes a moving speed detection device that detects a moving speed of the electronic device, a user interface setting unit that sets a user interface screen of the electronic device based on the detected moving speed, and the detection. Application setting means for setting an application to be executed by the electronic device based on the moving speed. The moving speed can be calculated from the amount of change per unit time of the current location measured by GPS. A user interface screen of the electronic device is set based on the current location measured by GPS and the detected moving speed, and an application to be executed by the electronic device is set based on the current location measured by GPS and the detected moving speed. It may be. The electronic device is a mobile phone or a PDA.

  It is also possible to combine one or a plurality of embodiments and modifications. It is possible to combine the modified examples in any way. The above description is merely an example, and the present invention is not limited to the above embodiment.

DESCRIPTION OF SYMBOLS 1 Navigation apparatus 2 Cradle 2A Cradle home 2B Cradle simple 2C Cradle station 15 Display monitor 18 GPS sensor 19 Data storage device 113 Power supply part 114 Battery

Claims (10)

A usage environment detection means for detecting a usage environment of the navigation device;
User interface setting means for setting a user interface screen of the navigation device based on the use environment detected by the use environment detection means;
A navigation device comprising: an application setting unit configured to set an application to be executed by the navigation device based on the usage environment detected by the usage environment detection unit. The navigation device according to claim 1, wherein
Current location detection means for detecting the current location of the navigation device;
A moving speed detecting means for detecting a moving speed of the navigation device;
Power supply detection means for detecting the presence or absence of external power supply to the navigation device,
The use environment detecting means includes a current position of the navigation device detected by the current position detecting means, a moving speed of the navigation device detected by the moving speed detecting means, and presence / absence of power supply detected by the power supply detecting means. And a navigation device for detecting a use environment of the navigation device. The navigation device according to claim 2, wherein
A navigation apparatus comprising: a power supply control means for controlling power supply to the navigation apparatus based on a use environment of the navigation apparatus detected by the use environment detection means. The navigation device according to any one of claims 1 to 3,
The user interface setting means displays an icon on the user interface screen, and sets a type of icon and an icon arrangement to be displayed on the user interface screen based on the use environment detected by the use environment detection means. A navigation device characterized by the above. The navigation device according to any one of claims 1 to 4,
A route search means for searching for a route to the facility acquired through the Internet network;
Route guidance means for performing route guidance according to the route searched by the route search means,
The route search means is an environment in which the use environment detected by the use environment detection means is used as an in-vehicle navigation device, and the route to the facility downloaded by the download means before the start of traveling Explore
The route guidance means is an environment in which the use environment detected by the use environment detection means is used as an in-vehicle navigation device, and provides route guidance according to the route searched by the route search means after the start of traveling. A navigation device characterized by performing. In a navigation device that can be used as an in-vehicle navigation device when attached to a cradle, and a portable navigation device when detached from a cradle,
A moving speed detecting means for detecting a moving speed of the navigation device;
User interface setting means for setting a user interface screen of the navigation device based on the detected moving speed;
A navigation device comprising: application setting means for setting an application to be executed by the navigation device based on the detected moving speed. The navigation device according to claim 6, wherein
A current location detecting means for detecting a current location of the navigation device;
The user interface setting means sets a user interface screen of the navigation device based on the detected moving speed and current location,
The application setting means sets an application to be executed by the navigation device based on the detected moving speed and the current location. In electronic devices with navigation functions that users carry and use,
A display device for displaying a map on the display screen;
Current location detection means for detecting the current location;
Display control means for displaying the detected current location mark on the map displayed on the display screen;
A moving speed detecting means for detecting a moving speed of the electronic device based on the detected time change amount of the current location;
User interface setting means for setting a user interface screen of the electronic device based on the detected moving speed;
An electronic device with a navigation function, comprising: application setting means for setting an application to be executed by the electronic device based on the detected moving speed. In electronic devices with navigation functions,
A moving speed detecting means for detecting a moving speed of the electronic device;
User interface setting means for setting a user interface screen of the electronic device based on the detected moving speed;
An electronic device comprising: application setting means for setting an application to be executed by the electronic device based on the detected moving speed. The electronic device according to claim 9,
A current location detecting means for detecting a current location of the electronic device;
The user interface setting means sets a user interface screen of the electronic device based on the detected moving speed and current location,
The application setting means sets an application to be executed by the electronic device based on the detected moving speed and the current location.

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