JP2014229184A - Display control program and information display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable a display screen to be appropriately scrolled even in a state where it is difficult for a user to operate an operation member.SOLUTION: A display control program is configured to cause a computer to execute: tilt detection for detecting a tilt of a display surface of a display part with respect to a prescribed reference surface (S50); display processing of causing the display part to display information (S10); when a tilt exceeding over a prescribed value is detected by the tilt detection, display control processing of scrolling a display screen toward a tilt direction of the display surface (S70); and, after causing the display part to display the information, when a tilt equal to or less than the prescribed value is detected by the tilt detection, display control processing of causing the scroll of the display screen to be stopped (S80).

Description

  The present invention relates to a display control program and an information display device.

  2. Description of the Related Art When a device is tilted while a display screen is scrolled, a mobile phone that accelerates or decelerates a scroll speed according to the tilt is known (see Patent Document 1).

JP 2008-123199 A

  In the prior art, it is necessary to press the operation member in order to scroll the display screen. For example, it is difficult for the user to scroll the display screen while wearing a glove, for example, while wearing a cold protection gear or protective clothing. was there.

  The display control program according to the present invention detects inclination of a display surface of a display unit with respect to a predetermined reference surface, detection processing for displaying information on the display unit, and detection of an inclination exceeding a predetermined value by inclination detection. A display control process for scrolling the display screen in the tilt direction of the display surface, and a start process for starting the display control process when tilt is detected by tilt detection after displaying information on the display unit. It is made to perform.

  ADVANTAGE OF THE INVENTION According to this invention, even if it is difficult for a user to operate an operation member, a display screen can be scrolled appropriately.

It is a figure which illustrates the appearance of the information display device by one embodiment of the present invention, and Drawing 1 (a) is a front view and Drawing 1 (b) is a rear view. It is a figure which illustrates the information display device which displays a map image. It is a figure which illustrates the information display device in scroll display. It is a figure which illustrates the scene where a user touch-operates a screen display part. It is a figure which illustrates the information display device which displays an enlarged map. It is a block diagram which illustrates the principal part structure of the information display apparatus of FIG. It is a flowchart explaining a map browsing program. It is a block diagram which illustrates the principal part structure of a digital camera. It is a figure explaining the supply aspect of a display control program.

(First embodiment)
Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. 1A and 1B are views illustrating the appearance of the information display device 10 according to the first embodiment of the present invention. FIG. 1A is a front view and FIG. 1B is a rear view. The information display device 10 is configured by, for example, a high-function mobile phone called a smartphone.

  In FIG. 1A, a camera 11 and a display / input unit 20 are provided in front of the information display device 10. In FIG. 1B, a camera 12 is provided on the back surface of the information display device 10.

  The camera 11 in FIG. 1A is used as a user photographing camera when using a videophone function, for example. The display / input unit 20 is configured by a touch panel liquid crystal display having both a display function for displaying an image, a map, an icon 25, and the like on the screen display unit 23, and an operation unit function for receiving a contact operation by a user.

  The display / input unit 20 is provided so as to cover the front of the casing of the information display device 10, and the screen display unit 23 is a display surface and an operation surface. When the screen display unit 23 is touched with a user's finger, the display / input unit 20 determines that the touch operation has been performed based on a change in the detected voltage value caused by the contact of the resistive film, and the contact position, for example. The detection signal shown is output. The display / input unit 20 according to the present embodiment can be operated even with a glove.

  The information display device 10 activates a program associated with the icon 25 displayed on the screen display unit 23 of the display / input unit 20, thereby enabling a telephone function, a mail function, a camera function, a map browsing function, etc. Demonstrates the functions realized by the startup program. Note that the display content of the screen display unit 23 illustrated in FIG. 1A is an example of a so-called home screen. The camera 12 in FIG. 1B is used as a photographing camera when the information display device 10 performs a camera function.

<Outline of automatic scrolling>
FIG. 2 is a diagram illustrating a state in which a map image is displayed on the screen display unit 23 of the display / input unit 20 of the information display device 10 of FIG. For example, when the “map” icon 25 displayed on the display / input unit 20 is touched, the information display device 10 activates the map browsing program associated with the icon 25 to display the input / output unit 20. A map image is displayed on the screen display unit 23.

  In FIG. 2, a message “Automatic scrolling starts when the device is leveled” is displayed on the screen display unit 23 on the map image. When the user holds the information display device 10 substantially horizontally or places the information display device 10 on a flat place, the information display device 10 starts an automatic scroll process. Thereafter, when the user tilts the information display device 10 so that the left side of the screen of the display / input unit 20 is lower than the right side of the screen, the information display device 10 displays the display / input unit 20 as illustrated in FIG. The displayed map is scrolled from the right side of the screen to the left side of the screen (that is, in the direction of the arrow). FIG. 3 is a diagram illustrating the information display device 10 during scroll display.

  Conversely, when the user tilts the information display device 10 so that the right side of the screen of the display / input unit 20 is lower than the left side of the screen, the information display device 10 displays the map being displayed on the display / input unit 20 from the left side of the screen. Scroll to the right of the screen. Similarly, when the user tilts the information display device 10 so that the screen upper side of the display / input unit 20 is lower than the screen lower side, the information display device 10 displays the map being displayed on the display / input unit 20 below the screen. Scroll to the top of the screen.

  FIG. 4 is a diagram illustrating a scene where the user performs a touch operation on the screen display unit 23 of the display / input unit 20. When one point of the screen display unit 23 is touched, the information display device 10 causes the display / input unit 20 to display an enlarged map with a predetermined magnification centered on the touched position. FIG. 5 is a diagram illustrating the information display device 10 displaying an enlarged map. The information display device 10 causes the display / input unit 20 to display an enlarged map with a higher magnification each time a point is touched.

  When, for example, two points on the screen display unit 23 are touched, the information display device 10 returns to the map display of the scale before enlargement with the approximate center of the two positions touched. The information display device 10 causes the display / input unit 20 to display a map with a reduced magnification each time two points are touched.

<Configuration of Information Display Device 10>
Since the present embodiment is characterized by the above-described automatic scroll display, the following description will be focused on this point. The information display device 10 has the following configuration in order to perform the automatic scroll display. FIG. 6 is a block diagram illustrating the main configuration of the information display device 10 of FIG. In FIG. 6, the information display device 10 includes a display / input unit 20, a control unit 30, the cameras 11 and 12, a communication unit 13, and an attitude detection unit 14.

<Display / input unit 20>
The display / input unit 20 includes a position detection unit 21, an information display unit 22, and a screen display unit 23. The position detection unit 21 includes a position detection signal indicating a contact position and display information included in the display control unit 32 (information indicating what is displayed at which coordinate position on the screen display unit 23 of the display / input unit 20). Based on the above, the object (icon 25, marker, etc.) on the screen of the display / input unit 20 is specified. The screen display unit 23 is a display surface and an operation surface as described above. The information display unit 22 is displayed on the screen display unit 23 as a character input window, for example, when character input is required.

<Control unit 30>
The control unit 30 includes a program execution unit 31, a display control unit 32, a communication control unit 33, and a nonvolatile memory 34, and controls the operation of each unit in the information display device 10.

  The program execution unit 31 executes a program associated with the icon 25. The program executed by the program execution unit 31 is a program stored in the nonvolatile memory 34 in association with the icon 25 specified by the position detection unit 21 of the display / input unit 20.

  The display control unit 32 displays an image, an icon 25 and the like on the screen display unit 23 of the display / input unit 20. In addition, the display control unit 32 causes the screen display unit 23 to display a marker 25B indicating the specific target in order to visually notify the user of the target specified by the position detection unit 21. Further, as described above, the display control unit 32 displays the information display unit 22 on the screen display unit 23 when character input is necessary. The communication control unit 33 controls communication with an external device by the communication unit 13. The nonvolatile memory 34 stores programs and data.

<Communication unit 13>
The communication unit 13 performs wireless communication in response to an instruction from the communication control unit 33. The communication unit 13 is configured to be able to perform communication via a wireless LAN (Local Area Network) access point and communication via a mobile phone network.

<Attitude detection unit 14>
The posture detection unit 14 includes an acceleration sensor. The attitude detection unit 14 acquires information indicating the tilt, movement (including the movement direction), and vibration of the information display device 10 based on the acceleration detection signal, and transmits the information to the control unit 30.

<Description of flowchart>
The flow of processing including automatic scrolling will be described with reference to the flowchart illustrated in FIG. FIG. 7 is a flowchart for explaining the map browsing program. When the “map” icon 25 displayed on the display / input unit 20 is touched, the program execution unit 31 activates the map browsing program.

  In step S10 of FIG. 7, the program execution unit 31 displays a map image on the screen display unit 23 of the display / input unit 20 and proceeds to step S20. The map image is, for example, a map acquired by the communication unit 13 and includes a current position estimated based on information from a wireless LAN access point.

  In step S20, the program execution unit 31 determines whether the information display device 10 is horizontal. When the inclination angle of the information display device 10 obtained based on the information from the posture detection unit 14 (the angle between the display surface of the screen display unit 23 and the horizontal plane) is less than a predetermined angle, the program execution unit 31 An affirmative decision is made in step S20 and the process proceeds to step S40. When the inclination angle of the information display device 10 obtained based on the information from the posture detection unit 14 exceeds the predetermined angle, the program execution unit 31 makes a negative determination in step S20 and proceeds to step S30.

  The process proceeds to step S30 when it is determined that the information display device 10 is not in the horizontal state. In this case, the program execution unit 31 causes the message illustrated in FIG. 2 to be displayed on the screen display unit 23 so as to overlap the map image, and returns to step S20. By displaying the message “Automatic scrolling starts when the device is leveled”, the user is prompted to place the information display device 10 in a horizontal state.

  The process proceeds to step S40 when it is determined that the information display device 10 is in the horizontal state. In the present embodiment, the automatic scroll process is started when the information display device 10 is once set in a horizontal state as a trigger. Therefore, in order to inform the user that the automatic scrolling process has started, the program execution unit 31 displays a message such as “The automatic scrolling process is being executed” on the map display 23 on the map image, Proceed to S50. In step S50, the program execution unit 31 detects again the inclination (inclination direction and its inclination angle) of the information display device 10 based on the information from the attitude detection unit 14, and proceeds to step S60.

  In step S60, the program execution unit 31 determines whether the inclination angle of the information display device 10 is less than a predetermined value. If the inclination angle of the information display device 10 obtained based on the information from the posture detection unit 14 is less than the predetermined angle, the program execution unit 31 makes a positive determination in step S60 and proceeds to step S80. When the inclination angle of the information display device 10 obtained based on the information from the posture detection unit 14 exceeds the predetermined angle, the program execution unit 31 makes a negative determination in step S60 and proceeds to step S70.

  When the process proceeds to step S70, it is considered that the information display device 10 has tilted beyond the determination threshold (the predetermined angle). The program execution unit 31 scrolls and displays the image being displayed on the screen display unit 23 at a predetermined speed in the tilt direction obtained based on the information from the posture detection unit 14. FIG. 3 is a diagram illustrating a case where the tilt direction is the left direction of the screen (arrow direction). The program execution unit 31 controls the scroll speed so that the larger the inclination angle, the lower the inclination angle between the predetermined speed (minimum speed) and the predetermined maximum speed.

  When the process proceeds to step S80, the information display device 10 is considered to be in a substantially horizontal state. The program execution unit 31 stops scrolling the screen being displayed on the screen display unit 23, and proceeds to step S90.

  In step S <b> 90, the program execution unit 31 determines whether a touch operation has been performed on the screen display unit 23. When contact is detected by the position detection unit 21, the program execution unit 31 makes a positive determination in step S90 and proceeds to step S100. When the position detection unit 21 does not detect contact, the program execution unit 31 makes a negative determination in step S90 and proceeds to step S130.

  In step S <b> 100, the program execution unit 31 determines whether the contact operation is one point or two points on the screen display unit 23. The program execution part 31 progresses to step S110, when the contact of one point is detected by the position detection part 21. FIG. The program execution unit 31 proceeds to step S120 when the position detection unit 21 detects two contact positions.

  In step S110, the program execution unit 31 causes the screen display unit 23 to display an enlarged image with a predetermined magnification centered on the position where the contact operation is performed (FIG. 5), and returns to step S90. FIG. 5 is an enlarged view of the region A surrounded by the broken line in FIG. 4 by one step.

  In step S120, the program execution unit 31 displays the image at the magnification before magnification on the screen display unit 23 so that the approximate center of the two touched points is the center of the screen, and returns to step S90. The program execution unit 31 causes the screen display unit 23 to display an image with a reduced magnification each time two points are touched.

  In step S <b> 130 of FIG. 7, the program execution unit 31 determines whether an end operation has been performed. For example, when the home switch (not shown) is operated, the program execution unit 31 determines that the operation is to be ended, makes an affirmative determination in step S130, and proceeds to step S140. If the operation of the home switch is not detected, the program execution unit 31 makes a negative determination in step S130 and returns to step S20. When returning to step S20, the above-described processing is repeated.

  In step S140, the program execution unit 31 terminates the display of the map image on the screen display unit 23 of the display / input unit 20, switches to the home screen display illustrated in FIG. Exit.

According to the first embodiment described above, the following operational effects can be obtained.
(1) A program installed in the information display device 10 includes tilt detection for detecting the tilt of the display surface of the display / input unit 20 with respect to a horizontal plane, display processing for displaying a map image on the display / input unit 20, and tilt detection. When a tilt exceeding a predetermined value is detected, the display control process for scrolling the display screen in the tilt direction of the display surface, and after displaying a map image on the display / input unit 20, a tilt equal to or smaller than the predetermined value is detected by tilt detection. Then, the program execution unit 31 is caused to execute a start process for starting the display control process. Thereby, even if it is difficult for the user to operate the operation member, the display screen can be appropriately scrolled. By starting the display control process with an inclination of a predetermined value or less, unintended screen scrolling can be prevented.

(2) After displaying the map image on the display / input unit 20, the program prompts the display / input unit 20 to reduce the tilt of the display surface when the tilt detection does not detect a tilt of a predetermined value or less. Added message display. Thereby, it is possible to inform the user that the inclination of the display surface should be once reduced.

(3) Since the program detects the tilt with reference to the horizontal plane, the display screen can be appropriately scrolled by tilting the display surface with respect to the horizontal plane.

(4) Since the program controls the display to continue scrolling until the tilt detected by the tilt detection becomes equal to or less than a predetermined value after the scroll of the display screen is started in the tilt direction of the display surface, the user can By intuitively tilting the display screen, the display screen can be appropriately scrolled.

(5) The program further includes a contact detection for detecting a contact operation on the display / input unit 20 and a display magnification change for changing a display magnification of a map image displayed on the display / input unit 20 when the contact operation is detected by the contact detection. The program execution unit 31 executes the process. Thereby, even when it is difficult for the user to operate the operation member, the display magnification can be changed only by touching the display / input unit 20.

(6) The program causes the display / input unit 20 to display a map image, and the display control process scrolls the map screen in the tilt direction of the display surface, so that the user can see the area he wants to see on the map. In addition, the map screen can be scrolled appropriately.

(Second embodiment)
The digital camera 100 may constitute an information display device. The digital camera 100 repeats positioning every predetermined time by the GPS module 113 and stores positioning results such as latitude and longitude in the flash memory 111. When the release operation is performed, the digital camera 100 records the captured image data as an image file in a storage medium such as a memory card. At this time, the latest positioning result stored in the flash memory 111 is included in the image file as shooting position information.

  FIG. 8 is a block diagram illustrating the main configuration of the digital camera 100. In FIG. 8, a digital camera 100 includes a photographing optical system 101, an image sensor 102, an AFE (Analog front end) circuit 103, an image processing circuit 104, an LCD monitor 105, a RAM 110, a flash memory 111, and a CPU 112. A GPS module 113, an external interface 114, an operation member 115, and a posture detection unit 116.

  The photographing optical system 101 includes a plurality of lens groups including a zoom lens and a focusing lens, and forms a subject image on the imaging surface of the image sensor 102. In order to simplify FIG. 8, the photographing optical system 101 is shown as a single lens. The image sensor 102 is configured by a CMOS image sensor, for example, and generates an image signal by photoelectrically converting a subject image. The image signal is input to the AFE circuit 103.

  The AFE circuit 103 performs predetermined signal processing on the image signal and converts the image signal after the signal processing into digital data. Digital data is input to the image processing circuit 104. The image processing circuit 104 performs various types of image processing (white balance adjustment processing, image compression processing, image expansion processing, etc.) on the digital data.

  The LCD monitor 105 is constituted by a liquid crystal panel, and displays an image, an operation menu screen, and the like according to an instruction from the CPU 112. The RAM 110 is used as a work memory for the CPU 112. The RAM 110 temporarily stores digital image data in the image processing step performed by the image processing circuit 104.

  The flash memory 111 is a nonvolatile memory, and is used for storing various data in addition to storing a program executed by the CPU 112. The CPU 112 controls an operation performed by the digital camera 100 by executing a program stored in the flash memory 111. The CPU 112 also performs AF (autofocus) operation control and automatic exposure (AE) calculation.

  The posture detection unit 116 includes an acceleration sensor. The posture detection unit 116 acquires information indicating the tilt, movement, and vibration of the digital camera 100 based on the acceleration detection signal, and sends the information to the CPU 112. The operation member 115 includes a main switch, a release button, a menu switch, and the like. The operation member 115 sends an operation signal corresponding to each operation, such as a main switch operation, a release operation, and a menu selection operation, to the CPU 112. The CPU 112 acquires the positioning data from the GPS module 113 in addition to monitoring the input of the operation signal from the operation member 115.

  The external interface 114 performs wired communication or wireless communication with an external device (such as a personal computer or a wireless LAN device) according to an instruction from the CPU 112, and transmits and receives data. Thereby, it is possible to send a photographed image to an external device or to acquire a map image from the external device.

  The GPS module 113 receives radio waves from the four GPS satellites 30A to 30D, and calculates positioning data (latitude, longitude, etc.) using information carried on the received radio waves. The CPU 112 receives positioning data from the GPS module 113 every predetermined time (for example, 10 seconds) and overwrites and stores the positioning data in a predetermined area of the nonvolatile memory (flash memory 111).

  The CPU 112 when the information indicating the positioning data of the shooting location is set to be stored in association with the captured image, generates an Exif (trademark) format image file including the captured image data and the positioning data, and is not shown. The image file is controlled to be recorded on the storage medium. Specifically, when the CPU 112 receives a release button pressing operation signal, the CPU 112 sends an instruction to each block in FIG. 8 to start shooting processing, and records the shot image file in a storage medium (not shown).

  When the image playback switch constituting the operation member 115 is operated, the CPU 112 causes the LCD monitor 105 to display a playback image based on the image file data recorded in the storage medium (not shown). When the zoom switch constituting the operation member 115 is operated to be up, the CPU 112 enlarges and displays the reproduction image being displayed on the LCD monitor 105 around the center of the screen, and overlays the reproduction image to “ The message “Automatic scrolling will start.” Is displayed. Note that the CPU 112 causes the LCD monitor 105 to display a reproduction image with an increased magnification each time a zoom-up operation is performed until the enlarged display magnification reaches a predetermined magnification.

  When the user holds the digital camera 100 so that the display surface of the LCD monitor 105 is substantially horizontal, the CPU 112 starts an automatic scroll process. Thereafter, for example, when the user tilts the digital camera 100 so that the left side of the LCD monitor 105 is lower than the right side of the screen, the CPU 112 scrolls the reproduced image displayed on the LCD monitor 105 from the right side of the screen toward the left side of the screen. Display.

  When the zoom switch constituting the operation member 115 is down-operated, the CPU 112 restores the enlargement magnification of the reproduced image being displayed on the LCD monitor 105. The CPU 112 causes the LCD monitor 105 to display a reproduced image with a reduced magnification each time a zoom-down operation is performed until the enlarged display magnification returns to the original display magnification.

  When the map display switch constituting the operation member 115 is operated, the CPU 112 causes the LCD monitor 105 to display a map image indicating the shooting location of the image instead of the image displayed on the LCD monitor 105. The map image is a map including the shooting location indicated by the positioning data stored together with the image data in the image file, and is an image acquired from the external device via the external interface 114. Note that if the positioning data has not been acquired or if no map image has been acquired, the map image cannot be displayed. For example, the CPU 112 does not acquire positioning data. The message “Not acquired” is displayed on the LCD monitor 105.

  When the zoom switch constituting the operation member 115 is operated to be up, the CPU 112 enlarges and displays the center of the map image displayed on the LCD monitor 105 around the center of the screen. The message “Automatic scrolling will start.” Is displayed. Note that the CPU 112 causes the LCD monitor 105 to display a map image with an increased magnification each time a zoom-up operation is performed until the enlarged display magnification reaches a predetermined magnification.

  When the user holds the digital camera 100 so that the display surface of the LCD monitor 105 is substantially horizontal, the CPU 112 starts an automatic scroll process. Thereafter, for example, when the user tilts the digital camera 100 so that the right side of the LCD monitor 105 is lower than the left side of the screen, the CPU 112 scrolls the map image being displayed on the LCD monitor 105 from the left side of the screen toward the right side of the screen. Display.

  When the zoom switch constituting the operation member 115 is down-operated, the CPU 112 restores the enlargement magnification of the map image being displayed on the LCD monitor 105. The CPU 112 causes the LCD monitor 105 to display a map image with a reduced magnification each time a zoom-down operation is performed until the enlarged display magnification returns to the original display magnification.

  When the image reproduction switch constituting the operation member 115 is operated again, the CPU 112 causes the LCD monitor 105 to display the reproduction image displayed before the map display instead of the map image displayed on the LCD monitor 105. .

According to the second embodiment described above, the following operational effects can be obtained.
(1) A program installed in the digital camera 100 exceeds a predetermined value by tilt detection for detecting the tilt of the display surface of the LCD monitor 105 with respect to a horizontal plane, display processing for displaying a map image on the LCD monitor 105, and tilt detection. When the tilt is detected, the display control process for scrolling the display screen in the tilt direction of the display surface, and after the map image is displayed on the LCD monitor 105, the display control process is started when a tilt of a predetermined value or less is detected by the tilt detection. The CPU 112 is made to execute the start process. Thereby, even if it is difficult for the user to operate the operation member, the display screen can be appropriately scrolled. By starting the display control process with an inclination of a predetermined value or less, unintended screen scrolling can be prevented.

(2) After displaying the map image on the LCD monitor 105, the program causes the LCD monitor 105 to display a prompt to reduce the inclination of the display surface when the inclination below the predetermined value is not detected by the inclination detection. I made it. Thereby, it is possible to inform the user that the inclination of the display surface should be once reduced.

(3) Since the program controls the display to continue scrolling until the tilt detected by the tilt detection becomes equal to or less than a predetermined value after the scroll of the display screen is started in the tilt direction of the display surface, the user can By intuitively tilting the display screen, the display screen can be appropriately scrolled.

(4) The program displays a map image on the LCD monitor 105, and the display control process scrolls the map screen in the tilt direction of the display surface, so that the user can display the area he wants to see on the map. You can scroll the map screen appropriately.

(Modification 1)
In the above description, the information display device 10 has been described using the high-function mobile phone or the digital camera 100 as an example, but a tablet terminal may be used. Here, the supply of the map browsing (display control) program to the high-function mobile phone, the tablet terminal or the like is performed by infrared communication or short-range wireless communication from the personal computer 205 storing the program, for example, as illustrated in FIG. Send to functional mobile phone etc.

  The program may be supplied to the personal computer 205 by setting a storage medium 204 such as a CD-ROM storing the program in the personal computer 205, or to the personal computer 205 by a method via the communication line 201 such as a network. You may load. When passing through the communication line 201, the program is stored in the storage device 203 of the server 202 connected to the communication line.

  It can also be transmitted to a high-function mobile phone or the like via a wireless LAN access point (not shown) connected to the communication line 201. Further, a storage medium 204B such as a memory card storing the program may be set in a high-function mobile phone or the like. Thus, the map browsing program can be supplied as various forms of computer program products such as provision via a storage medium or a communication line.

(Modification 2)
In the first embodiment, the example in which the map image is automatically scrolled by the information display device 10 has been described. However, the information display device 10 also automatically scrolls the captured image as in the second embodiment. It may be.

(Modification 3)
In step S90 of the first embodiment, the program execution unit 31 has been described in the case where the display image is displayed with the magnification of the display image changed when the screen display unit 23 is touched. Instead of changing the magnification of the display image according to the contact operation, the magnification of the display image may be changed according to the vibration applied to the information display device 10. In this case, the program execution unit 31 detects vibration of the information display device 10 based on information from the posture detection unit 14.

  For example, when one vibration is detected, the program execution unit 31 proceeds to step S110, and performs display with an increased display magnification. For example, if the next vibration is detected within one second after detecting one vibration, it is determined that the second vibration has been detected, and the process proceeds to step S120 to display with a reduced display magnification. According to the third modification, the display magnification can be changed according to the vibration applied to the information display device 10 even in a situation where it is difficult for the user to operate the operation member. If one vibration is detected and the next vibration is detected after one second has elapsed, it is determined that one vibration has been detected twice, and the display magnification is increased by two levels.

  The program execution unit 31 may change the magnification of the display image according to the moving direction of the information display device 10. In this case, the program execution unit 31 detects the moving direction of the information display device 10 based on the information from the posture detection unit 14.

  For example, when the program execution unit 31 detects a movement of the display / input unit 20 toward the screen display unit 23 (that is, a direction approaching the user's head (eye)), the program execution unit 31 proceeds to step S110, and displays with increased display magnification. I do. When the movement in the opposite direction (the direction away from the user's head (eye)) is detected, the process proceeds to step S120 to display with a reduced display magnification. Even when the moving direction is detected, the display magnification can be changed according to the vibration applied to the information display device 10 in a situation where it is difficult for the user to operate the operation member.

(Modification 4)
In the first embodiment and the second embodiment described above, the example in which the automatic scroll process is performed according to the inclination angle between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane has been described. Instead, the automatic scrolling process is performed according to the difference between the initial inclination angle α between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane and the inclination angle β changed from the initial inclination angle α. May be performed.

  The program execution unit 31 (or CPU 112) according to the fourth modified example displays the display surface and the horizontal plane of the display / input unit 20 (or the LCD monitor 105) when the map browsing program is activated (or when the map display switch is operated). Is detected as an initial inclination angle α. The program execution unit 31 (or the CPU 112) displays the map image on the display / input unit 20 (or the LCD monitor 105), and then the display surface of the changed display / input unit 20 (or the LCD monitor 105). The image being displayed is scroll-displayed at a predetermined speed based on the angle between the angle and the horizontal plane (inclination angle β).

  According to the fourth modification, the change angle (β−α) from the reference tilt angle α is set based on the initial tilt angle α between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane. When the angle exceeds a predetermined angle, the displayed image is scrolled and displayed at a predetermined speed. Thereby, even in a situation where it is difficult for the user to operate the operation member, the display screen can be appropriately scrolled by tilting the device so as to change the tilt of the display surface.

(Modification 5)
In the first embodiment and the second embodiment, the program execution unit 31 (or the CPU 112) determines that the inclination angle between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane is a predetermined angle. When exceeded, scrolling of the screen is started at a predetermined speed in the tilt direction. Instead, when the state where the tilt angle exceeds the predetermined angle continues for a predetermined time (for example, 2 seconds), scrolling of the screen may be started at a predetermined speed in the tilt direction.

  Similarly, in the program execution unit 31 (or CPU 112) in the fourth modification, the inclination angle between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane is changed from the reference inclination angle α. When the state where the tilt angle exceeds the predetermined angle continues for 2 seconds, scrolling of the screen is started in the tilt direction at a predetermined speed. According to the fifth modification, the scrolling can be appropriately started so as to follow the user's intention to start scrolling the display screen.

(Modification 6)
In addition, the program execution unit 31 (or the CPU 112) is in a state where the inclination angle between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane exceeds a predetermined angle for a predetermined time (eg, 2 seconds) If it is detected twice, scrolling of the screen may be started at a predetermined speed in the tilt direction.

  Similarly, in the program execution unit 31 (or CPU 112) in the fourth modification, the inclination angle between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane is changed from the reference inclination angle α. When the state where the tilt angle exceeds the predetermined angle is detected twice in the two seconds, scrolling of the screen is started in the tilt direction at a predetermined speed. According to the modified example 6, scrolling can be appropriately started so as to follow the user's intention to start scrolling the display screen.

(Modification 7)
In the above description, the program execution unit 31 controls the scroll speed so that the scroll speed increases as the tilt angle between the display surface of the display / input unit 20 and the horizontal plane increases, and decreases as the tilt angle decreases. The example to do was explained. In this case, when the tilt angle is changed and a predetermined time (for example, 2 seconds) elapses, the scroll speed change may be started. According to the modified example 7, the scroll speed can be appropriately changed so as to follow the user's intention to change the scroll speed of the display screen.

(Modification 8)
In the first embodiment and the second embodiment, the program execution unit 31 (or the CPU 112) is configured such that the inclination angle between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane is less than a predetermined angle. When this happens, the scrolling of the display screen is stopped. Instead, the inclination direction of the inclination angle between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane is the inclination direction of the inclination angle detected when the screen scroll display is started. Scrolling of the display screen may be stopped when the direction is different from (for example, opposite).

  Similarly, in the program execution unit 31 (or CPU 112) in the fourth modification, the inclination angle between the display surface of the display / input unit 20 (or the LCD monitor 105) and the horizontal plane is changed from the reference inclination angle α. The scrolling of the display screen is stopped when the tilt direction is different from the tilt direction detected at the time when the scroll display of the screen is started (for example, the opposite direction). According to the modified example 8, the scrolling can be appropriately stopped so as to follow the user's intention to stop the scrolling of the display screen.

(Modification 9)
The program execution unit 31 (or the CPU 112) may stop scrolling the display screen when the scroll amount reaches a predetermined limit value after starting scroll display of the screen.

  Similarly, in the program execution unit 31 (or CPU 112) according to the fourth modification, after the scroll display of the screen is started, the scroll of the display screen is stopped when the scroll amount reaches a predetermined limit value. According to the modified example 9, the scrolling can be appropriately stopped so as to follow the user's intention to limit the scroll amount of the display screen.

(Modification 10)
Furthermore, the program execution unit 31 (or the CPU 112) may stop scrolling of the display screen in accordance with vibration applied to the device after starting scroll display of the screen. In this case, the program execution unit 31 (or CPU 112) detects vibration based on information from the posture detection unit 14 (or posture detection unit 116).

  Similarly, in the program execution unit 31 (or the CPU 112) in the modified example 4, after the scroll display of the screen is started, the scroll of the display screen is stopped according to the vibration applied to the device. According to the modified example 10, the scrolling can be appropriately stopped so as to follow the user's intention to forcibly stop the scrolling of the display screen.

(Modification 11)
In the second embodiment, when the map image is automatically scrolled, the tilt angle (LCD monitor 105) of the digital camera 100 is used by using the image signal acquired by the image sensor 102 without using the detection signal of the posture detection unit 116. The angle between the display surface and the horizontal plane) may be obtained. In this case, the CPU 112 estimates the tilt angle based on a monitor image (live view image) repeatedly captured at a predetermined frame rate (for example, 30 frames / second).

  The CPU 112 estimates the tilt direction and tilt angle of the digital camera 100 based on how the position of the main subject moves between frames in the live view image. If the estimated tilt angle exceeds a predetermined value, the CPU 112 estimates The image being displayed on the LCD monitor 105 is scroll-displayed at a predetermined speed in the tilt direction. Data indicating the relationship between the tilt angle and the amount of image movement between frames is stored in the flash memory 111 in advance. As described above, according to the eleventh modification, automatic scroll display can be performed without using the posture detection unit 116.

(Modification 12)
When the map image is scrolled in the second embodiment, the map image may be scrolled in the tilt direction of the digital camera 100 only while the scroll button is pressed. In the twelfth modification, the CPU 112 displays a message “automatic scrolling in the tilt direction of the device only while the scroll button is pressed” superimposed on the map image being displayed on the LCD monitor 105. When the scroll button constituting the operation member 115 is pressed, the CPU 112 scrolls the map image being displayed on the LCD monitor 105 in the tilt direction of the digital camera 100. For example, when the user tilts the digital camera 100 so that the right side of the screen of the LCD monitor 105 is lower than the left side of the screen, the CPU 112 directs the map image being displayed on the LCD monitor 105 from the left side of the screen to the right side of the screen. Scroll display.

  When the pressing operation of the scroll button constituting the operation member 115 is released, the CPU 112 stops scrolling even when the digital camera 100 is tilted. Note that if the scroll button is pressed again while the digital camera 100 is kept tilted, the CPU 112 resumes scrolling the map image.

  The above description is merely an example, and is not limited to the configuration of the above embodiment.

DESCRIPTION OF SYMBOLS 10 ... Information display apparatus 11, 12 ... Camera 14, 116 ... Attitude detection part 20 ... Display / input part 30 ... Control part 31 ... Program execution part 34 ... Non-volatile memory 100 ... Digital camera 105 ... LCD monitor 112 ... CPU
113 ... GPS module

Claims (10)

Tilt detection for detecting the tilt of the display surface of the display unit with respect to a predetermined reference plane;
Display processing for displaying information on the display unit;
A display control process for scrolling a display screen in a tilt direction of the display surface when a tilt exceeding a predetermined value is detected by the tilt detection;
After the information is displayed on the display unit, a start process for starting the display control process when a tilt of the predetermined value or less is detected by the tilt detection;
A display control program for causing a computer to execute the above. The display control program according to claim 1,
After displaying the information on the display unit, if the tilt detection does not detect a tilt equal to or less than the predetermined value, the display unit displays a display prompting the tilt of the display surface to be reduced. Display control program to be executed. In the display control program according to claim 1 or 2,
In the display control program, the tilt detection detects the tilt of the display surface on the basis of the tilt of the display surface at the time when the information display on the horizontal plane or the display unit is activated. In the display control program according to any one of claims 1 to 3,
The display control program continues the scrolling until the tilt detected by the tilt detection becomes equal to or less than the predetermined value after the display screen starts scrolling in the tilt direction of the display surface. . In the display control program according to any one of claims 1 to 3,
In the display control process, after scrolling the display screen in the tilt direction on the display surface, the scroll is continued until the tilt detected by the tilt detection is opposite to the tilt direction at the start of the scroll. Characteristic display control program. In the display control program according to any one of claims 1 to 5,
Contact detection for detecting a contact operation on the display unit;
When a contact operation is detected by the contact detection, a display magnification change process for changing a display magnification of information displayed on the display unit;
Is further executed by a computer. In the display control program according to any one of claims 1 to 5,
Vibration detection to detect vibration;
When a vibration is detected by the vibration detection, a display magnification change process for changing a display magnification of information displayed on the display unit;
Is further executed by a computer. In the display control program according to any one of claims 1 to 7,
The display process displays a map image on the display unit,
In the display control process, the map screen is scrolled in the tilt direction of the display surface. Tilt detection for detecting the tilt of the display surface of the display unit with respect to a predetermined reference plane;
Operation detection for detecting the presence or absence of an operation signal from the operation member;
Display processing for displaying information on the display unit;
A display control process for scrolling a display screen in a tilt direction of the display surface detected by the tilt detection while the operation signal is detected by the operation detection;
A display control program for causing a computer to execute the above. A display for displaying information;
A program execution unit that executes the display control program according to any one of claims 1 to 9,
An information display device comprising:

Images