JP2014021827A - Information appliance, method and program for display control - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an information appliance enabling a user to specify a movement position and a size of a display area of a display object on the screen freely, and a method and a program for display control of the appliance.SOLUTION: The information appliance includes: display means having a screen on which a display object is displayed; detection means for detecting a locus of movement of indication means on the screen; and control means for identifying the size and location of a specific area in the screen on the basis of a location of the locus on the screen and a direction of a prescribed shape represented by the locus on the screen, and displaying the display object on the specified area, when the locus represents the prescribed shape.

Description

  The present invention relates to an information device, a display control method, and a program. For example, the present invention relates to an information device, a display control method, and a program that control a display position of a display target in a screen.

  Patent Document 1 describes a portable information terminal capable of changing the position of an operation unit (display target) on a screen.

  The portable information terminal described in Patent Literature 1 includes a display unit having a screen, a touch panel, and a control unit. When the operation unit is displayed on the screen and the touch panel accepts a drag operation, the control unit moves the position of the operation unit on the screen in the drag direction of the drag operation.

JP 2009-284468 A

  The user of the portable information terminal described in Patent Literature 1 can move the position of the operation unit on the screen, but cannot specify the size of the display area at the destination of the operation unit. Designating the size of the display area at the movement destination of the operation unit is designating the size of the region where the user wants to display the operation unit, which is a useful function for the user.

  For this reason, a technique that allows the user to easily specify the movement position of the display target on the screen and the size of the display area has been desired.

  An object of the present invention is to provide an information device, a display control method, and a program that can solve the above-described problems.

The information device of the present invention is
Display means having a screen for displaying a display object;
Detecting means for detecting a trajectory of movement of the instruction means on the screen;
When the trajectory represents a predetermined shape, the size and position of the specific region in the screen based on the position of the trajectory on the screen and the orientation of the predetermined shape represented by the trajectory on the screen And control means for displaying the display object in the specific area.

The display control method of the present invention is a display control method performed by an information device,
A display step having a screen for displaying a display object;
A detection step of detecting a trajectory of movement of the instruction means on the screen;
When the trajectory represents a predetermined shape, the size and position of the specific region in the screen based on the position of the trajectory on the screen and the orientation of the predetermined shape represented by the trajectory on the screen And a control step of displaying the display object in the specific area.

The program of the present invention is stored in a computer.
A display procedure having a screen for displaying a display object;
A detection procedure for detecting a trajectory of movement of the instruction means on the screen;
When the trajectory represents a predetermined shape, the size and position of the specific region in the screen based on the position of the trajectory on the screen and the orientation of the predetermined shape represented by the trajectory on the screen And a control procedure for displaying the display object in the specific area.

  According to the present invention, the user can easily specify the movement position of the display target on the screen and the size of the display area.

It is the block diagram which showed the portable terminal 100 of 1st Embodiment of this invention. 1 is an external view of a mobile terminal 100. FIG. 4 is a flowchart for explaining the operation of the mobile terminal 100. It is the figure which showed an example of the motion of the thumb for setting a specific area | region to the lower left part of the screen 1a. It is the figure which showed the specific area | region specified by each of "display large" "displaying" "display small". It is the figure which showed the example of the image 1b1 before the display change mode setting, and the image 1b2 reduced in size so that all the images 1b1 may fit in a specific area | region. It is the figure which showed the example of the image 1b1 before the display change mode setting, and the image 1b2 reduced in size so that all the images 1b1 may fit in a specific area | region. It is the figure which showed the example of the image 1b1 before the display change mode setting, and the image 1b2 reduced in size so that all the images 1b1 may fit in a specific area | region. It is the figure which showed the example which displays a part of image 1b, without changing the size of the image 1b before the display change mode setting, and the image 1b in a specific area. It is the figure which showed the example which displays a part of image 1b, without changing the size of the image 1b before the display change mode setting, and the image 1b in a specific area. It is the figure which showed the example which displays a part of image 1b, without changing the size of the image 1b before the display change mode setting, and the image 1b in a specific area. 2 is a diagram illustrating an information device including a display unit 1, a touch panel 2, and a control unit 3. FIG. 13 is a flowchart for explaining the operation of the information device shown in FIG. It is the figure which showed the example in which a user draws the locus | trajectory of arc-shaped movement with fingers other than a thumb. It is a figure which shows 100 A of portable terminals of 2nd Embodiment of this invention. It is a flowchart for demonstrating operation | movement of 100 A of portable terminals. It is the figure which showed an example of the motion of the thumb for setting a specific area | region to the lower left part of the screen 1a. It is the figure which showed the specific area | region specified by each of "display large" "displaying" "display small". It is the figure which showed an example of the portable terminal 100 of 1st Embodiment which has a multi-window function.

  Embodiments of the present invention will be described below with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a mobile terminal 100 according to the first embodiment of the present invention. FIG. 2 is a diagram illustrating an appearance of the mobile terminal 100.

  The mobile terminal 100 is, for example, a mobile phone or a smartphone, and is an example of an information device. Note that the information device is not limited to a mobile phone or a smart phone. For example, a game machine, a tablet PC (Personal Computer), a notebook PC, a PDA (Personal Data Assistants), a tablet terminal, an electronic bulletin board, or a digital signage But you can.

  The mobile terminal 100 includes a display unit 1, a touch panel 2, and a control unit 3.

  The display unit 1 is an example of a display unit.

  The display unit 1 includes a screen 1a that displays various images. For example, an image 1b as shown in FIG. 2 is displayed on the screen 1a. In FIG. 2, an image 1b is displayed on the entire screen 1a. The image 1b on the screen 1a is not limited to the image shown in FIG. An image 1b on the screen 1a is an example of a display target.

  The touch panel 2 is an example of a detection unit or an input detection unit. Note that the detection means or the input detection means may be a touch sensor or a touch pad.

  The touch panel 2 is stacked so as to overlap the front surface of the display unit 1 and includes an input surface 2a.

  As the touch panel 2, a touch-type touch panel that detects an object when the object touches the input surface 2 a may be used, or when the object approaches the input surface 2 a, a non-contact that detects the object is detected. A touch (proximity detection) type touch panel may be used.

  Hereinafter, an example in which a touch-type touch panel is used as the touch panel 2 will be described. When a non-contact type touch panel is used as the touch panel 2, a word “contact” described later may be replaced with a word “proximity”.

  The touch panel 2 detects a position (hereinafter, referred to as “contact position”) where the instruction unit 200 contacts the input surface 2a.

  The instruction unit 200 is an example of an instruction unit. The instruction unit 200 is, for example, a finger or stylus of a user of the mobile terminal 100 (hereinafter simply referred to as “user”).

  An xy coordinate is assigned to the input surface 2 a of the touch panel 2. The touch panel 2 detects the contact position of the instruction unit 200 using the xy coordinates.

  The touch panel 2 detects the locus of movement of the instruction unit 200 on the screen 1a using the detection result of the contact position of the instruction unit 200.

  The control unit 3 is an example of a control unit.

  The control unit 3 controls the operation of the mobile terminal 100.

  For example, when the trajectory detected by the touch panel 2 represents an arc shape, the control unit 3 displays the screen based on the position of the trajectory on the screen 1a and the direction of the arc shape represented by the trajectory on the screen 1a. The size and position of the specific area in 1a are specified. The specific area is an area for displaying an image on the screen 1a. The position and size of the specific area on the screen 1a are specified by the user. The arc shape is an example of a predetermined shape.

  The control unit 3 displays a part or all of the image on the screen 1a (for example, the image 1b shown in FIG. 2) in the specific area where the size and position on the screen 1a are specified.

  The mobile terminal 100 has a normal mode and a display range change mode. The normal mode is a mode for displaying the image 1b on the screen 1a. The display range change mode is a mode for setting a specific area.

  The control unit 3 manages the mode of the mobile terminal 100.

  In a state where the image 1b is displayed on the entire screen 1a under the normal mode (hereinafter referred to as “normal display state”), the control unit 3 is in a region of a predetermined area or more of the input surface 2a for a predetermined time or longer. When continuous contact of input unit 200 (hereinafter referred to as “switching operation”) is detected, the mode of portable terminal 100 is switched from the normal mode to the display range change mode.

The predetermined area is, for example, 1 cm ² , and the predetermined time is, for example, 2 seconds. The predetermined area is not limited to 1 cm ² and can be changed as appropriate. The predetermined time is not limited to 2 seconds and can be changed as appropriate.

  When the touch panel 2 finishes detecting the locus of movement of the instruction unit 200 on the screen 1a in the state of the display range change mode, the control unit 3 switches the mode of the mobile terminal 100 from the display range change mode to the normal mode.

  When the touch panel 2 detects a switching operation in a situation where the image 1b is displayed in a specific area smaller than the screen 1a under the normal mode (hereinafter referred to as “reduced display situation”), the control unit 3 The display of the image 1b is terminated, and the image 1b is displayed on the entire screen 1a.

  The switching operation is not limited to the contact of the input unit 200 that continues for a predetermined time or more in a region of a predetermined area or more of the input surface 2a, and can be changed as appropriate.

  Next, the operation will be described.

  FIG. 3 is a flowchart for explaining an operation when the touch panel 2 detects a switching operation when the mobile terminal 100 is in the normal display state.

  In the following, it is assumed that the shapes of the screen 1a, the image 1b, and the specific area are rectangular. In the normal display situation, the four corners of the screen 1a and the four corners of the image 1b overlap.

  When the user continuously touches the user's thumb (an example of the instruction unit 200) for a predetermined time or longer in a region of a predetermined area or more on the input surface 2a in the normal display state, the touch panel 2 detects a switching operation (step S301).

  When the touch panel 2 detects the switching operation, the touch panel 2 outputs a detection result of the switching operation to the control unit 3.

  When receiving the detection result of the switching operation in the normal display state, the control unit 3 sets the mode of the mobile terminal 100 to the display range change mode (step S302).

  Subsequently, the control unit 3 displays a change notification display (for example, a display “display range change mode” is displayed) indicating that the mode of the mobile terminal 100 is in the display range change mode on the screen 1a ( Step S303). Note that the method of notification that the mode of the mobile terminal 100 has changed to the display range change mode is not limited to display, and may be, for example, voice notification or vibration notification.

  By viewing the change notification display, the user recognizes that the mode of the mobile terminal 100 has been changed to the display range change mode. Subsequently, the user once removes the thumb from the input surface 2a, and then, in order to set a specific area, the thumb is placed on the input surface so as to draw an arc of an ellipse with the thumb in contact with the input surface 2a again. Move on 2a.

  FIG. 4 is a diagram showing an example of the movement of the thumb for setting the specific area in the lower left portion of the screen 1a. In FIG. 4, the same components as those shown in FIG. 1 or 2 are denoted by the same reference numerals.

  In FIG. 4, the user places the thumb 200 from the start point 200a on the side 1a1 of the screen 1a to the end point 200b on the side 1a2 of the screen 1a with the base of the thumb 200 of the left hand positioned at the lower left corner of the screen 1a. Move to draw an ellipse arc. In FIG. 4, the locus 200c of the movement of the thumb on the screen 1a, that is, on the input surface 2a is shown in an arc shape.

  The touch panel 2 detects a locus of movement of the thumb on the input surface 2a (hereinafter simply referred to as “movement locus”) as the thumb moves on the input surface 2a (step S304).

  In the present embodiment, the touch panel 2 outputs a detection result indicating the thumb position to the control unit 3 every time the position of the thumb moving on the input surface 2a is detected at a predetermined sampling interval. And the detection result showing the position of the thumb output in time series represents the locus of movement.

  Thereafter, the user removes the thumb from the input surface 2a.

  When the thumb is separated from the input surface 2a, the touch panel 2 ends the detection of the movement locus (step S305).

  When the touch panel 2 finishes detecting the movement locus, that is, when the thumb is separated from the input surface 2a, the touch panel 2 outputs a detection result indicating that the thumb is separated from the input surface 2a to the control unit 3.

  When the control unit 3 receives the detection result indicating that the thumb is away from the input surface 2a, the control unit 3 returns the mode of the mobile terminal 100 from the display range change mode to the normal mode (step S306).

  Subsequently, the control unit 3 determines whether or not the trajectory of movement detected by the touch panel 2 in the display range change mode is an arc shape (step S307).

  For example, the control unit 3 determines that the movement trajectory has an arc shape when the straight line connecting the movement trajectory and the start point and the end point does not intersect the portion of the movement trajectory between the start point and the end point. . On the other hand, when the straight line connecting the movement trajectory and the start point and the end point intersects the portion of the movement trajectory between the start point and the end point, the control unit 3 determines that the movement trajectory is not an arc shape.

  When the movement trajectory has an arc shape, the control unit 3 determines the specific area in the screen 1a based on the position of the movement trajectory on the screen 1a and the direction of the arc shape represented by the trajectory on the screen 1a. Is specified (step S308). The direction of the arc shape is a direction from a portion between the start point and the end point of the movement locus toward a straight line connecting the movement locus, the start point, and the end point.

  In the present embodiment, a region existing on the direction of the arc shape from the movement trajectory is also referred to as the inner side of the arc shape represented by the movement trajectory.

  In the present embodiment, the control unit 3 sets, as the specific angle that is one corner of the specific area, the angle that exists inside the arc shape represented by the trajectory of movement among the four corners of the screen 1a. Based on the position of the upper trajectory, the diagonal position of the specific angle in the specific area is set.

  In addition, the control part 3 may set the angle | corner which exists inside the arc shape which the locus | trajectory of a movement represents among the four angles which the image 1b has as a specific angle of a specific area | region.

  In the present embodiment, the control unit 3 specifies the size and position of the specific area in the screen 1a as follows.

  In the following, in order to give redundancy to the size of the specific area, “display large”, “displaying”, and “display small” are alternatively selected as conditions for specifying the size of the specific area in advance. It is assumed that the control unit 3 is set.

  “Display large” is a condition that prioritizes display size. For the specific area set under the condition of “large display”, when the movement trajectory is set based on the movement of the thumb, the touch operation with the thumb may arrive in the direction of the two sides constituting the specific angle. Although it is guaranteed, it is not guaranteed that the touch operation with the thumb reaches the diagonal of the specific angle.

  “Small display” is a condition that prioritizes operability. As for the specific area set under the condition of “small display”, when the movement locus is set based on the movement of the thumb, it is guaranteed that the touch operation with the thumb reaches the entire specific area. .

  “Displaying” is a condition that considers both display size and operability. Regarding the specific area set under the condition “displaying”, when the movement trajectory is set based on the movement of the thumb, the touch operation with the thumb may arrive in the direction of the two sides constituting the specific angle. It is assumed that a touch operation with the thumb can be reached if the thumb is stretched to some extent even with respect to a diagonal of a specific angle.

  The control part 3 sets the angle | corner which exists inside the arc shape which the locus | trajectory of a movement represents among four angles which the screen 1a has as a specific angle.

  Subsequently, the control unit 3 specifies an intersection point between each of the two sides constituting the specific angle and the locus of movement. For example, in the case of FIG. 4, each intersection is a start point 200a and an end point 200b.

  Subsequently, the control unit 3 determines which of “display large”, “displaying”, and “display small” is set.

  When “display large” is set, the control unit 3 sets a rectangular specific region having a vertex of a specific angle and each intersection as a vertex.

  When “small display” is set, the control unit 3 first sets a rectangular reference region having a vertex at a specific angle and each intersection. Subsequently, the control unit 3 determines the position of the specific angle of the reference area and the reference area so that the reference area falls within the setting area defined by each of the two sides constituting the specific angle and the movement trajectory. The reference area is reduced while maintaining the aspect ratio. The control unit 3 identifies the reference area that falls within the setting area as the specific area.

  When “displaying” is set, the control unit 3 determines the diagonal position of the specific angle in the specific area set in “large display” and the specific area in the specific area set in “small display”. The diagonal of the specific angle is set at a position intermediate between the diagonal positions of the corners, and the size and position of the specific area are specified.

  FIG. 5 is a diagram illustrating specific areas specified by “large display”, “displaying”, and “small display”.

  In FIG. 5, the specific area 400a is specified when “large display” is set. The specific area 400b is specified when “displaying” is set. The specific area 400c is specified when “small display” is set.

  When specifying the size and position of the specific area in step S308, the control unit 3 displays the image 1b displayed before setting the display change mode in step S302 in the specific area (step S309).

  The control unit 3 changes the size of the image 1b so that the entire image 1b displayed before the display change mode is set fits in the specific area.

  6 to 8 are diagrams showing examples of an image 1b1 that was displayed before setting the display change mode and an image 1b2 that has been reduced in size so that all of the image 1b1 can fit within a specific area. .

  The control unit 3 may display a part of the image 1b in the specific area without changing the size of the image 1b displayed before setting the display change mode.

  9 to 11 are diagrams illustrating an example in which the image 1b displayed before the display change mode is set and an example in which a part of the image 1b is displayed in the specific area without changing the size of the image 1b.

  If the movement locus is not arc-shaped in step S307, the control unit 3 displays the image 1b on the entire screen 1a (step S310).

  Next, the effect of this embodiment will be described.

  According to the present embodiment, the display unit 1 includes the screen 1a that displays the image 1b. The touch panel 2 detects the locus of movement of the instruction unit 200 on the screen 1a. When the movement trajectory represents an arc shape, the control unit 3 determines whether or not the screen 1a has a position based on the position of the movement trajectory on the screen 1a and the direction of the arc shape represented by the movement trajectory on the screen 1a. The size and position of the specific area are specified, and a part or all of the image 1b is displayed in the specific area.

  For this reason, the user can easily specify the movement position of the image 1b and the size of the display area on the screen 1a by appropriately moving the instruction unit 200 on the screen 1a.

  Note that the above-described effect is also achieved by an information device including the display unit 1, the touch panel 2, and the control unit 3.

  FIG. 12 is a diagram illustrating an information device including the display unit 1, the touch panel 2, and the control unit 3. FIG. 13 is a flowchart for explaining the operation of the information device shown in FIG.

  In the information device shown in FIG. 12, the display unit 1 displays the image 1b on the screen 1a (step S1301). Subsequently, the touch panel 2 detects a locus of movement of the instruction unit 200 on the screen 1a (step S1302). Subsequently, when the movement trajectory represents a predetermined shape, the control unit 3 based on the position of the movement trajectory on the screen 1a and the direction of the predetermined shape represented by the movement trajectory on the screen 1a, The size and position of the specific area in the screen 1a are specified, and a part or all of the image 1b is displayed in the specific area (step S1303).

  In the present embodiment, the shapes of the screen 1a, the image 1b, and the specific area are rectangular. The predetermined shape is an arc shape. The control unit 3 sets, as the specific angle that is one corner of the specific area, a corner that exists inside the arc shape represented by the trajectory of movement among the four corners of the screen 1a or the image 1b. The size and position of the specific area are specified by setting the diagonal position of the specific angle in the specific area based on the position of.

  For this reason, in order to set the movement position of the image 1b on the screen 1a and the size of the display area, the user may set the movement locus of the instruction unit 200 on the screen 1a to an arc shape. The arc-shaped movement trajectory is formed, for example, when the user moves the screen 1a with the left hand (or right hand) thumb while holding the mobile terminal 100 with the left hand (or right hand).

  Therefore, the user can set the moving position of the image 1b on the screen 1a and the size of the display area using the thumb of the hand holding the mobile terminal 100. Therefore, the user can set the moving position of the image 1b on the screen 1a and the size of the display area with one hand.

  Further, when the user operates the mobile terminal 100 with one hand, the user often operates the mobile terminal 100 using the thumb of the hand holding the mobile terminal 100. For this reason, the arc-shaped movement trajectory set by the thumb of the hand holding the portable terminal 100 also represents the boundary of the range in which the user can operate with one hand without holding the portable terminal 100.

  Therefore, the user can move an image (for example, an image to be operated) to a range where it can be operated with one hand without holding the mobile terminal 100 or in the vicinity thereof. In recent years, since the screen size of the mobile terminal tends to increase, it is possible to move the image to a range where the user can operate with one hand without holding the mobile terminal 100 or the vicinity thereof, which improves operability.

  As a matter of course, the user may draw an arc-shaped movement locus using a finger other than the thumb, a stylus, or a finger of a hand that does not have the mobile terminal 100.

  FIG. 14 is a diagram illustrating an example in which a user draws an arc-shaped movement locus with a finger (for example, an index finger) 201 other than the thumb.

  The control unit 3 may set a diagonal of a specific angle within an area of a predetermined distance from the movement trajectory. In this case, for example, it is possible to set a diagonal of a specific angle near the movement locus. The predetermined distance can be set as appropriate.

  In the present embodiment, the control unit 3 changes the size of the image 1b so that all of the image 1b fits in the specific area. For this reason, the user can recognize all of the image 1b in the image 1b in the specific area.

  When the display unit 1 displays the image 1b on the entire screen 1a before the touch panel 2 detects the arc-shaped locus, the control unit 3 sets the size of the image 1b displayed on the entire screen 1a. A part of the image 1b may be displayed in the specific area without changing. In this case, it is possible to prevent the image 1b from becoming difficult to be recognized as the size of the image 1b is reduced.

  In this embodiment, a touch panel is used as the detection unit and the input detection unit. For this reason, it is easy to detect the locus of movement of the instruction unit 200 on the screen 1a.

(Second Embodiment)
In the first embodiment, an arc shape is used as the predetermined shape, but in the second embodiment, a linear shape is used as the predetermined shape. The predetermined shape is not limited to the arc shape or the linear shape, and can be changed as appropriate.

  FIG. 15 is a diagram illustrating a mobile terminal 100A according to the second embodiment of the present invention. In FIG. 15, the same components as those shown in FIG. Hereinafter, the portable terminal 100A illustrated in FIG. 15 will be described focusing on differences from the portable terminal 100 illustrated in FIG.

  In the mobile terminal 100A shown in FIG. 15, the control unit 3A is used instead of the control unit 3 shown in FIG.

  The control unit 3A is an example of a control unit.

  The control unit 3A controls the A operation of the mobile terminal 100.

  For example, when the locus detected by the touch panel 2 represents a straight line shape, the control unit 3A determines the screen based on the position of the locus of movement on the screen 1a and the direction of the line represented by the locus on the screen 1a. The size and position of the specific area in 1a are specified.

  The control unit 3A displays a part or all of the image on the screen 1a (for example, the image 1b shown in FIG. 2) in the specific area where the size and position on the screen 1a are specified.

  Similar to the portable terminal 100, the portable terminal 100A has a normal mode and a display range change mode.

  The control unit 3A manages the mode of the mobile terminal 100A in the same manner as the control unit 3. Similarly to the control unit 3, “large display”, “displaying”, and “small display” are alternatively set in the control unit 3 A as conditions for specifying the size of the specific area.

  Next, the operation will be described.

  FIG. 16 is a flowchart for explaining the operation when the touch panel 2 detects a switching operation when the mobile terminal 100A is in the normal display state. In FIG. 16, the same processes as those shown in FIG. 3 are denoted by the same reference numerals. Further, it is assumed that the shape of the screen 1a, the image 1b, and the specific area is rectangular.

  Hereinafter, the operation of the mobile terminal 100A will be described with a focus on processing different from the processing shown in FIG.

  When step S303 is executed, the user once removes the thumb from the input surface 2a, and then, in order to set a specific area, the user touches the thumb so that a straight line is drawn while the thumb is again in contact with the input surface 2a. Move up.

  FIG. 17 is a diagram showing an example of the movement of the thumb for setting the specific area in the lower left portion of the screen 1a. In FIG. 17, the same components as those shown in FIG. 1 or 2 are denoted by the same reference numerals.

  In FIG. 17, the user places the base of the thumb of the left hand at the lower left corner of the screen 1a, with the thumb directed toward the upper right corner of the screen 1a, and the thumb on the screen 1a (input surface 2a). Make contact. Thereafter, the user moves the thumb so as to draw a straight line toward the lower left corner of the screen 1a while contacting the thumb with the screen 1a (input surface 2a). In FIG. 17, the locus 200d of the movement of the thumb on the screen 1a, that is, the input surface 2a is shown together with the start point 200e and the end point 200f of the locus 200d.

  Thereafter, when step S306 ends, the control unit 3A determines whether or not the movement locus detected by the touch panel 2 in the display range change mode has a linear shape (step S1601).

  When the movement trajectory has a linear shape, the control unit 3A determines the specific region in the screen 1a based on the position of the movement trajectory on the screen 1a and the direction of the straight line represented by the trajectory on the screen 1a. The size and position are specified (step S1602).

  In the present embodiment, the control unit 3A has an angle formed by the direction from the start point to the end point of the linear trajectory and the direction from the start point of the trajectory to the vertex of the corner of the screen 1a among the four corners of the screen 1a. The smallest corner is set as the specific corner of the specific area. Of the four corners of image 1b, control unit 3A has the smallest angle formed by the direction from the start point to the end point of the linear trajectory and the direction from the start point of the trajectory to the vertex of the corner of image 1b. May be set as a specific angle of the specific region. 3 A of control parts set the diagonal position of a specific angle based on the position of the starting point of a locus | trajectory.

  For example, the control unit 3A sets the diagonal position of the specific angle as follows.

  The control unit 3A determines which of “large display”, “displaying”, and “small display” is set.

  When “large display” is set, the control unit 3A sets the specific angle at a position that is outside the starting point of the locus (in a direction opposite to the direction from the starting point to the ending point of the linear locus) at a certain distance from the starting point of the locus. Set the diagonal of. The fixed interval can be set as appropriate.

  When “small display” is set, the control unit 3A sets the diagonal of the specific angle at a position spaced apart from the start point of the track on the inner side (direction from the start point to the end point of the straight track) of the track. Set.

  When “displaying” is set, the control unit 3A sets the diagonal of the specific angle at the position of the start point of the trajectory.

  FIG. 18 is a diagram illustrating specific areas specified by “large display”, “displaying”, and “small display”.

  In FIG. 18, the specific area 400 d is specified when “large display” is set. The specific area 400e is specified when “displaying” is set. The specific area 400f is specified when “small display” is set.

  When the control unit 3A specifies the size and position of the specific area in step S1602, the control unit 3A executes step S309.

  Next, the effect of this embodiment will be described.

  According to the present embodiment, the shapes of the screen 1a, the image 1b, and the specific area are rectangular, and the predetermined shape is a linear shape. Among the four corners of the screen 1a or the image 1b, the control unit 3A has the smallest angle formed by the direction from the start point to the end point of the linear trajectory and the direction from the start point of the trajectory to the vertex of the corner of the screen 1a. The angle is set as a specific angle which is one corner of the specific area, and the size and position of the specific area are set by setting the diagonal position of the specific angle in the specific area based on the position of the start point of the trajectory. Identify.

  For this reason, in order to set the movement position of the image 1b on the screen 1a and the size of the display area, the user may set the movement locus of the instruction unit 200 on the screen 1a to a linear shape. The linear movement trajectory is formed, for example, when the user moves the screen 1a with the left hand (or right hand) thumb while holding the mobile terminal 100A with the left hand (or right hand).

  Therefore, the user can set the moving position of the image 1b on the screen 1a and the size of the display area using the thumb of the hand holding the mobile terminal 100A. Therefore, the user can set the moving position of the image 1b on the screen 1a and the size of the display area with one hand.

  Further, the linear movement trajectory set by the thumb of the hand holding the portable terminal 100A also represents the boundary of the range in which the user can operate with one hand without holding the portable terminal 100A.

  Therefore, the user can move an image (for example, a screen to be operated) to a range where it can be operated with one hand without holding the mobile terminal 100A or in the vicinity thereof.

  Note that the control unit 3A may set a diagonal of a specific angle within a region at a specific distance from the start point of the movement trajectory. In this case, it is possible to set a diagonal of a specific angle within an area of a specific distance from the start point of the movement trajectory. The specific distance can be set as appropriate.

  In each of the above embodiments, the specific angle of the specific area is set to one of the four corners of the screen 1a or the image 1b. For this reason, when the hand operating the mobile terminal 100 or 100A is the left hand, the user can set the specific area at the lower left corner of the screen 1a, and when the hand operating the mobile terminal 100 or 100A is the right hand The user can set the specific area at the lower right corner of the screen 1a. For this reason, each embodiment can cope with both right-handed and left-handed.

  In the first embodiment, as the movement of the instruction unit 200 that forms an arc-shaped locus, the movement from the upper left side to the lower right side is shown on the screen 1a. However, the direction of the movement of the instruction unit 200 is the screen 1a. The direction from the upper left side to the lower right side is not limited and can be changed as appropriate.

  In each of the above embodiments, the arc-shaped trajectory or the linear trajectory does not necessarily have to touch the end (side) of the screen 1a. For example, when the arc-shaped trajectory does not touch the edge of the screen 1a, the control unit 3 predicts an extended portion of the trajectory based on the shape of the drawn arc-shaped trajectory, and the extended portion and the screen The intersection with the end of 1a is set as the start point and end point of the trajectory.

  In each of the embodiments described above, when the control unit 3 or 3A displays the image 1b with the reduced size in the specific area smaller than the screen 1a, the control unit 3 or 3A sets the aspect ratio of the image 1b with the reduced size to the size of the image 1b. The aspect ratio of the image 1b before being reduced may be the same or different. In the case where it is possible to select whether or not to maintain the aspect ratio, the control unit 3 or 3A displays a setting item regarding whether or not the aspect ratio needs to be maintained on the display unit 1 and displays the setting result of the user. Accepted from the touch panel 2 and determines whether or not to maintain the aspect ratio according to the setting result.

  In the above embodiment, the control unit 3 or 3A may enlarge or reduce the image 1b displayed in the specific area based on an instruction from the user. For example, when the touch panel 2 receives an enlargement instruction when the image 1b is displayed in the specific area, the control unit 3 or 3A enlarges the image 1b in the specific area.

  Each of the above embodiments can also be applied to a terminal having a multi-window function.

  FIG. 19 is a diagram illustrating an example of the mobile terminal 100 according to the first embodiment having a multi-window function.

  In the mobile terminal 100 having the multi-window function, it is necessary to select a window (hereinafter referred to as “selected window”) to be displayed in a specific area from among a plurality of windows (display targets). The selection window is an example of a display target.

  The control unit 3 selects the window touched during the switching operation as a selection window.

  Then, when the locus of movement of the instruction unit 200 on the selection window has an arc shape, the control unit 3 selects an angle existing inside the arc shape represented by the movement locus among the four corners of the selection window. And set as a specific angle of a specific area. Thereafter, the control unit 3 operates in the same manner as described above, and displays the selection window in the specific area.

  In the case of the mobile terminal 100A according to the second embodiment having the multi-window function, the control unit 3A selects the window touched during the switching operation as the selection window.

  Then, when the locus of movement of the instruction unit 200 on the selection window has a linear shape, the control unit 3A determines the direction and locus from the start point to the end point of the linear locus among the four corners of the selection window. The angle formed by the direction from the starting point to the apex of the corner of the selection window is set as the specific angle that is one corner of the specific area. Thereafter, the control unit 3A operates in the same manner as described above, and displays the selection window in the specific area.

In each of the above embodiments, a touch panel is used as the detection means. However, the detection means is not limited to the touch panel and can be changed as appropriate. For example, an instruction to move the mouse pointer on the screen 1a is received as detection means, and the mouse pointer is moved on the screen 1a based on the instruction to detect the movement locus of the mouse pointer on the screen 1a. An input unit such as a mouse may be used. The input unit such as a mouse is an example of a movement instruction unit.
The mouse pointer is an example of an instruction unit.

  In the above embodiment, “large display”, “displaying”, and “small display” are alternatively set in the control units 3 and 3A, but “large display”, “displaying”, and “small display” are set. It does not have to be. In this case, the control units 3 and 3A may set the specific area, for example, when “displaying” is always set. Note that the setting condition of the specific area when “display large”, “displaying”, and “display small” are not set is not limited to “displaying” but may be “display large” or “display small”.

  In the above embodiment, the mobile terminals 100 and 100A may be realized by a computer. In this case, the computer reads and executes a program recorded on a recording medium such as a CD-ROM (Compact Disk Read Only Memory) that can be read by the computer, and executes the functions of the portable terminals 100 and 100A. . The recording medium is not limited to the CD-ROM and can be changed as appropriate.

  In each embodiment described above, the illustrated configuration is merely an example, and the present invention is not limited to the configuration.

100, 100A Portable terminal 1 Display unit 1a Screen 2 Touch panel 2a Input surface 3, 3A Control unit

Claims (10)

Display means having a screen for displaying a display object;
Detecting means for detecting a trajectory of movement of the instruction means on the screen;
When the trajectory represents a predetermined shape, the size and position of the specific region in the screen based on the position of the trajectory on the screen and the orientation of the predetermined shape represented by the trajectory on the screen And control means for displaying the display object in the specific area. The information device according to claim 1,
The shape of the screen, the display target, and the specific area is a rectangle,
The predetermined shape is an arc shape,
The control means sets, as a specific angle that is one corner of the specific region, an angle that exists inside the arc shape represented by the trajectory among the four corners of the screen or the display target, An information device that specifies a size and a position of the specific area by setting a diagonal position of the specific angle in the specific area based on the position. The information device according to claim 1,
The shape of the screen, the display target, and the specific area is a rectangle,
The predetermined shape is a linear shape,
Of the four corners of the screen or the display object, the control means has the smallest angle between the direction from the start point to the end point of the linear trajectory and the direction from the start point to the vertex of the corner. Is set as a specific angle that is one corner of the specific region, and the diagonal position of the specific angle in the specific region is set based on the position of the start point of the trajectory. An information device that identifies height and position. The information device according to claim 2,
The control device is an information device that sets the diagonal in a region at a predetermined distance from the trajectory. The information device according to claim 3,
The information device, wherein the control means sets the diagonal in an area of a specific distance from the starting point of the trajectory. The information equipment according to any one of claims 1 to 5,
The information device is an information device that changes a size of the display target so that the display target is entirely within the specific area. The information equipment according to any one of claims 1 to 5,
If the display means displays the display target on the entire screen before the detection means detects the locus of the predetermined shape, the control means changes the size of the display target displayed on the screen. Without displaying the part of the display target in the specific area. In the information equipment according to any one of claims 1 to 7,
The detection means is an input detection means that is disposed in front of the screen and detects a contact position or proximity position of the indication means to detect a movement path of the indication means on the screen, or on the screen An information device which is a movement instruction unit that receives an instruction to move the instruction unit and moves the instruction unit on the screen based on the instruction and detects a movement path of the instruction unit on the screen. . A display control method performed by an information device,
A display step having a screen for displaying a display object;
A detection step of detecting a trajectory of movement of the instruction means on the screen;
When the trajectory represents a predetermined shape, the size and position of the specific region in the screen based on the position of the trajectory on the screen and the orientation of the predetermined shape represented by the trajectory on the screen And a control step of displaying the display object in the specific area. On the computer,
A display procedure having a screen for displaying a display object;
A detection procedure for detecting a trajectory of movement of the instruction means on the screen;
When the trajectory represents a predetermined shape, the size and position of the specific region in the screen based on the position of the trajectory on the screen and the orientation of the predetermined shape represented by the trajectory on the screen And a control procedure for displaying the display object in the specific area.