JP7157104B2 - Display method - Google Patents

Description

The present invention relates to the technology of mobile terminal devices. The present invention also relates to user interface technology for display screens.

2. Description of the Related Art Mobile terminal devices, such as smartphones, which enable input operations by touching a display screen of a touch panel with a user's finger or the like have become widespread. The mobile terminal device controls the display of content, etc. within the display screen according to the touch input operation. The mobile terminal device acquires content information from, for example, the Internet in response to an input operation, and displays the content information on the display screen. At that time, if the entire content cannot be displayed on the display screen, the portable terminal device displays part of the display information of the content. The mobile terminal device accepts various operations such as tapping, swiping, flicking, and pinching as touch input operations within the display screen. For example, in the case of a swipe operation, the user touches the display screen with a finger, moves the finger in the touched state, and then releases the finger. In the flick operation, the user touches the display screen with the finger, moves the finger quickly, and then releases the finger. The mobile terminal device scrolls the display range of the content within the display screen according to the touch input operation. As a result, the user can view other part or the whole of the content on the display screen.

Further, the mobile terminal device is provided with a screen called a basic operation screen or a home screen. For example, on the home screen, icons of a plurality of applications such as mail and browser are arranged. Also, a plurality of home screens may be provided. When an icon is selected by an input operation on the home screen, the application associated with the icon is executed and the application screen is displayed. If multiple applications are running, multiple application screens are provided. The application screen displays all or part of the content or the like. The user can switch the display range of the home screen or the like displayed within the display screen by a touch input operation.

Japanese Patent Laying-Open No. 2011-76349 (Patent Document 1) is cited as a prior art example related to the user interface of the mobile terminal device as described above. Patent Literature 1 describes the following as a mobile information terminal or the like. The mobile information terminal detects the tilt of the device itself, generates tilt information indicating the direction and magnitude of the tilt, and based on the tilt information about the tilt detected while the screen is kept in contact with the touch operation. to change the displayed image.

Further, in recent years, touch panels and portable terminal devices equipped with not only touch sensors but also pressure sensors capable of detecting a pressure state have been realized.

JP 2011-76349 A

However, the size of the display screen of the mobile terminal device is limited. becomes the display range. When a user wants to view desired content or a part or the entire screen, it is necessary to repeat touch input operations such as swiping many times in order to scroll the display range. Repeating the touch input operation many times takes time and puts a burden on the body. In addition, when a large number of icons and the like are arranged on the display screen, the finger may not be able to reach the desired icon or the like when the user searches for the desired icon and touches the location. In that case, for the desired operation, it is necessary to change the state of the handle of the terminal, operate it with both hands, etc., which is troublesome.

When using the technique disclosed in Patent Document 1, when the user touches the display screen of the terminal, which has a substantially flat plate shape, in a horizontal state and tilts the display screen to an angle, the displayed image can be scrolled. . However, the inclination state of the terminal and the state of the handle and fingers vary depending on the individual user, situation, intended operation, and the like. Normally, when a user views a display screen while holding a terminal in his or her hand, the display screen is tilted vertically with respect to the horizontal ground in accordance with the line of sight of the user and the state of the hand held the terminal. often. Therefore, the technology disclosed in Patent Document 1 cannot appropriately handle various situations, and there is a possibility that the contents of the display screen may be difficult to see or may be scrolled by an unintended touch. There is room for improvement in terms of usability.

It is an object of the present invention to provide a user interface technology for a mobile terminal device and a display screen, which can change the display range of content or the like in response to various user conditions with little effort, thereby realizing more suitable usability. is to provide

A representative embodiment of the present invention is a mobile terminal device characterized by having the following configuration.

A mobile terminal device according to one embodiment includes a display unit that displays information on a display screen, a pressure detection unit that detects pressure on the display screen, and a control unit that changes the display range of the information displayed on the display screen. and a display control unit configured to perform: when the pressure detection unit detects a pressure of a predetermined magnitude or more, the display control unit displays on the display screen in a state in which the pressure is held changing the display range of the information to be displayed;

According to the representative embodiments of the present invention, regarding user interface technology for mobile terminal devices and display screens, it is possible to change the display range of content or the like in response to various user states with little effort. More suitable usability can be realized.

1 is a diagram showing an overview of the configuration of a mobile terminal device according to Embodiment 1 of the present invention; FIG. 2 is a diagram showing a functional block configuration of the mobile terminal device according to Embodiment 1; FIG. 2 is a diagram showing the configuration of software and the like of the mobile terminal device according to Embodiment 1; FIG. 4 is a diagram showing content display on an application screen in the mobile terminal device of Embodiment 1. FIG. FIG. 10 is a diagram showing detection of a touch pressure sensor in the mobile terminal device according to the first embodiment; FIG. 4 is a diagram showing the state of use, tilt angle, tilting operation, etc. by a user of the mobile terminal device of Embodiment 1, as viewed from the side; FIG. 10 is a diagram showing a tilting operation and the like of the mobile terminal device according to the first embodiment, as viewed from the front of the display screen; FIG. 10 is a diagram showing scroll display of content as display range change control in the mobile terminal device of Embodiment 1; 4 is a diagram showing a flow of control processing in the mobile terminal device according to the first embodiment; FIG. 4 is a diagram showing the relationship between pressure and scroll speed in the mobile terminal device of Embodiment 1. FIG. FIG. 10 is a diagram showing display screens and switching display of a plurality of home screens in the mobile terminal device according to Embodiment 2 of the present invention; FIG. 10 is a diagram showing operations on the home screen and screen switching as display control in the mobile terminal device of the second embodiment; FIG. 10 is a diagram showing a flow of control processing in the mobile terminal device of the second embodiment; FIG. 10 is a diagram showing a flow of processing for switching screens in the first direction in the mobile terminal device according to the second embodiment; FIG. 10 is a diagram showing a flow of processing for switching screens in the second direction in the mobile terminal device according to the second embodiment; FIG. 10 is a diagram showing a display state of a display screen in a mobile terminal device according to a modification of the second embodiment; FIG. 11 is a diagram showing content history information in a mobile terminal device according to a modification of the second embodiment; FIG. 10 is a diagram showing a plurality of page information of content in the mobile terminal device of Embodiment 2; FIG. 10 is a diagram showing display control in the mobile terminal device according to Embodiment 3 of the present invention; FIG. 12 is a diagram showing a flow of control processing in the mobile terminal device of Embodiment 3; FIG. 10 is a diagram showing the relationship between pressure and time interval in the mobile terminal device of Embodiment 3; FIG. 11 is a diagram showing operations corresponding to left and right hands in the portable terminal device of Embodiment 3; FIG. 10 is a diagram showing display control in the mobile terminal device according to Embodiment 4 of the present invention; FIG. 14 is a diagram showing a flow of control processing in the mobile terminal device of Embodiment 4; FIG. 20 is a diagram showing a flow of icon arrangement change processing in the portable terminal device of the fourth embodiment; FIG. 10 is a diagram showing the appearance and operation of a mobile terminal device according to Embodiment 5 of the present invention; FIG. 20 is a diagram showing a flow of control processing in the mobile terminal device of Embodiment 5;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In principle, the same parts are denoted by the same reference numerals in all the drawings for describing the embodiments, and repeated description thereof will be omitted.

(Embodiment 1)
A portable terminal device according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 10. FIG.

[Configuration overview]
FIG. 1 shows a schematic configuration of a mobile terminal device according to a first embodiment. FIG. 1 shows a state in which the user holds the housing 1 of the portable terminal device with his left hand and touches and presses a portion within the display screen 2 with his thumb. The mobile terminal device is tilted at an absolute tilt angle θ with respect to the horizontal plane. A part of the entire display information 3 such as contents is displayed as a display range 4 on the display screen 2 . For the sake of explanation, the X direction, Y direction, and Z direction are shown. The X direction and the Y direction are directions forming a plane of the housing 1, the display screen 2, the display information 3 of the content, and the like. The X direction is the horizontal direction, horizontal direction, and horizontal direction within the screen. The Y direction is the vertical direction, vertical direction, and vertical direction within the screen. The Z direction is perpendicular to the X and Y directions and is the thickness direction of the housing 1 and the like.

A mobile terminal device includes a display unit, a touch detection unit, a pressure detection unit, an inclination angle detection unit, a display control unit, and the like. The display unit displays display information 3 such as content on the display screen 2 . The touch detection unit detects the presence or absence of a touch on the display screen 2, position coordinates, and the like. The pressure detection unit detects the strength of pressure applied to the display screen 2 and the like. The tilt angle detection unit detects an angle θ, an angle θn, and the like as the tilt angle of the mobile terminal device. The display control unit controls scrolling 5, 6, etc. as control for changing the display range 4 of the display information 3 based on the state of pressing and tilt angle.

When the user wants to view another part of the content displayed on the display screen 2, the user touches and presses a portion within the display screen 2 with, for example, a thumb while holding the device in a suitable hand-held state. At that time, the pressure detection unit detects a pressure equal to or greater than a predetermined magnitude. The tilt angle detection unit detects the tilt angle of the housing 1 at that time. When a predetermined press is detected, the display control unit sets the tilt angle θ detected at that time as the reference angle θ0.

The user performs an operation of tilting the housing 1 while touching and pressing the display screen 2 . In other words, the housing 1 is rotated about a predetermined rotation axis and direction. The tilt angle detection unit similarly detects the tilt angle θn associated with the tilting operation and rotation. The display control unit performs control to change the display range 4 on the display screen 2 according to the magnitude of the difference between the tilt angle θn detected while the touch and pressure are being held and the reference angle θ0. . As the change control, the display control unit controls display operations such as scrolls 5 and 6 and screen switching. Scrolls 5 and 6 are operations for continuously moving the display range 4 displayed on the display screen 2 up and down in the Y direction. Screen switching is an operation of moving the display range 4 so as to switch between a partial area of the content and a unit such as a screen, which will be described later.

The user releases the finger from the display screen 2 in a state in which the desired content or screen portion is displayed by the operation of scrolling 5, 6, or the like. The pressure detection unit detects a state in which there is no pressure equal to or greater than a predetermined magnitude at that time. The display control unit stops scrolling 5, 6, etc. based on the detection of the state of no pressing.

The lower part of FIG. 1 shows the above control on the time axis. The portable terminal device first enters a specific control mode when a touch pressing operation is performed on the display screen 2 with a pressure greater than or equal to a predetermined size from the state of the normal mode. In this control mode, the reference angle θ0 is set, and the change control of the display range 4 is performed according to the tilting operation while the pressure is maintained. When the user lifts his/her finger, there is no pressure of a predetermined magnitude or more, the control mode is released, and the normal mode is restored. In this manner, the user can change the display range 4 of the content or the like by a simple operation to quickly view a desired portion.

[Mobile terminal device (1)]
FIG. 2 shows the functional block configuration of the mobile terminal device according to the first embodiment. The mobile terminal device of Embodiment 1 is a smart phone. A mobile phone, a tablet PC, a PDA, and other various portable digital devices can be applied as the mobile terminal device.

The mobile terminal device of Embodiment 1 includes a main control unit 101, a system bus 102, a ROM 103, a RAM 104, a storage unit 105, an operation unit 106, a vibration generation unit 107, an expansion interface unit 108, a sensor unit 110, an image processing unit 120, It has a voice processing unit 130, a communication processing unit 140, and the like.

The main control unit 101 is composed of a microprocessor unit or the like, and controls the entire mobile terminal device according to program processing. A system bus 102 is a data communication path for transmitting and receiving data between the main control unit 101 and each unit. The ROM 103 is a memory that stores basic operation programs such as an OS, application programs, and the like. For the ROM 103, a rewritable ROM such as EEPROM or flash ROM is used. By updating the program stored in the ROM 103, it is possible to upgrade the version of the basic operation program and expand the functions. The RAM 104 serves as a work area during execution of basic operation programs, application programs, and the like. The storage unit 105 stores application programs and the like.

The operation unit 106 is a part including an input device that allows a user to perform an input operation, and includes operation keys. The operation keys include operation keys for turning the mobile terminal device on/off and standby, and operation keys for displaying a basic operation screen.

The vibration generator 107 vibrates the mobile terminal device using an eccentric motor or the like. This makes it possible to inform the user of the status. The extended interface unit 108 is a group of interfaces for extending the functions of the mobile terminal device. The expansion interface unit 108 is composed of, for example, a USB interface, a memory interface, and the like. The USB interface connects keyboards and other USB devices. The memory interface connects memory cards and other memory media, and transmits and receives data.

The sensor unit 110 is a sensor group for detecting the state of the mobile terminal device. The sensor unit 110 includes a GPS receiver 111 , an acceleration sensor 112 , a gyro sensor 113 , a geomagnetic sensor 114 , an illuminance sensor 115 , a proximity sensor 116 and a touch pressure sensor 117 . Sensor unit 110 may include other sensors.

Using the GPS receiver 111, the position of the mobile terminal device can be detected as latitude and longitude, for example. The motion and tilt of the mobile terminal device can be detected using the acceleration sensor 112 and the gyro sensor 113 . As the tilt, at least the angle of tilt with respect to the horizontal plane can be detected as an absolute tilt. The direction of the mobile terminal device can be detected using the geomagnetic sensor 114 . The illuminance sensor 115 can be used to detect the ambient brightness of the mobile terminal device. The proximity sensor 116 can be used to detect the proximity of the mobile terminal device to surrounding objects.

The touch and pressure sensor 117 can be used to detect the state of finger touch and pressure on the display screen 2 of the display unit 121 . For example, touch presence/absence and touch position coordinates can be detected as the touch state. For example, the presence or absence of pressure and the strength of pressure can be detected as the pressure state. Note that the touch pressure sensor 117 is not limited to the integrated type of the touch sensor and the pressure sensor, and the touch sensor and the pressure sensor may be provided as separate devices.

The image processing unit 120 includes a display unit 121 , an image signal processing unit 122 , a first image input unit 123 and a second image input unit 124 . The display unit 121 configures the display screen 2 and includes a display device such as a liquid crystal panel. The display unit 121 displays the video data processed by the video signal processing unit 122 on the display screen 2 . The display unit 121 corresponds to the function of the touch pressure sensor 117 and may include a touch panel of the type in which the touch pressure sensor 117 is built. The video signal processing unit 122 includes a video RAM or the like, and drives the display unit 121 based on video data input to the video RAM. The video signal processing unit 122 performs format conversion of video data, superimposition processing of menus and other OSD signals, and the like, as necessary. The first image input section 123 and the second image input section 124 are configured by camera units, for example. The camera unit obtains image data of surroundings and objects by converting light input from a lens into an electrical signal using an element such as a CCD or CMOS sensor.

Audio processing unit 130 includes audio output unit 131 , audio signal processing unit 132 , and audio input unit 133 . The audio output unit 131 includes a speaker and outputs the audio signal processed by the audio signal processing unit 132 as audio. The audio input unit 133 includes a microphone, converts ambient audio into audio data, and inputs the audio data.

Communication processing unit 140 includes LAN communication unit 141 , telephone network communication unit 142 , and short-range communication unit 143 . The LAN communication unit 141 performs wireless communication connection and data transmission/reception with a wireless communication access point. The telephone network communication unit 142 performs wireless communication connection, telephone communication, and data transmission/reception with a base station of the mobile telephone communication network. The short-range communication unit 143 is compatible with a communication interface such as BlueTooth (registered trademark), and performs short-range wireless communication with corresponding devices. Each unit of the communication processing unit 140 includes an encoding circuit, a decoding circuit, an antenna, and the like. The communication processing unit 140 may include an infrared communication unit and the like.

[Portable terminal device (2)]
FIG. 3 shows, as a software configuration of the mobile terminal device according to the first embodiment, the configuration of programs and data in the ROM 103, RAM 104, and storage unit 105 in particular. The ROM 103 stores a basic operation program 103a and other programs 103b. The RAM 104 includes a basic operation execution unit 104a, an application execution unit 104b, a temporary storage area 104c, and the like. During execution of the basic operation program, etc., data is held in the temporary storage area 104c as needed.

The storage unit 105 has an application program 105a, various information/data storage areas 105b, and the like. The application program 105a is a program for realizing various functions such as mail, browser, map, game, and electronic book reader. The various information/data storage area 105b stores various types of information and data such as setting information of the portable terminal device and setting information for each application. The storage unit 105 includes a non-volatile storage device such as a flash ROM, SSD, or HDD, and retains stored information even when power is not supplied to the mobile terminal device.

Note that the ROM 103 and the RAM 104 may be configured integrally with the main control unit 101 . Some or all of the functions of the ROM 103 may alternatively be implemented by a partial storage area of the storage section 105 .

The main control unit 101 reads a basic operation program 103a from the ROM 103, develops it in the RAM 104, and executes it, thereby realizing a basic operation execution unit 104a. The main control unit 101 reads the application program 105a from the storage unit 105, develops it in the RAM 104, and executes it, thereby realizing the application execution unit 104b.

The basic action execution unit 104a includes a touch detection unit 201, a pressure detection unit 202, an inclination angle detection unit 203, a display control unit 204, and a vibration control unit 205 as execution units. Each execution part cooperates.

The touch detection unit 201 uses the touch pressure sensor 117 to perform touch detection processing. The touch detection unit 201 implements a well-known function of detecting touches at multiple locations within the display screen 2 . The touch detection unit 201 implements a known function of detecting operations such as tapping, swiping, flicking, and pinching. The pressure detection unit 202 uses the touch pressure sensor 117 to perform pressure detection processing. The pressure detection unit 202 detects whether or not a touch position is pressed and the strength of the pressure.

The tilt angle detection unit 203 uses the acceleration sensor 112 and the gyro sensor 113 to detect the tilt angle of the mobile terminal device. The display control unit 204 performs processing for controlling display contents of the display screen 2 according to an input operation on the display screen 2 of the display unit 121 . This processing includes control processing such as scroll display operation. The vibration control unit 205 uses the vibration generation unit 107 to perform processing for generating vibration in the mobile terminal device.

Note that the OS of the mobile terminal device realized by the basic operation program 103a includes a known graphical user interface controller. The graphical user interface controller realizes a function of obtaining input information through a touch input operation on the display screen 2 and a function of controlling output to the display screen 2 based on control processing according to the input information.

[Appearance and content display]
FIG. 4 shows an example of the appearance of the mobile terminal device and content display on the application screen. The left side of FIG. 4 shows the configuration of the front face of the housing 1 having the display screen 2, and the right side shows the configuration of the rear side. A generally rectangular display screen 2 is provided on the surface of a generally flat plate-shaped housing 1 . In the display screen 2, as content display information 401, in this example, a partial area of a web page on an application screen by a web browser is displayed. It should be noted that texts, images, etc. in Web pages are simply illustrated with symbols such as ◯, ×, Δ, and □. Objects such as links may be included in the content. In this example, a case where a link 7 such as a URL is included between an area indicated by x and an area indicated by Δ is simply illustrated. The display screen 2 also includes an area 402 for displaying information such as a clock and an address.

The housing 1 includes a front camera unit 423 corresponding to the first video input unit 123, a rear camera unit 424 corresponding to the second video input unit 124, a speaker 431 of the audio output unit 131, and a microphone of the audio input unit 133. 433, etc. are provided.

The housing 1 has a power key k1 and a home key k2 as operation keys. The power key k1 enables input operations for turning on/off the power of the portable terminal device and switching to/returning to the standby state. The power is turned on/off by pressing the power key k1 for a predetermined time or longer. Shifting to or returning from the standby state is performed by pressing the power key k1 for a period of time shorter than a predetermined period of time. The home key k2 enables input operations related to display of a home screen, which is a basic operation screen to be described later. By pressing the home key k2 while the application screen is displayed, the display is switched to the home screen.

The user performs an input operation of touching an object such as a link 7 of content in the application screen or an icon in the home screen on the display screen 2 . Thereby, the portable terminal device reads and displays the content associated with the link 7, for example. The mobile terminal device, for example, executes an application associated with an icon and displays an application screen.

[Touch press detection]
FIG. 5 shows detection of touch position coordinates and pressure using the touch pressure sensor 117 . It has an area 500 corresponding to the display screen 2 and the touch pressure sensor 117 . A region 500 is a region where touch and pressure states can be detected. In the region 500, it has position coordinates (X, Y) in the X-direction and Y-direction planes. The position of the point touched or pressed by the finger in the area 500 is shown as position coordinates (X1, Y1). Let the origin of the area 500 be the upper left position coordinates (0, 0), the horizontal width of the area 500 be Xm, and the vertical width be Ym.

The touch detection unit 201 uses the touch pressure sensor 117 to detect the position coordinates (X1, Y1) of the touched point in the area 500 . The pressure detection unit 202 uses the touch pressure sensor 117 to detect the strength of the pressure at the point pressed by the touch. Let Pn be the strength of the pressure. Also, the touch detection unit 201 can detect the number of touches and the coordinates of each touch position when a plurality of fingers touch the area 500 at the same time using the touch pressure sensor 117 .

Note that the methods of touch detection and press detection are not particularly limited, and known methods can be applied. As an example, a capacitive touch pressure detection method can be applied. In this method, changes in capacitance caused by proximity or pressing of a finger on the display screen are detected as voltage values, and touch position coordinates and pressure strength are obtained by calculation based on the voltage values.

[Usage status, tilt angle, operation]
FIG. 6 shows a state in which the user holds and uses the mobile terminal device, the tilt angle of the mobile terminal device, the tilting operation, etc., as viewed from the side of the user and the housing 1 . In this state, the planes corresponding to the housing 1 and the display screen 2 are tilted with respect to the horizontal and vertical planes. In this tilted state, the horizontal direction has an absolute tilt angle θ with respect to the horizontal plane. The mobile terminal device of Embodiment 1 detects this angle θ and sets it as the reference angle θ0. The user performs an operation of tilting the housing 1 for scrolling or the like from the state of the reference angle θ0.

FIG. 7 shows the tilting operation and the like corresponding to FIG. 6 with the front of the display screen 2 viewed from the user's line of sight. In the example of FIG. 7, a point near the center of the display screen 2 in the X and Y directions is touched. It is also assumed that this point is a reference point for holding the portable terminal device by hand. The axis of rotation during the tilting operation is the axis in the X direction, indicated by line 701 .

In FIGS. 6 and 7, let θn be the absolute tilt angle when further tilting operation is performed with respect to the reference angle θ0. The angle θn is the angle of inclination of the display screen 2 and the contents in the Y direction in this example. As an amount representing the angle of the relative inclination, there is a difference value (θn−θ0) between the reference angle θ0 and the angle θn. In addition, the positive direction and the negative direction are shown with respect to the tilting operation and the tilting angle θn. The positive direction is the direction in which the upper side of the display screen 2 is tilted forward as viewed from the user when the reference point of support is fixed, and the negative direction is the direction in which the upper side of the display screen 2 is tilted backward when viewed from the user. the direction of the case.

[Display range change control, scroll display]
FIG. 8 shows a content scroll display operation as display range change control in the portable terminal device of the first embodiment. An application screen within the display screen 2 includes an area 801 in which content 800 can be displayed. A part of the display information 3 of the content 800 is displayed as the display range 4 in the area 801 . A content 800 is an example of a web page, and actual data is composed of HTML or the like. Display information 3 of content 800 shows a case where links 7 are included between areas such as text and images. The display information 3 of the content 800 is changed according to the size of the area 801 by the application.

The size of the entire display information 3 of the content 800 , that is, the standard size without scaling or the like is large relative to the size of the area 801 . Therefore, the entire display information 3 cannot be displayed in the area 801 . Therefore, part of the display information 3 of the content 800 is displayed as the display range 4 in the area 801 . A display range 4 is a range when the display information 3 of the content 800 is displayed in the area 801 of the display screen 2 . In this example, the display range 4 indicates the case where the area is in the middle of the Web page, and includes part of the area indicated by x, link 7, and part of the area indicated by Δ.

When the user wants to view another part of the content 800 that is not displayed from the state of the display range 4 displayed in the area 801, conventionally, the user scrolls by swiping, flicking, or the like. This example shows a case where the display information 3 can be scrolled upward or downward in the Y direction. Conventionally, when viewing large-sized content 800, it is necessary to repeat an operation such as swiping many times, which is troublesome.

On the other hand, in Embodiment 1, the display range 4 in the area 801 can be scrolled by the operation of pressing the area 801 of the display screen 2 and tilting the housing 1 by the user. Thereby, the display range 4 of the display information 3 of the content 800 can be changed. Scroll 5 is the first direction scroll, and indicates scrolling to the top or relatively upward within the content 800 . In scroll 5, the display range 4 is moved upward, and a relatively upward part of the content 800 is displayed in the area 801. FIG. Scrolling 6 is the second direction scrolling and indicates scrolling to the end or relatively downward within the content 800 . In scroll 6, the display range 4 is moved downward, and a relatively downward part of the content 800 is displayed in the area 801. FIG.

[Display control]
Display control in the mobile terminal device according to the first embodiment will be described below. When displaying content on the application screen of the display screen 2, the display control unit 204 of the mobile terminal device receives a specific touch pressing operation and an operation of tilting the housing 1 by the user, and scrolls the display range 4. Perform range change control.

Assume that the user is initially in a hand-held state as shown in FIG. 6 and is viewing a portion of the content 800 as the display range 4 as shown in FIG. When the user wants to view another part of the content 800 from that state, first, the user touches and presses the area 801 of the display screen 2 with a finger. At this time, the user presses with a certain amount of strength. The mobile terminal device shifts to a specific control mode when the strength of the pressure is greater than or equal to a predetermined magnitude. The mobile terminal device detects the angle θ in FIG. 6 corresponding to the state at that time, and sets it as the reference angle θ0. The reference angle θ0 is an angle temporarily set for control.

The user performs an operation of tilting the housing 1 in a desired direction while keeping such touch and pressure. For example, when the user wants to scroll 5 upward, the user performs an operation of tilting in the negative direction. The mobile terminal device detects the angle θn according to the tilting operation, and detects the difference value (θn−θ0) that is the amount of the relative tilt angle. Using the magnitude of the angle θn, specifically the difference value (θn−θ0), the portable terminal device determines whether or not to scroll, the direction and speed of the scroll, and the like. The mobile terminal device controls scrolling differently depending on the direction and magnitude of the angle θn. This scroll display operation changes the display range 4 in the area 801 of the display screen 2 .

When the desired display range 4 is displayed in the area 801 by scrolling, the user releases the finger. As a result, the mobile terminal device stops scrolling at that point. That is, the display range 4 at that time is displayed in the area 801 . The user can browse another part of the content 800 corresponding to the display range 4 . Also, if the position where the scrolling is stopped and the finger is lifted corresponds to an object such as the link 7, the portable terminal device performs processing for executing the object, for example, processing for reading and displaying the content of the link 7.

[Control flow]
FIG. 9 shows a flow of control processing for implementing display range change control according to the first embodiment. The basic operation execution unit 104a, particularly the display control unit 204, executes the processing of the flow in FIG. Modes that are control states for realizing this flow include a first mode, a second mode, and a third mode. Assume that the administrative values of each mode are 0, 1, and 2. Mode=0 (first mode) indicates the initial state. Mode=1 (second mode) is a touched state and indicates a state in which the reference angle θ0 is not set. Mode=2 (third mode) is a state in which a predetermined pressure is applied, and indicates a state in which the reference angle θ0 is set. FIG. 9 has steps S101 to S123. The steps will be described below.

(S101) The display control unit 204 reads the content selected by the user. The display control unit 204 first sets the mode to mode=0 (first mode).

(S102) The display control unit 204 first displays the beginning of the content, for example, the area 821 in FIG. Note that such a display position is determined according to the application or content.

(S103) The mobile terminal device receives input operations by the user through the operation unit 106 and the touch pressure sensor 117, and acquires input information corresponding to the input operations. The display control unit 204 acquires touch input information through the touch detection unit 201 . At that time, the touch detection unit 201 detects presence/absence of touch and touch position coordinates (X1, Y1). Further, the pressure detection unit 202 detects the presence or absence of pressure and the strength of pressure Pn.

(S104) Based on the input information, the display control unit 204 branches the processing by determining whether or not there is a touch. If there is a touch (Y), proceed to S105, and if there is no touch (N), proceed to S120.

(S105) The display control unit 204 acquires the touch position coordinates (X1, Y1) from the touch detection unit 201. FIG.

(S106) Further, the display control unit 204 acquires the strength of pressure Pn at the touch position from the pressure detection unit 202 .

(S107) The display control unit 204 compares the pressure strength Pn acquired in S106 with a predetermined threshold value Pt, determines whether the strength Pn is equal to or greater than the threshold value Pt, and branches the process. If Pn≧Pt, proceed to S110, and if Pn<Pt, proceed to S108.

(S108) The display control unit 204 stores and holds the touch position coordinates (X1, Y1) acquired in S105 in the memory.

(S109) The display control unit 204 sets the mode to mode=1 (second mode), and returns to S103.

(S110) The display control unit 204 acquires the inclination angle θn of the mobile terminal device by the inclination angle detection unit 203 .

(S111) The display control unit 204 checks whether the current mode is mode=2 (third mode), and branches. If mode=2 (third mode), proceed to S115; otherwise, proceed to S112.

(S112) The display control unit 204 sets the angle θn acquired in S110 as the reference angle θ0.

(S113) The display control unit 204 stores and holds the reference angle θ0 in the memory.

(S114) The display control unit 204 sets the mode to mode=2 (third mode), and returns to S103.

(S115) On the other hand, in the case of mode=2 (third mode), in S115, the display control unit 204 compares the absolute value |θn−θ0| of the difference between the angle θn and the reference angle θ0 with a predetermined threshold value θt. Then, it is determined whether or not it is equal to or greater than the threshold value θt, and branching is performed. If |θn−θ0|≥θt, the process proceeds to S116, and if not, the process returns to S103. Note that when the difference value is 0 or almost 0, it means that there is no change from the state of the reference angle θ0. Therefore, by setting the threshold value θt, it is possible to prevent scrolling when the tilt angle slightly changes unintentionally by the user.

(S116) The display control unit 204 sets the scroll speed Sn to be used for the scroll display operation according to the following formula (1), using the pressure strength Pn and the like acquired in S106.
Sn=S0×Pn/Pt (1)

Let S0 be a predetermined reference scroll speed. The reference scroll speed S0 may be a fixed setting value for implementation, or may be a setting value that can be variably set by the user. In the case of formula (1), the scroll speed Sn is determined by multiplying the reference scroll speed S0 according to the magnitude of the pressing force Pn with respect to the threshold value Pt (Pn/Pt). That is, the stronger the user's pressure, the higher the scroll speed Sn can be.

(S117) Next, the display control unit 204 determines whether the sign of the difference value (θn−θ0) between the angle θn and the reference angle θ0 is positive or negative, and branches. If positive ((θn-θ0)>0), proceed to S118; if negative ((θn-θ0)<0), proceed to S119.

(S118) The display control unit 204 uses the scroll speed Sn set in S116 to perform downward scroll processing for causing scroll 6 in FIG. 8 to correspond to the tilt in the positive direction, and then returns to S103.

(S119) The display control unit 204 uses the scroll speed Sn set in S116 to perform upward scroll processing for causing scroll 5 in FIG.

(S120) On the other hand, if there is no touch in S104, in S120 the display control unit 204 checks whether the current mode is mode=1 (second mode) and branches. If mode=1 (second mode), proceed to S121; otherwise, proceed to S123.

(S121) The display control unit 204 stores the touch position coordinates (X1, Y1) stored in S108 as the touch position on the display screen 2, and the position of the object such as the link 7 in the display information 3 on the display screen 2. compare. The display control unit 204 branches depending on whether those positions match. If they match, the process proceeds to S122, and if they do not match, the process proceeds to S123.

(S122) The display control unit 204 executes processing associated with the link 7. FIG. For example, the display control unit 204 acquires the content specified by the URL of the link 7 from a server on the Internet, reads it, and displays it on the display screen 2 . In this case, the portable terminal device exits the loop of this flow as indicated by A1, and similarly processes new content from the beginning of this flow.

(S123) The display control unit 204 sets the mode to mode=0 (first mode), and returns to S103.

[Scroll speed setting]
FIG. 10 shows the relationship between the pressing strength Pn and the scroll speed Sn, which corresponds to step S116 in FIG. 9 and relates to the setting of the scroll speed Sn. The horizontal axis represents the strength of pressure Pn, and indicates, for example, the values of threshold values Pt, 2×Pt, and 3×Pt. The vertical axis is the scroll speed Sn, which indicates values of the reference scroll speed S0, 2*S0, and 3*S0, for example. A straight line 1001 indicates a function corresponding to the formula (1), and the scroll speed Sn increases linearly according to the strength Pn.

[Effects, etc.]
As described above, according to the mobile terminal device of Embodiment 1, it is possible to change the display range of content or the like in response to various conditions of the user with little effort, and to achieve more favorable usability. The mobile terminal device changes the content display range 4 by scroll display control using the pressure strength Pn and the relative tilt angle θn. The user holds the housing 1 of the portable terminal device in a hand-held state suitable for him/herself and the situation, for example, a state in which he/she naturally holds it with one hand. The user can set that state as the reference angle θ0 by pressing at a desired time. Then, the user can change the display range 4 by scrolling the display information of the content by tilting the housing 1 in the desired direction. The user can browse the desired display range 4 quickly with a simple operation without having to repeat the touch operation many times. The user can move a desired distance by scrolling with one operation.

Since the control mode is entered and the reference angle .theta.0 is set by using a predetermined press as a trigger, scrolling by mistake will not occur even if the user unintentionally touches the screen. In addition, the user can adjust the scroll speed or the like to his liking according to the strength of the pressing force or the like. In addition, the user can quickly execute a link or the like in conjunction with a scroll operation without requiring a separate touch operation.

[Modification (1)]
As modifications of the first embodiment, the following is possible. Contents to be subjected to display range change control are not limited to web pages and the like, and various types of photographic images and the like can be applied. For example, when the size of the photographic image is large or when the photographic image is enlarged, a part of the photographic image is displayed on the display screen 2 . At that time, the scroll control and the like in the first embodiment can be similarly applied. In addition, the display range change control is not limited to the scroll display operation, and may be an enlargement/reduction operation or the like. For example, the portable terminal device displays a photographic image, and when the user tilts the display screen 2 while pressing it, the display size of the photographic image is enlarged or reduced according to the tilt angle. Thereby, the user can browse a desired part or the whole of the photographic image.

[Modification (2)]
In the first embodiment, as shown in FIG. 1, etc., the case of controlling the scroll display operation in the Y direction using the tilt angle of the display screen 2 and the content in the Y direction was shown, but the present invention is not limited to this. . It is also possible to control the scroll display operation in the X direction using the tilt angle of the display screen 2 and the contents in the X direction. Further, it is possible to control the scroll display operation in all directions including up, down, left, and right by performing both the Y-direction control and the X-direction control at the same time. Such control in each direction may be a fixed application for implementation, a selectable application according to user settings, or an application selected according to an application, content, or the like. For example, in the case of an application that displays content that has a relatively large size and can be enlarged or reduced, such as a photograph or a map, the omnidirectional control may be applied.

In the first embodiment, the correspondence between controls is downward scrolling 6 for a positive tilt and upward scrolling 5 for a negative tilt, but the reverse correspondence may be used.

The scroll display operation of Embodiment 1 is an operation of continuously changing the display range 4, for example, an operation of smoothly moving in units of pixels, but the present invention is not limited to this. For example, an operation of intermittently scrolling for each fixed area or distance is also applicable.

[Modification (3)]
In step S116 of FIG. 9, it is determined that the scroll speed Sn is changed according to the pressing force Pn, but this is not the only option. The scroll speed Sn may be determined according to the magnitude of the angle θn using the following equation (2).
Sn=S0×|θn−θ0|/θt (2)

In the case of the formula (2), the scroll speed Sn is determined so as to increase the reference scroll speed S0 according to the magnitude of the absolute value |θn−θ0| with respect to the threshold value θt. In the case of this modified example, the relationship for setting the scroll speed Sn is that shown in FIG. 10, in which the pressing force Pn is replaced by the absolute value |θn−θ0| of the difference value with respect to the tilt angle θn.

[Modification (4)]
In step S116 of FIG. 9 and FIG. 10, the scroll speed Sn is determined by a linear function such as the straight line 1001, but it is possible without being limited to this. For example, like function 1002 in FIG. 10, it may be determined by a stepwise function. In this function 1002, the scroll speed Sn is determined to be a constant value according to the division of the pressure strength Pn. Further, when determining the scroll speed Sn, a function including a predetermined upper limit value and a lower limit value may be applied, and the scroll speed Sn may be determined within the range from the lower limit value to the upper limit value. Also, a non-linear function may be applied instead of the linear function.

Also, the scroll speed Sn may be set to a constant value regardless of the pressing force Pn or the angle θn. Further, the scroll speed Sn may be settable by user setting. As the user setting means, for example, a user setting screen or the like may be displayed on the display screen 2 and an item for setting the scroll speed Sn or the like may be provided.

The threshold value Pt for the pressing force Pn in step S107 of FIG. 9 or the threshold value θt for the angle θn in step S115 may be a fixed set value for implementation, or a set value that can be variably set by the user. good too. In the case of a form that allows user settings, the user can make suitable settings that are easy for him/herself to operate.

[Modification (5)]
At the time when the reference angle θ0 is set by pressing of a predetermined magnitude or more and the control mode is shifted to a specific control mode, predetermined information representing the state of the control mode may be displayed within the display screen 2 . This is not limited to display, and may be predetermined audio output or vibration generation. Further, when the control mode is released by releasing the finger, the display of the predetermined information may be erased or other predetermined output may be performed.

Further, when shifting to the control mode by triggering a pressing force equal to or greater than a predetermined level, the touch duration may be further used as a condition for determination. In other words, when the touch duration time when the pressure is greater than or equal to a predetermined magnitude is greater than or equal to a predetermined threshold value, the transition to the control mode may be made.

(Embodiment 2)
A mobile terminal device according to a second embodiment of the present invention will be described with reference to FIGS. 11 to 18. FIG. The basic configuration of the second embodiment and the like is the same as that of the first embodiment, and the configuration parts of the second embodiment that are different from those of the first embodiment will be described below.

[Home Screen]
FIG. 11 shows the home screen of display screen 2 and switching between a plurality of home screens in the second embodiment. The mobile terminal device of Embodiment 2 switches and displays a plurality of home screens on the display screen 2 in accordance with a specific touch pressing operation. A plurality of home screens with different contents are provided as home screens. One home screen is basically displayed in the display screen 2 . One home screen selected from among the plurality of home screens corresponds to the display range 4 . On one home screen, icons 9 and the like associated with applications are arranged on the background. When the user selects the icon 9, the corresponding application screen is displayed.

In this example, home screens H1 to H5 are provided as a plurality of home screens. The home screens H1 to H5 are managed in a virtual layered arrangement as information by the OS of the mobile terminal device. That is, the home screens H1-H5 are managed as layers L1-L5. For example, the home screen H1 is the top layer L1 and is arranged on the near side. The home screen H5 is the bottom layer L5 and is arranged on the back side. The number of home screens and layers is increased or decreased as needed. Note that the bottom layer may be connected to the top layer in a loop.

The home screens H1 to H5 are divided by genre, for example. For example, on the home screen H1, three icons 9 corresponding to communication-related genre applications such as e-mail, SNS, and chat are arranged at the bottom. For example, on the home screen H2, icons of genres such as games are arranged. A plurality of home screens can also be set by the user. Also, when a plurality of icons cannot fit on one home screen, the home screen may be automatically divided into a plurality of home screens.

[Display control]
FIG. 12 shows a touch pressing operation on the home screen and a screen switching display operation as display control according to the second embodiment. The mobile terminal device according to the second embodiment receives a specific touch pressing operation by the user, and controls screen switching between a plurality of home screens on the display screen 2 as display range change control. In the first embodiment, the target of the display range change control is the content display information, but in the second embodiment, it is a plurality of home screens.

Embodiment 1 and the like show the case where the user can operate the mobile terminal device with one hand. On the other hand, Embodiment 2 shows a case where the user operates the mobile terminal device with both hands. It is assumed that the user holds the mobile terminal device with the left hand (not shown) as in FIG. Then, as shown in FIG. 12, the user touches and presses a location within the display screen 2 with the finger of the right hand. In Embodiment 2, one-finger and two-finger are selectively used as the touch pressing operation. The touch detection unit 201 and the pressure detection unit 202 use the touch pressure sensor 117 to distinguish and detect the touch pressure with one finger and the touch pressure with two fingers on the display screen 2 . That is, a state in which a pressure of a predetermined magnitude or more is present at one location within the display screen 2 and a state in which two locations within the display screen 2 are simultaneously pressed to a predetermined magnitude or greater are detected.

The display control unit 204 applies two types of screen switching operations according to the proper use of the two types of touch pressing operations. As shown in FIG. 12, the display control unit 204 controls the first direction and the second direction as screen switching directions. As a correspondence relationship, in the case of pressing with one finger, the screen is switched in the first direction, for example, the layer descending direction, and in the case of pressing with two fingers, the screen is switched in the second direction, such as the layer ascending direction. and

As shown in the upper part of FIG. 12, the display control unit 204 displays a plurality of home screens in the layer descending direction, which is the first direction, while a single-finger press of a predetermined magnitude or more is detected. , sequentially. That is, one home screen displayed as the display range 4 on the display screen 2 is sequentially switched from the front top layer L1 to the back bottom layer L5 while the button is held.

As shown in the lower part of FIG. 12 , the display control unit 204 displays a plurality of home screens in the layer ascending direction, which is the second direction, while a pressure of two fingers or more is detected. and switch in order. That is, one home screen displayed as the display range 4 on the display screen 2 is switched sequentially from the bottom layer L5 at the back to the top layer L1 at the front while the pressing is held.

Further, when the screen is switched to the desired home screen by the screen switching, the user releases the finger from the display screen 2 to bring it into a non-pressing state. At that point, the display control unit 204 stops screen switching.

[Control flow (1)]
FIG. 13 shows a flow of control processing by the display control unit 204 of the mobile terminal device according to the second embodiment. FIG. 13 has steps S201 to S217. The steps will be described below. Embodiment 2 has a first mode, a second mode, a third mode, and a fourth mode as modes. It should be noted that modes are independent in each embodiment and have different meanings.

(S201) The display control unit 204 sets the mode to mode=0 (first mode).

(S202) Let the layer of one home screen displayed on the display screen 2 be a layer Ln. The display control unit 204 first sets the layer Ln to the top layer L1.

(S203) The display control unit 204 displays on the display screen 2 the home screen corresponding to the set layer Ln. First, the home screen H1 corresponding to the layer L1 is displayed.

( S<b>204 ) The display control unit 204 receives a touch press operation through the operation unit 106 and the touch press sensor 117 .

(S205) The display control unit 204 branches depending on whether or not there is a touch. If there is a touch, proceed to S206; if there is no touch, proceed to S214.

(S206) The display control unit 204 acquires touch input information including the touch position coordinates (X1, Y1) detected by the touch detection unit 201. FIG. This touch input information includes information for distinguishing between one-finger and two-finger touches.

(S207) The display control unit 204 acquires the pressure intensity Pn detected by the pressure detection unit 202. FIG.

(S208) The display control unit 204 determines whether or not the pressure strength Pn is greater than or equal to the threshold value Pt, and branches. If Pn≧Pt, proceed to S211, and if Pn<Pt, proceed to S209.

(S209) The display control unit 204 stores and holds the touch position coordinates (X1, Y1) in the memory.

(S210) The display control unit 204 sets the mode to mode=1 (second mode), and returns to S203.

(S211) On the other hand, in S211, based on the touch input information acquired in S206, the display control unit 204 determines whether there are one or two touch points and the number of touch points, and branches. If there is one touch, the process proceeds to S212, and if there are two touches, the process proceeds to S213.

(S212) The display control unit 204 performs layer descending processing as first direction screen switching corresponding to a single touch. The display control unit 204 updates the setting of the layer Ln as necessary, and returns to S203.

(S213) The display control unit 204 performs a layer ascending process as second direction screen switching corresponding to two touches. The display control unit 204 updates the setting of the layer Ln as necessary, and returns to S203.

(S214) On the other hand, if there is no touch in S205, in S214 the display control unit 204 checks whether the mode is mode=1 (second mode), and branches. If mode=1 (second mode), proceed to S215; otherwise, proceed to S217.

(S215) The display control unit 204 determines whether the touch position coordinates (X1, Y1) stored in S209 match the position of the icon on the home screen displayed on the display screen 2, and branches. conduct. If the touch position corresponds to the icon position, the process proceeds to S216; otherwise, the process proceeds to S217.

(S216) The display control unit 204 executes the application associated with the corresponding icon position. Then, as in A2, the loop of this flow is exited, and transition is made to the processing of the application screen of the application to be executed.

(S217) The display control unit 204 sets the mode to mode=0 (first mode), and returns to S203.

[Control flow (2)]
FIG. 14 shows details of the layer descending process in step S212 of FIG. This process has steps S221 to S229. Control has mode=2 (third mode). The third mode represents layer descent processing.

(S221) The display control unit 204 checks whether the current mode is mode=2 (third mode), and branches. If mode=2 (third mode), proceed to S224; otherwise, proceed to S222.

(S222) The display control unit 204 sets the mode to mode=2 (third mode).

(S223) The display control unit 204 starts a timer to measure time. Let Tn be the value of the time measured by the timer. Then, the layer descending process of S212 ends. This value Tn corresponds to the time during which the display screen 2 is kept pressed by the user.

(S224) The display control unit 204 determines whether or not the timer value Tn is equal to or greater than the predetermined time threshold value T0, and branches. If the value Tn is equal to or greater than the threshold value T0, the process proceeds to S225, and if not, the layer descending process of S212 ends.

(S225) The display control unit 204 determines whether or not the layer Ln of the home screen displayed on the display screen 2 is the bottom layer (for example, layer L5), and branches. If it is the bottom layer, proceed to S226; otherwise, proceed to S227.

(S226) The display control unit 204 uses the vibration control unit 205 to generate a predetermined first vibration pattern. This informs the user that the currently displayed home screen has become the home screen H5 corresponding to the bottom layer L5. Then, the layer descending process of S212 ends.

(S227) The display control unit 204 increments the layer Ln displayed on the display screen 2 by 1 so as to lower it. For example, the layer Ln goes from the first layer L1 to the next layer L2.

(S228) The display control unit 204 uses the vibration control unit 205 to generate a predetermined second vibration pattern. This informs the user that the currently displayed home screen has become a home screen corresponding to a layer other than the bottom layer. For example, when switching to the bottom screen, the display control unit 204 generates vibration larger than the second vibration as the first vibration.

(S229) After that, the display control unit 204 restarts the timer and terminates the layer descending process of S212.

[Control flow (3)]
FIG. 15 shows details of the layer ascending process in step S213 of FIG. It has steps S231-239. This process is basically similar in concept to the layer descent process in FIG. Control has mode=3 (fourth mode). A fourth mode represents a layer ascending process.

In S231, the display control unit 204 checks whether the current mode is mode=3 (fourth mode), and branches. If mode=3 (fourth mode), proceed to S234; otherwise, proceed to S232. In S232, the display control unit 204 sets the mode to mode=3 (fourth mode). In S233, the display control unit 204 starts a timer to measure time, and ends the layer raising process in S213. In S234, the display control unit 204 determines whether or not the value Tn is equal to or greater than the threshold T0, and branches. If the value Tn is equal to or greater than the threshold value T0, the process proceeds to S235.

In S235, the display control unit 204 determines whether or not the layer Ln of the home screen currently displayed on the display screen 2 is the top layer L1, and branches. If it is the top layer L1, proceed to S236; otherwise, proceed to S237. In S236, the display control unit 204 uses the vibration control unit 205 to generate a predetermined first vibration pattern. This informs the user that the currently displayed home screen has become the home screen H1 corresponding to the top layer L1. Then, the layer ascending process of S213 ends.

In S237, the display control unit 204 decrements the layer Ln displayed on the display screen 2 by 1 so as to raise it. In S238, the display control unit 204 uses the vibration control unit 205 to generate a predetermined second vibration pattern. This informs the user that the currently displayed home screen has become a home screen corresponding to a layer other than the top layer. For example, when switching to the top screen, the display control unit 204 generates vibration larger than the second vibration as the first vibration. In S239, the display control unit 204 restarts the timer and ends the layer raising process in S213.

[Effects, etc.]
As described above, in the second embodiment, by pressing the display screen 2 with one finger or two fingers as shown in FIG. can do. When the user selects a desired home screen from a plurality of home screens, the user can easily switch between the home screens with a single operation without having to repeatedly perform operations such as swiping. In addition, since vibration occurs each time the screen is switched, the user can easily recognize the state of screen switching.

[Modification (1)]
As modifications of the second embodiment, the following is possible. Simultaneous touch detection at multiple locations with multiple fingers may be used instead of simultaneous touch detection at two locations with two fingers. As for the corresponding relationship of control, the layer may be raised in the case of one finger, and the layer may be lowered in the case of two fingers. In addition, the present invention is applicable not only to the layered arrangement of a plurality of screens but also to the parallel arrangement in the X direction or the Y direction. Alternatively, the step of generating vibration in FIGS. 14 and 15 may be omitted. One vibration pattern may be used without dividing into the first vibration pattern and the second vibration pattern. Moreover, it is not limited to the generation of vibration, and may be replaced by display of predetermined characters or images, output of predetermined sound, or the like.

[Modification (2)]
FIG. 16 shows the display state of the display screen 2 in the modified example. As shown in FIG. 16, there are cases where a plurality of screens are arranged and displayed in layers or in parallel within the display screen 2 . In that case, as a modified example, control similar to that of the second embodiment can be applied. For example, by pressing the home key k2 twice from the state of the normal home screen, the state transitions to the layered display state of a plurality of screens as shown on the left side of FIG. In this example, a case of layered arrangement of a plurality of application screens G1 to G4 is shown. In the state on the left side, the application screen G1 is displayed as the layer L1 in the foremost state. When pressed from this state with, for example, one finger, the layer is lowered to switch to the layer display state on the right side of FIG. 16 . In this state, the application screen G2 is displayed as the layer L1 in the foremost state.

[Modification (3)]
The information subject to display range change control is not limited to a plurality of home screens, and can be similarly applied to a plurality of application screens and the like.

FIG. 17 shows a case where content history information within an application screen is targeted for change control. History screens E1 to E3, etc., which have content history information in chronological order and correspond to browsing history information of Web pages, for example, are shown. For example, the display range 4 is the latest history screen E1. The history screens E1 to E3, etc. can be changed from the present to the past by the operation of pressing to change the inclination in the Y direction as in the first embodiment, or the operation of pressing with one or two fingers as in the second embodiment. Alternatively, the display is switched from the past to the present direction.

FIG. 18 shows a case where content within an application screen, for example, a plurality of page information constituting an electronic book, is subject to change control. As a plurality of page information, for example, page screens p1 to p3 corresponding to each page are shown. For example, the display range 4 is the first page screen p1. Similarly, the page screens p1 to p3 can be switched and displayed in a desired direction by an operation of pressing to change the tilt in the X direction, an operation of pressing with one finger or two fingers, or the like.

(Embodiment 3)
A mobile terminal device according to a third embodiment of the present invention will be described with reference to FIGS. 19 to 22. FIG. The components of the third embodiment that are different from those of the first embodiment and the like will be described below. Embodiment 3 shows a case of controlling switching between a plurality of home screens as in Embodiment 2. FIG.

[Display control]
FIG. 19 shows display control according to the third embodiment. The user selectively uses two types of touch pressing operations. The mobile terminal device divides the display screen 2, that is, the area of the home screen into two types of areas, an upper area R1 and a lower area R2. The two types of touch pressing operations include a first operation of pressing a location within the upper region R1 and a second operation of pressing a location within the lower region R2. As shown in the upper part of FIG. 19, when the first operation is performed, the mobile terminal device switches screens in the first direction in the same manner as the operation in the upper part of FIG. 12 of the second embodiment. As shown in the lower part of FIG. 19 , when the second operation is performed, the mobile terminal device switches screens in the second direction in the same manner as the operation in the lower part of FIG. 12 . A boundary line 190 indicated by a dashed dotted line is a boundary line between the upper region R1 and the lower region R2 and is not displayed within the display screen 2 .

[Control flow (1)]
FIG. 20 shows a flow of control processing of the display control unit 204 according to the third embodiment. It has steps S301 to S317. 20, the main difference from the flow of FIG. 13 of the second embodiment is steps S311 to S313. In S308, if the pressing force Pn is greater than or equal to the threshold value Pt, the process proceeds to S311. In terms of control, it has first to fourth modes.

(S311) The display control unit 204 determines whether the touch press position indicated by the touch position coordinates (X1, Y1) acquired in S306 is within the upper region R1 or the lower region R2. For example, the display control unit 204 determines that it is within the upper region R1 if the value Y1 is smaller than the value (Ym/2) that is half the vertical width Ym, and that it is within the lower region R2 if it is greater than the value. . The display control unit 204 branches according to the distinction between these two types of regions. In the case of the upper region R1, the process proceeds to S312, and in the case of the lower region R2, the process proceeds to S313.

(S312) The display control unit 204 performs layer descending processing as first direction screen switching corresponding to the upper region R1, updates the setting of the layer Ln as necessary, and returns to S303.

(S313) The display control unit 204 performs layer ascending processing as second direction screen switching corresponding to the lower region R2, updates the setting of the layer Ln as necessary, and returns to S303.

[Control flow (2)]
Detailed processing of S312 and S313 in FIG. 20 is as follows. This processing is basically the same as in FIGS. 14 and 15, and the different parts are described below. In S224 of FIG. 14 and S234 of FIG. 15, it is determined whether the time value Tn of the timer is equal to or greater than the threshold value T0 in the case of the third mode or the fourth mode. In the third embodiment, instead of S224 in FIG. 14 and S234 in FIG. 15, the following processing is performed.

The display control unit 204 first determines the time interval Kn for updating the layer Ln in the screen switching display operation based on the following equation (3).
Kn=K0×Pt/Pn (3)

Let Kn be the time interval to be obtained in the equation (3). Let K0 be a predetermined time interval that serves as a reference. The display control unit 204 uses the pressure strength Pn and the pressure threshold Pt. Note that specific values such as Pt differ from embodiment to embodiment. In the formula (3), the time interval Kn is calculated by decreasing the time interval K0 according to the magnitude of the threshold value Pt (Pt/Pn) with respect to the pressing force Pn. That is, the time interval Kn is determined to be shorter as the pressing force Pn is greater. The display control unit 204 uses the time interval Kn as the threshold value T0 for the time value Tn of the timer.

Next, the display control unit 204 compares the time value Tn of the timer with the time interval Kn, which is the threshold value T0, and branches. If the value Tn is equal to or greater than the time interval Kn, the process proceeds to S225 or S235; otherwise, the process ends.

As described above, in the third embodiment, the time interval for updating layers at the time of screen switching is variably set according to the pressing strength Pn.

[Set time interval]
FIG. 21 shows the relationship between the pressure intensity Pn and the time interval Kn regarding the setting of the time interval Kn. In Embodiment 3, time interval Kn is determined by curve 2101 according to equation (3). Curve 2101 is a non-linear function, and as Pn is made larger than Pt, Kn decreases sharply at first and then gradually decreases Kn.

As a modification, a stepwise relationship may be applied as in the function 2102, or a linear function may be applied. In function 2102, the time interval Kn is determined as a constant value for each range of Pn. An upper limit value and a lower limit value may be defined for the time interval Kn. The time interval Kn may be a constant value independent of the pressing force Pn, or may be a user set value.

[One-handed operation]
FIG. 22 shows operations corresponding to left and right hands according to the third embodiment. (a) shows the first operation of pressing the upper region R1 with the left hand. (b) shows the second operation of pressing the lower region R2 with the left hand. (c) shows the first operation of pressing the upper region R1 with the right hand. (d) shows a second operation of pressing the lower region R2 with the right hand. Embodiment 3 thus has a function capable of coping with both one-handed operation such as operation with only the left hand and operation with only the right hand. Either one-handed operation is selectable by the user. It should be noted that the first embodiment and the like also have a function capable of supporting both one-handed operations. In Embodiment 2, both hands and two fingers are used.

[Effects, etc.]
As described above, in Embodiment 3, the user can switch between and display a plurality of home screens by pressing the upper region R1 or the lower region R2 of the display screen 2 . Accordingly, similarly to the second embodiment, it is possible to easily switch to a desired home screen without performing touch input operations many times.

[Modification]
The following are possible as modifications of the third embodiment. As for the corresponding relationship of control, the layer may be raised in the case of the upper region R1 and the layer may be lowered in the case of the lower region R2.

The positions of the two types of regions, the upper region R1 and the lower region R2, and the position of the boundary line 190 may be fixed set values for implementation or variable set values that can be set by the user. In the case of user setting, it is possible to set a suitable area that is easy for the user to operate according to the size of the user's fingers. As the user setting means, for example, a boundary line between the upper region R1 and the lower region R2 is displayed on the user setting screen, and the boundary line is moved according to the user input operation to set the position desired by the user. good too. Alternatively, the user is asked to touch and press two desired locations on the user setting screen. The mobile terminal device acquires information such as their positions and pressures, and sets a boundary line between the two types of regions between those positions. User settings may be similarly enabled for operations in other embodiments.

Also, the present invention is not limited to the above two types of regions, and can be applied. For example, the inside of the display screen 2 may be divided into two types of areas, a left area and a right area. In this case, there is a first operation of pressing the left area and a second operation of pressing the right area. The screen switching direction or the like is changed according to the first operation and the second operation. For example, assume that a plurality of application screens, a plurality of icons, etc. are arranged in parallel in the X direction. In the case of the first operation, the screen is switched or scrolled to the left, and in the case of the second operation, the screen is switched or scrolled to the right. Also, two types of regions with arbitrary sizes may be set at arbitrary positions in the display screen 2 .
(Embodiment 4)

A mobile terminal device according to a fourth embodiment of the present invention will be described with reference to FIGS. 23 to 25. FIG. Hereinafter, configuration parts in the fourth embodiment that are different from those in the first embodiment and the like will be described. In the fourth embodiment, a plurality of icons displayed in the home screen are targeted for display range change control, and arrangement change control of the plurality of icons is performed.

[Control outline and icon layout]
FIG. 23 shows a display example of the arrangement of a plurality of icons on the home screen as an overview of display control in the fourth embodiment. It should be noted that the case in which the user operates with the thumb while holding the housing 1 with the left hand is shown.

FIG. 23(a) shows the first arrangement state. In the area where the home screen is displayed on the display screen 2, a plurality of icons 9 are arranged in a matrix in parallel in the X direction and the Y direction. This example shows a case where eight icons 9 associated with eight applications are arranged in an area near the lower side. Eight icons 9 are indicated by "App1" to "App8" for identification.

FIG. 23(b) shows the second arrangement state. In the second arrangement state, the plurality of icons 9 are arranged in a circular, ring shape, and move in the ring so as to rotate on the circumference of the circle. As for the movement of the group of icons 9, they are moved at predetermined time intervals in the same manner as in the second embodiment. In the fourth embodiment, rings are arranged with a predetermined position in the display screen 2 as the center point Q0.

In the fourth embodiment, a pressing operation of pressing a portion within the display screen 2 with a predetermined size or more is accepted. The pressed position is an arbitrary position within the display screen 2 . The pressing position may be a position on the icon 9 in particular, or may be a position in an area other than the icon 9 . The mobile terminal device performs control to change the display state of the home screen, that is, the icon arrangement, in accordance with a predetermined pressing operation. As the change control, the mobile terminal device transitions from the first placement state to the second placement state. Then, in the second arrangement state, the portable terminal device rotates and moves the plurality of icons of the ring in a predetermined direction while the pressure is being held.

In addition, the portable terminal device stops rotation of the icons in response to a predetermined operation, that is, an operation in which the finger is released to release the pressure, and automatically selects and executes the icon corresponding to the released position. The user may shift the position while maintaining a predetermined amount of pressure or more from the first pressed position. For example, the user moves the finger to the position of the desired icon and releases the finger at that position. Accordingly, the mobile terminal device selects the icon at that position. Alternatively, the user moves the finger to a position where there is no icon and releases the finger at that position. As a result, the mobile terminal device returns to the first arrangement state without selecting the icon.

[Control flow (1)]
FIG. 24 shows the flow of control processing of the display control unit 204 according to the fourth embodiment. It has steps S401 to S415. In terms of control, it has first to third modes. It has S410 and S415 as mainly characteristic processing parts.

(S401) The display control unit 204 sets the mode to mode=0 (first mode).

(S402) The display control unit 204 displays the home screen on the display screen 2 in the first layout state as shown in FIG. 23(a).

(S403) The display control unit 204 accepts a user input operation.

(S404) The display control unit 204 branches depending on whether or not there is a touch. If there is a touch, proceed to S405; if there is no touch, proceed to S411.

(S405) The display control unit 204 acquires touch position coordinates (X1, Y1).

(S406) The display control unit 204 acquires the pressure strength Pn.

(S407) The display control unit 204 determines whether or not the pressure strength Pn is greater than or equal to the threshold value Pt, and branches. If Pn≧Pt, proceed to S410, and if Pn<Pt, proceed to S408.

(S408) The display control unit 204 stores and holds the touch position coordinates (X1, Y1) in the memory.

(S409) The display control unit 204 sets the mode to mode=1 (second mode), and returns to S403.

(S410) The display control unit 204 performs icon arrangement change processing. That is, the display control unit 204 causes the icon arrangement state of the display screen 2 to transition from the first arrangement state to the second arrangement state. Details of this process are shown in FIG. After this process, the process returns to S403.

(S411) On the other hand, if there is no touch in S404, in S411 the display control unit 204 checks whether the mode is mode=1 (second mode) and branches. If mode=1 (second mode), proceed to S412; otherwise, proceed to S414.

(S412) The display control unit 204 compares the touch position coordinates (X1, Y1) stored in S408 with the position of the icon in the home screen, determines whether they match, and branches. If the touched position, ie, the position where the pressure is held, corresponds to the icon position, the process proceeds to S413; otherwise, the process proceeds to S414.

(S413) The display control unit 204 executes the application associated with the corresponding icon. After that, like A4, the loop of this flow is exited, and the processing of the application to be executed is transitioned to.

(S414) The display control unit 204 sets the mode to mode=0 (first mode), and proceeds to S415.

(S415) The display control unit 204 performs icon arrangement restoration processing. That is, the display control unit 204 causes the icon arrangement state to transition from the second arrangement state to the first arrangement state. Then, return to S403.

[Control flow (2)]
FIG. 25 shows the details of the icon arrangement change processing in step S410. It has steps S421 to S428. S423 and S427 are included as characteristic processing parts.

(S421) The display control unit 204 checks whether the mode is mode=2 (third mode), and branches. If mode=2 (third mode), proceed to S425; otherwise, proceed to S422.

(S422) The display control unit 204 sets the mode to mode=2 (third mode).

(S423) The display control unit 204 performs icon arrangement rotation display processing. The display control unit 204 arranges a plurality of icons in a ring shape as shown in FIG. 23(b). A ring is placed based on the center point Q0. In the initial state, for example, the icon "App1" is placed at a predetermined position, which in this example is the upper end (12 o'clock on the clock), and the icon "App2" and subsequent icons are placed clockwise from there at equal intervals. do. The equal spacing is determined according to the number of icons.

Alternatively, the display control unit 204 arranges the icon closest to the pressed position (for example, "App2" in (a)) at the closest position on the ring (for example, the position of "App8" in (b)). may Depending on the number of icons, the size of the ring may be changed, the size of the icon may be changed, or a part of the ring may be displayed on the display screen 2.

(S424) The display control unit 204 starts the timer to measure the time as the value Tn, and ends this flow.

(S425) On the other hand, when mode=2 (third mode), in S425, the display control unit 204 sets the time interval Kn as in the third embodiment. That is, it is calculated as Kn=K0×Pt/Pn based on the above equation (3). This time interval Kn is used as a time interval for moving the icon by a predetermined distance. Specific values are different from those in the third embodiment. As described above, the time interval Kn decreases in accordance with the pressing strength Pn, so that the positions of the icons are switched more quickly.

(S426) The display control unit 204 determines whether or not the timer value Tn is greater than or equal to the time interval Kn, which is the threshold value T0, and branches. If Tn≧Kn, proceed to S427; otherwise, terminate this flow.

(S427) The display control unit 204 performs icon arrangement movement processing in the second arrangement state. The display control unit 204 moves each icon in a predetermined direction (clockwise) in units of predetermined equal intervals as the display of the group of icons arranged on the circumference of the ring. For example, the icon "App1", which was initially located at the top position in FIG. 23(b), is moved to the position of the icon "App2". Similarly, each icon is moved to the position of the previous icon.

(S428) The display control unit 204 restarts the timer and terminates this flow.

[Effects, etc.]
As described above, in the fourth embodiment, even if the finger cannot reach the desired icon that the user wants to select in the first layout state, the icon group is rotated to change to the second layout state so that the desired icon can be selected. When comes to your finger position, you can select that icon by releasing your finger. Conventionally, when a user selects an icon with one finger of one hand, the finger may not reach the desired icon. In that case, the user has to take the trouble of changing the state of the handle, pressing with fingers of another hand, or the like. In Embodiment 4, such trouble is not required, and icons can be easily and quickly selected with one hand and one finger. Also, by changing the time interval for rotating the icon according to the strength of the pressing force, it is possible to quickly move the desired icon to a position reached by the finger.

[Modification]
The following are possible as modifications of the fourth embodiment. The display control of the fourth embodiment can be similarly applied not only to a plurality of icons arranged on the screen but also to other objects. Examples of other objects include multiple mail items in a mail application screen.

Further, the movement of the icon group is not limited to intermittent movement at each time interval, and may be continuous movement similar to scrolling in the first embodiment. Movement of the icon group is not limited to ring-shaped rotation. For example, a plurality of icons are arranged in parallel in the X direction, the Y direction, or any other direction, and the leading icon and the trailing icon are connected by a loop. In that arrangement, the icon group is moved at intervals of time or by continuous scrolling or the like.

Further, the position of the center point Q0 of the icon arrangement ring is not limited to a fixed set value for implementation, and may be a variable position set by the user. For example, it can be set to a suitable position according to the position of the user's hand and fingers. Also, the position of the center point Q0 may be determined according to the position of the touch pressing each time. For example, the point of touch position coordinates (X1, Y1) may be set as the center point Q0, or the center point Q0 may be set near that point.

Also, the icon arrangement change control of the fourth embodiment may be combined with the control using the two types of operations of the second and third embodiments. In that case, the rotation direction of the icon can be changed according to the distinction of the pressing operation. For example, in the case of pressing the first area, the rotation can be clockwise, and in the case of pressing the second area, the rotation can be counterclockwise.

(Embodiment 5)
A mobile terminal device according to a fifth embodiment of the present invention will be described with reference to FIGS. 26 and 27. FIG. Hereinafter, configuration parts in the fifth embodiment that are different from the first embodiment and the like will be described. In the fifth embodiment, as two types of operations, a pressing operation on the pressure sensor on the front surface of the housing 1 and a pressing operation on the pressure sensor on the rear surface of the housing 1 are used separately. The mobile terminal device performs different display range change controls according to those operations. Similar to the second embodiment and the like, switching between a plurality of home screens is shown as a change control target and operation, but scrolling of content display information and the like can also be applied.

[Appearance, Operation]
FIG. 26 shows the appearance, operation, etc. of the mobile terminal device according to the fifth embodiment. The left side of FIG. 26 shows the front of the mobile terminal device, and shows the state in which it is held with the left hand. A touch pressure sensor 117 is arranged in a region corresponding to the display screen 2 . The right side of FIG. 26 shows the rear surface of the mobile terminal device, and shows the state in which it is held with the left hand. A rear surface pressure sensor 118 is arranged on the rear surface at a predetermined position, for example, the center in the X direction and the position in the upper region in the Y direction. An operation of pressing the back pressure sensor 118 with one finger of the left hand is shown.

[Device configuration]
The portable terminal device according to the fifth embodiment has a rear pressure sensor 118 in addition to the touch pressure sensor 117 in the sensor section 110 as a part different from the configuration of FIG. 2 of the first embodiment. The back pressure sensor 118 detects the presence and strength of pressure. The pressure detection unit 202 in FIG. 3 detects not only the pressure state of the touch pressure sensor 117 but also the pressure state of the rear pressure sensor 118 .

[Control flow]
FIG. 27 shows a flow of control processing of the display control unit 204 according to the fifth embodiment. It has steps S501 to S518.

(S501 to S510) The processing from S501 to S510 is the same as the processing from S201 to S210 in the second embodiment. In S502, a layer Ln is set for layer update at the time of screen switching. First, the screen of layer L1 is displayed. In S507, the strength of pressure Pn is detected using the touch pressure sensor 117 on the front surface. In S508, when the pressure strength Pn is equal to or greater than the threshold value Pt, the process proceeds to S511.

(S511) The display control unit 204 performs layer descending processing as screen switching in the first direction, updates the layer Ln as necessary, and returns to S503.

(S512) On the other hand, when there is no touch through the touch pressure sensor 117 in S505, the process proceeds to S512. In S<b>512 , the pressure detection unit 202 detects the pressure state through the back pressure sensor 118 . The pressure detection unit 202 acquires the pressure strength Pm as the pressure state.

(S513) The display control unit 204 determines whether or not the pressing force Pm is greater than or equal to a predetermined threshold value Ps, and branches. If Pm≧Ps, proceed to S514; otherwise, proceed to S515.

(S514) The display control unit 204 performs layer raising processing as the screen switching in the second direction, updates the layer Ln as necessary, and returns to S503.

(S515-S518) The processing after S515 is the same as the processing after S214 in FIG.

The details of the layer descending process of S511 are as follows. Basically, it is the same as the layer descending process of the second and third embodiments. In S511, the time interval Kn regarding layer updating is set for the pressure intensity Pn acquired in S507, as in S425 of FIG. Then, the display control unit 204 determines whether the time value Tn of the timer is equal to or greater than the time interval Kn, which is the threshold value T0, and branches. Subsequent processing is the same as described above.

The details of the layer ascending process of S514 are as follows. Basically, it is the same as the layer ascending process of the second and third embodiments. In S514, the time interval Kn for layer update is set for the strength of pressure Pm on the back surface acquired in S512, as in S425 of FIG. For example, the time interval Kn is determined based on the following formula (4).
Kn=K0×Ps/Pm (4)

Then, the display control unit 204 determines whether the time value Tn of the timer is equal to or greater than the time interval Kn, which is the threshold value T0, and branches. Subsequent processing is the same as described above.

[Effects, etc.]
As described above, in the fifth embodiment, when the user presses the touch pressure sensor 117 on the front display screen 2 by a predetermined amount or more, the plurality of home screens are switched in the first direction and displayed. be done. Further, when the user presses the back surface pressure sensor 118 on the back surface by a predetermined amount or more, a plurality of home screens are displayed while being switched in the second direction. The user can easily switch screens and the like while holding the mobile terminal device in one hand and properly using front pressure and rear pressure.

[Modification]
The following are possible as modifications of the fifth embodiment. In Embodiment 5, as the correspondence relationship of control, in the case of pressing the front surface, the layer descending process is performed, and in the case of pressing the back surface, the layer ascending process is performed. A pressure sensor may be provided not only at the rear pressure sensor 118 but also at another position of the housing 1, for example, at a side position.

(Other embodiments)
In the above-described embodiments, cases of content, home screens, application screens, icons, and the like have been described as targets of display range change control. In addition, scrolling, screen switching, icon movement, etc. have been described as display operations for change control. These are not limited to the combinations in the above-described embodiments, and various combinations are of course possible.

For example, it is possible to combine the touch pressing and tilt angle control of the first embodiment with the multiple screen switching control of the second embodiment. In this form, when the user presses the inside of the screen and tilts the housing, the mobile terminal device controls the direction, speed, time interval, etc. of screen switching using the strength of the pressure and the tilt angle.

For example, it is possible to combine the content scroll display control of the first embodiment with the multiple-finger press control of the second embodiment, or the two-type region press control of the third embodiment. In this form, when the user performs a pressing operation within the screen, the mobile terminal device controls the scrolling direction, speed, etc. of the content using the strength, position, and number of pressings.

Although the present invention has been specifically described above based on the embodiments, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the invention. Some or all of the functions of the present invention may be realized by hardware such as an integrated circuit, or may be realized by software program processing.

1 -- housing, 2 -- display screen, 3 -- display information, 4 -- display range, 5, 6 -- scroll.

Claims (1)

A display method for an information processing device,
a pressure detection step of detecting a pressure applied to the pressure sensor of the information processing device;
a display control step for performing control to change the display range of information displayed and output by the information processing device,
In the pressing detection step,
Detecting a touch on the pressure sensor, distinguishing and detecting two types of operations: a first operation of pressing any one point on the pressure sensor and a second operation of pressing any multiple points simultaneously;
In the display control step,
changing the display range of the information when the pressure is maintained when a pressure of a predetermined size or more is detected,
According to the distinction between the two types of operations, two types of operations for changing the display range of the information are a first operation of changing the display range of the information in a first direction and a second operation of changing the display range of the information in a second direction. to control the display by performing actions and
Display method.

Images