JP6639254B2 - Information terminal - Google Patents

Description

  The present invention relates to an information terminal having a bendable touch panel.

  In recent years, information terminals having a bendable touch panel (flexible display) have been studied. Such an information terminal can be used by a user in a state where the touch panel is folded in a mountain or in a valley. Therefore, as one of the usage scenes of such an information terminal, a case where the user performs a touch operation (swipe operation) across a bending position in a state where the touch panel is folded in a mountain or in a valley is considered. In addition, there has been conventionally known an information processing apparatus including two touch panels and capable of detecting a series of touch operations between the two touch panels (for example, see Patent Document 1 below).

JP 2010-250463 A

  Consider a case where the user performs a swipe operation on the bendable touch panel described above. When two display surfaces adjacent to each other across a bendable boundary among the display surfaces of the touch panel are parallel (that is, when the touch panel is not bent), the user can switch from one display surface to the other display surface. It is considered that a touch operation (swipe operation) on the touch panel can be performed without any problem.

  However, when the two display surfaces are inclined with respect to each other (that is, when the touch panel is folded at a bendable boundary), a swipe operation from one display surface to the other display surface is performed. In addition, the user's finger tends to separate easily near the bending position. Therefore, in the bent state, an operation intended by the user (a swipe operation from one display surface to the other display surface) may not be correctly detected. Note that Patent Document 1 discloses a mechanism for detecting a series of touch operations between two touch panels, but does not assume that the two touch panels are used in an inclined state. It does not suggest a solution to the problem.

  Therefore, an object of the present invention is to provide an information terminal capable of improving the operability of a user for a bendable touch panel.

  The information terminal of the present invention is an information terminal having a bendable touch panel, wherein the detection unit detects a bent state of the touch panel, a touch detection unit that detects a user's touch on the touch panel, and a touch detection unit that detects the touch state. Determination means for determining a user's touch operation based on the touch, at least one of the touch detection means and the determination means, when the bending state is detected by the detection means, than when the bending state is not detected Also, a predetermined process is performed to make it easy for the user's touch operation across the bending position of the touch panel to be determined as a series of touch operations.

  In the information terminal of the present invention, a predetermined process for facilitating determination of a user's touch operation across a bending position as a series of touch operations (for example, a swipe operation) upon detection of the bending state of the touch panel is detected. Is executed. Thus, in a situation where the touch panel is bent, it is possible to appropriately determine a series of touch operations that straddle the bending position (for example, an operation performed by a user with the intention of swiping across the bending position). As a result, the operability of the user for the bendable touch panel can be improved.

  In the above information terminal, the touch detection unit sets the touch detection sensitivity in an area within a predetermined range from the bending position to be higher than when the bending state is not detected, when the bending state is detected by the detection unit. Is also good.

  Consider a case in which the user performs a swipe operation from the one display surface on the touch panel to the other display surface on the touch panel based on the bending position when the touch panel is in the bent state. In this case, the user's finger is likely to separate from the display surface near the bending position, so that a swipe operation across the bending position may not be properly detected. On the other hand, according to the above configuration, when the bending state is detected, the touch detection sensitivity (hereinafter, referred to as “touch sensitivity”) in an area within a predetermined range from the bending position is increased. Even if the finger is slightly away from the display surface, it is possible to detect a touch in a region near the bending position. Thereby, it is possible to appropriately determine a series of touch operations across the bending position.

  In the above information terminal, the touch detection means detects the bending state by the detection means, and when detecting a touch approaching the bending position, detects the touch detection sensitivity in an area within a predetermined range from the bending position, It may be higher than when it is not detected.

  In the above configuration, as an opportunity to increase the touch sensitivity near the bending position, in addition to the touch panel being bent, a touch approaching the bending position is detected. Thereby, only when there is a possibility that a series of touch operations across the bending position may be performed, the touch sensitivity in the area near the bending position can be increased. In other words, when it is not assumed that the user touches the area near the bending position, it is possible to prevent the touch sensitivity from increasing in the area near the bending position. As a result, a series of touch operations across the bending position can be appropriately determined while appropriately preventing a touch contrary to the user's intention from being detected in a region near the bending position.

  In the information terminal, the determination unit detects the bent state by the detection unit, and detects a touch at a first position on the first display surface on one side of the display surface of the touch panel based on the bending position. If a touch is detected at the second position on the second display surface on the other side after the above, whether the distance between the first position and the second position on the display surface is within a predetermined threshold value May be determined, and when it is determined that the distance is within the threshold value, it may be determined that the touch at the first position and the touch at the second position constitute a series of touch operations.

  According to the above configuration, when the distance between the departure position (first position) on the first display surface and the landing position (second position) on the second display surface is within a threshold, the first The user's touch operation from the display surface to the second display surface (that is, the operation performed by the user with the intention of swiping) can be appropriately determined as a series of touch operations. That is, even if the user's finger is slightly separated near the bending position where touching becomes difficult in the bending state, it is possible to appropriately determine a series of touch operations across the bending position.

  In the above information terminal, the detecting means further detects an inclination angle between the first display surface and the second display surface, and the determining means determines the threshold value according to the inclination angle detected by the detecting means. May be.

  For example, it is considered that as the inclination angle between the first display surface and the second display surface increases, the area where the touch becomes difficult in the vicinity of the bending position (that is, the area where the finger easily separates) changes. For example, when the user performs a touch operation with the intention of a swipe operation from the first display surface to the second display surface, the size of the section where the finger is separated from the display surface (that is, the finger is separated from the display surface) It is considered that the distance from the departure point away from the camera to the landing point where the finger re-contacts the display surface) tends to increase as the inclination angle increases. According to the above configuration, by determining the threshold value according to the inclination angle, it is possible to more appropriately determine a series of touch operations across the bending position.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the information terminal which can improve the operability of a user with respect to a bendable touch panel.

It is an external appearance perspective view of the information terminal of this embodiment. It is a figure showing an example of a user's swipe operation in a bent state. FIG. 2 is a block diagram illustrating a functional configuration of the information terminal. FIG. 2 is a block diagram illustrating a hardware configuration of the information terminal. It is a figure used for description of the 1st processing in a bent state. It is a flowchart which shows the operation | movement of the information terminal when performing 1st process. It is a flow chart which shows operation of an information terminal at the time of performing the 2nd processing.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same or equivalent elements will be denoted by the same reference symbols, without redundant description.

  FIG. 1 is an external perspective view of the information terminal of the present embodiment. As shown in FIG. 1, the information terminal 1 of the present embodiment includes a three-foldable housing 2 having a substantially rectangular shape in plan view, and a touch panel 3 arranged on one main surface of the housing 2. . The touch panel 3 has a rectangular display surface 31. The touch panel 3 is an electronic component in which a display device such as a liquid crystal panel that performs screen display and a position input device that detects a touch (contact) of a user's finger and a touch position by a capacitance method are used. The information terminal 1 is used, for example, as a portable terminal carried by a user.

  As shown in FIG. 1, in the present embodiment, as an example, the display surface 31 is bendable along bending positions L1 and L2, which are two bendable boundaries. The bending positions L1 and L2 extend in the lateral direction of the display surface 31 so as to divide the display surface 31 into three equal parts along the longitudinal direction of the display surface 31. The housing 2 and the touch panel 3 together with the display surface 31 are configured to be bendable along the bending positions L1 and L2 of the display surface 31. The display surface 31 includes a display surface 31a located outside the bending position L1, a display surface 31b located between the bending positions L1 and L2, and a display surface 31c located outside the bending position L2. It is configured. In the following description, the direction in which the display surface 31b faces the front will be described.

  In the present embodiment, as an example, the display surface 31a can be bent forward by 180 degrees and can be bent backward by 90 degrees with respect to the display surface 31b. Further, the display surface 31c can be bent forward by 45 degrees and can be bent backward by 180 degrees with respect to the display surface 31b. In the information terminal 1, the housing 2 and the touch panel 3 are bent such that the display surface 31a is bent 180 degrees forward with respect to the display surface 31b, and the display surface 31c is bent 180 degrees backward with respect to the display surface 31b. This results in a compact three-fold state.

  In the touch panel 3, one screen (for example, a screen of a specific application such as a browser) may be displayed over the three display surfaces 31a, 31b, and 31c, or a separate screen may be provided for each of the display surfaces 31a, 31b, and 31c. A screen may be displayed (for example, screens of different applications A, B, and C may be displayed on the respective display surfaces 31a, 31b, and 31c). Further, one screen is displayed over two display surfaces adjacent to each other (for example, a display surface combining the display surfaces 31a and 31b), and another screen is displayed on the other one display surface (in this case, the display surface 31c). A screen may be displayed. Further, on the touch panel 3, a series of touch operations (for example, a swipe operation) can be executed between the respective display surfaces 31a, 31b, 31c.

  FIG. 2 is a diagram illustrating an example of the user's swipe operation in the bent state. As shown in FIG. 2, in the present embodiment, as an example, a state in which the display surface 31a and the display surface 31b are parallel to each other and the display surface 31c is bent forward by an inclination angle θ with respect to the display surface 31b. (Bent state) is assumed. In FIG. 2A, in the bent state, the user performs a swipe operation across the bending position L2 from the touch position P0 (x0, y0) on the display surface 31c to the touch position P3 (x3, y3) on the display surface 31b. It shows the situation. Such a swipe operation is performed, for example, when selecting an object displayed at the touch position P0 and moving the object to the touch position P3. Here, the coordinates (x, y) of the touch position are XY representing the position on the display surface 31 when the longitudinal direction of the display surface 31 is the X-axis direction and the short direction of the display surface 31 is the Y-axis direction. Coordinates. FIG. 2B schematically shows the locus of the position of the user's finger (the index finger in this example) in the swipe operation.

  As shown in FIG. 2B, in the bent state, the bending position L2 is a valley of the bending, so that a region near the bending position L2 (that is, the R surface formed by the display surfaces 31b and 31c). , The user's finger tends to separate from the display surface 31 easily. In the example of FIG. 2, after the user's finger separates from the display surface 31 (display surface 31c) at the touch position P1 (x1, y1), the user's finger moves at the touch position P2 (x2, y2) to the display surface 31 (display). Surface 31b). That is, at a position between the touch position P1 (x1, y1) and the touch position P2 (x2, y2), “finger separation” in which the user's finger separates from the display surface 31 occurs.

  When such finger separation occurs, in the conventional general touch detection mechanism, the touch operations before and after the finger separation are determined to be separate touch operations. In the example of FIG. 2, the touch operation (swipe operation) from the touch position P0 (x0, y0) to the touch position P1 (x1, y1) and the touch position P3 (x3, y3) from the touch position P2 (x2, y2). Touch operations (swipe operations) up to this point are determined to be touch operations independent of each other. As a result, in the above example, the object displayed at the touch position P0 moves only to the touch position P1, and does not move to the touch position P3 that the user intended as the destination. As described above, when the finger unintended by the user is generated, the user operation is performed by a touch operation originally intended by the user (in the example of FIG. 2, a series of swipes across the bending position L2 from the touch position P0 to the touch position P3). Operation).

  Therefore, the information terminal 1 can determine a user's touch operation (swipe operation or the like) straddling the bending positions L1 and L2 as a series of touch operations even when the finger separation as described above occurs in the bending state. It is configured. Hereinafter, each function of the information terminal 1 thus configured will be described.

  FIG. 3 is a block diagram illustrating a functional configuration of the information terminal 1. As shown in FIG. 3, the information terminal 1 includes a detection unit (detection unit) 11, a touch detection unit (touch detection unit) 12, a touch information storage unit 13, and a determination unit (determination unit) 14. .

  FIG. 4 is a hardware configuration diagram of the information terminal 1. As shown in FIG. 4, the information terminal 1 physically includes one or a plurality of CPUs 101, a RAM 102 and a ROM 103 as main storage devices, a touch panel 3, a communication module 104 as a data transmitting and receiving device such as a network card, a semiconductor memory. It is configured as a computer system including an auxiliary storage device 105 and the like. The functions shown in FIG. 3 are performed by reading predetermined computer software on hardware such as the CPU 101 and the RAM 102 shown in FIG. 4 so that the touch panel 3 and the communication module 104 are operated under the control of the CPU 101. It is realized by reading and writing data in the memory and the auxiliary storage device 105 and the like. Hereinafter, each function of the information terminal 1 shown in FIG. 3 will be described.

  The detection unit 11 is a part that detects a bent state of the touch panel 3. The detecting unit 11 constantly monitors whether the display surface 31 is bent along the bending position L1 or the bending position L2 of the touch panel 3. Specifically, the detection unit 11 monitors whether or not the display surface 31a is bent along the bending position L1 with respect to the display surface 31b based on a state in which the display surfaces 31a, 31b, and 31c are parallel. At the same time, it monitors whether or not the display surface 31c is bent along the bending position L2 with respect to the display surface 31b.

  The detecting unit 11 detects the bent state and also sets two display surfaces (a set of display surfaces 31a and 31b or a display surface 31b and 31c) adjacent to each other across a bending position (bending position L1 or bending position L2). ) Is detected. In the example of FIG. 2, the detection unit 11 detects a bent state in which the display surface 31c is bent with respect to the display surface 31b, and displays the display surface (first display surface) 31c and the display surface (second display surface). ) 31b is detected.

  The detection result by the detection unit 11 is passed to the touch detection unit 12 and the determination unit 14. The delivery of the detection result may be performed periodically, for example, at a predetermined time interval. Also, the delivery of the detection result is triggered by a change in the bent state of the display surface 31 (that is, a change in the inclination angle between the adjacent display surfaces across the bent position L1 or the bent position L2). You may.

  The touch detection unit 12 is a part that detects a user's touch on the touch panel 3. Specifically, the touch detection unit 12 detects a time when the user touches the display surface 31 of the touch panel 3 (touch time) and a position of the touch on the display surface 31 (touch position). I do. The touch position is represented by, for example, the XY coordinates described above.

  For example, consider a case in which the user performs a swipe operation of sliding a position touched by a finger on the display surface 31. In this case, the touch detection unit 12 detects a touch during the swipe operation. Then, for each detected touch, the touch detection unit 12 generates touch information that is a set of the XY coordinates (touch position) of each touch and the touch time at which each touch was detected. The touch information generated in this way is transferred to the touch information storage unit 13. The touch information storage unit 13 is a part that accumulates touch information acquired from the touch detection unit 12 for a certain period. The touch information stored in the touch information storage unit 13 is referred to by the touch detection unit 12 and the determination unit 14 as appropriate.

  When the bending state is detected by the detection unit 11, the touch detection unit 12 performs a series of touch operations by the user across the bending positions L1 and L2 of the touch panel 3 more than when the bending state is not detected. It is possible to execute a predetermined process (first process) for facilitating the determination.

Hereinafter, the first process will be specifically described using the example of FIG. 2 as a specific example. As illustrated in FIG. 5, when the detection unit 11 detects a bent state in which the display surface 31c is bent with respect to the display surface 31b, the touch detection unit 12 performs a touch in an area A within a predetermined range from the bending position L2. (Hereinafter, referred to as “touch sensitivity”) is higher than when the bent state is not detected (that is, when the display surface 31b and the display surface 31c are parallel). The area A is, for example, an area on the display surfaces 31b and 31c included in a range within a predetermined threshold value d1 from the bending position L2. That is, when the X-coordinate of the bending position L2 and _{x L2,} region A is a region where the X coordinate is comprised between _x L2 -d1 to _x L2 + d1.

  As described above, the touch panel 3 detects a touch by a capacitance method, and a small amount of static electricity is constantly flowing on the surface of the display surface 31. For example, by increasing the amount of the static electricity, it is possible to detect that the static electricity has been absorbed without the user's finger touching the display surface 31. That is, the touch can be detected only when the user's finger approaches the display surface 31 to some extent. Therefore, when the bending state shown in FIG. 5 is detected, the touch detection unit 12 increases the amount of static electricity flowing in the area A to be larger than the amount of static electricity flowing in the normal case (when the bending state is not detected). . In other words, when the bending state is detected, the touch detection unit 12 sets the area A near the bending position L2 as a high-sensitivity area having higher touch sensitivity than other areas. Accordingly, the touch sensitivity in the area A is increased, and even if the user's finger is slightly away from the display surface 31 in the area A, it is possible to detect the touch in the area A.

  In addition, the touch detection unit 12 increases the touch sensitivity near the bending positions L1 and L2, in addition to the fact that the touch panel 3 is in the bending state and the detection of a touch approaching the bending positions L1 and L2. It may be. That is, in the example of FIG. 5, when the bending state is detected by the detection unit 11 and the touch approaching the bending position L2 is detected, the touch detection unit 12 determines the touch detection sensitivity in the area A, It may be higher than when it is not detected.

  For example, based on the history of the touch information stored in the touch information storage unit 13 (that is, the time-series information on the touch position detected by the touch detection unit 12), the touch detection unit 12 detects a touch approaching the bending position L2. It can be determined whether or not it has been detected. For example, the touch detection unit 12 extracts the most recent (for example, five) touch information stored in the touch information storage unit 13 and the X coordinate of the touch position is monotonously changed to the value of the X coordinate of the bending position L2. If it can be determined that the touch is approaching, it may be determined that a touch approaching the bending position L2 has been detected.

  According to the above configuration, the touch sensitivity in the area A near the bending position L2 can be increased only when there is a possibility that a series of touch operations across the bending position L2 may be performed. In other words, when the user does not assume a touch operation across the bending position L2 (that is, when it is not assumed that the user touches the area A), it is possible to prevent the touch sensitivity of the area A from being increased. be able to. As a result, a series of touch operations (swipe operations) across the bending position L2 can be appropriately determined while appropriately preventing a touch against the user's intention in the region A from being detected.

  The determination unit 14 is a unit that determines a user's touch operation based on the touch detected by the touch detection unit 12 (that is, the touch information stored in the touch information storage unit 13). For example, the determination unit 14 refers to the history of the touch information stored in the touch information storage unit 13 and performs matching with the touch patterns of various touch operations stored in advance, so that the user's touch operation (tap operation, long operation) is performed. Push operation, swipe operation, flick operation, etc.). Since a method of determining a touch operation from touch information is known, a detailed description thereof is omitted. Hereinafter, a determination process specific to the determination unit 14 will be described.

  When the bending state is detected by the detection unit 11, the determination unit 14 performs a series of touch operations by the user across the bending positions L1 and L2, which are the boundaries where the touch panel 3 can be bent, when the bending state is not detected. It is possible to execute a predetermined process (second process) for making it easy to determine that this is a touch operation.

  Hereinafter, the second process will be specifically described using the example of FIG. 2 as a specific example. As described above, as shown in FIG. 2, when a finger separation occurs between the touch position P1 and the touch position P2, in the conventional general touch detection mechanism, the touch operations before and after the finger separation are separated touches. It is determined to be an operation. That is, the touch operation (swipe operation) from the touch position P0 to the touch position P1 and the touch operation (swipe operation) from the touch position P2 to the touch position P3 are determined to be mutually independent touch operations.

  Therefore, when the detecting unit 11 detects a bent state in which the display surface 31c is bent with respect to the display surface 31b, the determination unit 14 performs the following processing. In other words, after the touch is detected at the touch position P1 (first position) of the display surface 31c (first display surface) on one side based on the bending position L2 of the display surface 31, the determination unit 14 performs the other operation. When a touch is detected at the touch position P2 (second position) on the display surface 31b (second display surface) on the side, the distance between the touch position P1 and the touch position P2 on the display surface 31 is a predetermined threshold. It is determined whether it is within d2. When the distance is determined to be within the threshold value d2, the determination unit 14 determines that the touch at the touch position P1 and the touch at the touch position P2 constitute a series of touch operations.

For example, the determination unit 14 refers to the touch information storage unit 13 and obtains touch information regarding the touch position P1 at which the display surface 31c was last touched, and touch information regarding the touch position P2 at which the display surface 31b was first touched thereafter. , Get. Further, the determination unit 14 calculates a distance Δd between the touch position P1 (x1, y1) and the touch position P2 (x2, y2) according to the following equation (1). Then, when the following equation (2) is satisfied, the determination unit 14 determines that the touch at the touch position P1 and the touch at the touch position P2 constitute a series of touch operations.
Δd = √ ((x2-x1) ² + (y2-y1) ² ) (1)
Δd ≦ d2 (2)

  For example, when the above equation (2) holds, the discriminating unit 14 has caused a finger separation unintended by the user in a section from the touch position P1 to the touch position P2 (that is, a section in which no touch is detected). It is regarded as a section. That is, the determination unit 14 determines that a finger operation has not occurred between the touch position P1 and the touch position P2, and that a touch operation (swipe operation) connecting the touch position P1 and the touch position P2 has been performed. Thereby, the determination unit 14 can determine that the above-described user operation is a series of touch operations (swipe operations) from the touch position P0 to the touch position P3 via the touch positions P1 and P2.

  Note that, for a section from the touch position P1 to the touch position P2 where the finger separation actually occurs and the touch position is not detected by the touch detection unit 12, the determination unit 14 determines that the touch position P1 is on the display surface 31. It can be considered that the swipe operation has been performed on the straight path (the shortest path) connecting to the touch position P2. As another method, the determination unit 14 can regard that a swipe operation has been performed on a curved path connecting the touch position P1 and the touch position P2 as described below. That is, the determination unit 14 generates a virtual curve C1 that extends the trajectory (curve) of the touch position detected by the touch detection unit 12 from the touch position P0 to the touch position P1 toward the touch position P1. In addition, the determination unit 14 generates a virtual curve C2 that extends the trajectory (curve) of the touch position detected by the touch detection unit 12 from the touch position P2 to the touch position P3 toward the touch position P2. Then, the determination unit 14 may obtain an approximate curve that connects the touch position P1 and the touch position P2 and approximates both the curves C1 and C2, and may determine the approximate curve as a curved path that is regarded as a swipe operation. .

  Further, the determination unit 14 may determine the threshold value d2 according to the inclination angle θ formed between the display surface 31b and the display surface 31c detected by the detection unit 11. For example, it is considered that as the inclination angle θ between the display surface 31b and the display surface 31c increases, the area where the touch becomes difficult in the vicinity of the bending position L2 (that is, the area where the finger easily separates) changes. For example, when the user performs a touch operation with the intention of a swipe operation from the display surface 31c to the display surface 31b, the size of a section where the finger is separated from the display surface 31 (that is, the finger is separated from the display surface 31) It is considered that the distance Δd) from the touch position P1, which is the departure point, to the touch position P2, which is the point of contact where the finger re-contacts the display surface 31, tends to increase as the inclination angle θ increases. Therefore, according to the above configuration, the folding position L2 is determined by determining the threshold value d2 in accordance with the inclination angle θ (for example, by determining the threshold value d2 such that the threshold value d2 increases as the inclination angle θ increases). It is possible to more appropriately determine a series of touch operations that straddle.

  Further, when a finger unintended by the user occurs in a section between the touch position P1 and the touch position P2, the finger is first displayed on the display surface 31b from the time t1 at which the touch was last detected at the touch position P1 on the display surface 31c. The time difference Δt (= t2−t1) until time t2 when a touch is detected at the touch position P2 is considered to be relatively short. Conversely, when the time difference Δt is large, even if the above equation (2) is satisfied, a swipe operation from the touch position P0 to the touch position P1 and a swipe operation from the touch position P2 to the touch position P3 are performed. Are highly likely to be independent operations. Therefore, as a condition for determining that the touch at the touch position P1 and the touch at the touch position P2 constitute a series of touch operations, the determination unit 14 determines that the time difference Δt is within a predetermined threshold dt (Δt ≦ dt). May be added.

  The information terminal 1 may be configured to execute either one of the first process by the touch detection unit 12 and the second process by the determination unit 14, or to execute both processes. May be configured. When the first process is executed, basically, a touch is detected even if a finger separation occurs near the bending position (for example, the bending position L2), so that the second process is unnecessary. Conceivable. However, when the finger is too far from the surface of the area A, even if the first processing is executed, a touch may not be detected at the bending position L2. Even in such a case, by using the second processing described above together with the first processing, it is possible to appropriately determine a series of touch operations across the bending position.

  Next, an example of the operation of the information terminal 1 when the touch detection unit 12 executes the first process will be described with reference to FIG. First, the touch detection unit 12 determines whether the bending state is detected by the detection unit 11 (Step S11). Here, for example, when the bending state at the bending position L2 is detected (step S11: YES), the touch detection unit 12 refers to the touch information storage unit 13 and determines whether a touch approaching the bending position L2 is detected. Is determined (step S12).

  If a touch approaching the bending position L2 has been detected (step S12: YES), the touch detection unit 12 executes the first process described above. That is, the touch detection unit 12 increases the touch sensitivity in the area A near the bending position L2 (Step S13).

  On the other hand, when the bending state is not detected (Step S11: NO) or when the touch approaching the bending position L2 is not detected (Step S12: NO), the touch detection unit 12 sets the touch sensitivity of the area A to the normal touch sensitivity. The size is set (step S14).

  In addition, the touch detection unit 12 periodically executes the processing of steps S11 to S13 at predetermined time intervals. Thus, when the bending state is detected and a touch approaching the bending position (for example, the bending position L2) is detected, the touch sensitivity of the area A near the bending position L2 is increased, and a series of steps across the bending position L2 is performed. It is possible to appropriately determine a touch operation (for example, a swipe operation).

  Next, an example of the operation of the information terminal 1 when the determination unit 14 executes the second process will be described with reference to FIG. First, the determination unit 14 determines whether the bending state is detected by the detection unit 11 (Step S21). Here, for example, when the bending state at the bending position L2 is detected (step S21: YES), the determination unit 14 acquires information on the inclination angle θ formed by the display surface 31b and the display surface 31c from the detection unit 11. Then, the threshold value d2 of the above equation (2) is determined based on the inclination angle θ (step S22).

  Subsequently, the determination unit 14 refers to the touch information storage unit 13 and touches information on the touch position P1 at which the display surface 31c was last touched and touch information on the touch position P2 at which the display surface 31b was first touched. And get. Then, the determination unit 14 calculates the distance Δd between the touch position P1 (x1, y1) and the touch position P2 (x2, y2) using the above equation (1) (step S23).

  Subsequently, the determination unit 14 determines whether the above equation (2) holds (step S24). When the above equation (2) holds (step S24: YES), the determination unit 14 executes the above-described second processing. That is, the determination unit 14 considers that the finger has not separated between the touch position P1 and the touch position P2 in the user operation, and performs the user operation from the touch position P0 via the touch positions P1 and P2. It is determined that this is a series of touch operations (swipe operations) that reach the touch position P3 (step S25).

  On the other hand, when the bent state is not detected (step S21: NO) or when the above equation (2) is not satisfied (step S24: NO), the determination unit 14 determines whether the finger is between the touch position P1 and the touch position P2. It is determined that separation has occurred, and the touch operation (swipe operation) from the touch position P0 to the touch position P1 and the touch operation (swipe operation) from the touch position P2 to the touch position P3 are mutually independent touch operations. It is determined (step S26).

  Note that the determination unit 14 periodically executes the processes of steps S21 to S26 at predetermined time intervals. Accordingly, the bending state is detected, and the finger separation between the display surfaces 31b and 31c adjacent to each other across the bending position (for example, the bending position L2) is equal to or less than a certain value (that is, the above equation ( When 2) is satisfied), it is considered that no finger separation has occurred, and it is possible to appropriately determine a series of touch operations (for example, a swipe operation) across the bending position L2.

  In the information terminal 1 described above, the touch operation of the user straddling the bending position (in the present embodiment, as an example, the bending position L2) is a series of touch operations (for example, a swipe operation) when the bending state of the touch panel 3 is detected. ) Are performed (first processing and second processing) to make it easier to determine Accordingly, in a situation where the touch panel 3 is bent, it is possible to appropriately determine a series of touch operations (for example, an operation performed by a user with the intention of swiping across the bending position L2) straddling the bending position L2. Become. As a result, the operability of the user for the bendable touch panel 3 can be improved.

  Further, when the bending state is detected by the detection unit 11, the touch detection unit 12 increases the touch sensitivity in an area A within a predetermined range from the bending position L2 as compared with a case where the bending state is not detected. When the touch panel 3 is in a bent state (in the present embodiment, as an example, a state in which the display surface 31c is bent with respect to the display surface 31b), the user's finger tends to separate from the display surface near the bending position L2. For this reason, the swipe operation over the bending position L2 may not be properly detected. On the other hand, according to the above configuration, when the bending state is detected, the touch sensitivity in the area A within a predetermined range from the bending position L2 is increased, so that the user's finger is slightly away from the display surface 31 near the bending position L2. Even in this case, it is possible to detect a touch in the area A near the bending position L2. Thereby, it is possible to appropriately determine a series of touch operations across the bending position L2.

  In addition, when the bending state is detected by the detection unit 11 and a touch approaching the bending position L2 is detected, the touch detection unit 12 determines the touch sensitivity in the area A within a predetermined range from the bending position L2, Set higher than when not detected. In the above configuration, the opportunity to increase the touch sensitivity in the vicinity of the bending position L2 is, in addition to the fact that the touch panel 3 is in the bending state, the detection of a touch approaching the bending position L2. Accordingly, the touch sensitivity of the area A can be increased only when there is a possibility that a series of touch operations over the bending position L2 may be performed. In other words, when it is not assumed that the user touches the area A, it is possible to prevent the touch sensitivity of the area A from being increased. As a result, a series of touch operations across the bending position L2 can be appropriately determined while appropriately preventing a touch against the user's intention in the region A from being detected.

  In addition, the determination unit 14 detects the bent state by the detection unit 11 and detects a touch at the touch position P1 of the display surface 31c on one side of the display surface 31 of the touch panel 3 based on the bending position L2. If a touch is subsequently detected at the touch position P2 on the other display surface 31b, it is determined whether the distance Δd between the touch position P1 and the touch position P2 on the display surface 31 is within a predetermined threshold value d2. . Then, when it is determined that the distance Δd is within the threshold value d2, the determination unit 14 determines that the touch at the touch position P1 and the touch at the touch position P2 constitute a series of touch operations. According to the above configuration, when the distance Δd between the departure position (touch position P1) on the display surface 31c and the landing position (touch position P2) on the display surface 31b is within the threshold value d2, the display surface 31c is switched to the display surface. The user's touch operation up to 31b (that is, an operation performed by the user with the intention of a swipe operation) can be appropriately determined as a series of touch operations. That is, even if the user's finger is slightly separated near the bending position L2 where touching becomes difficult in the bending state, a series of touch operations across the bending position L2 can be appropriately determined.

  In the bent state, the detection unit 11 further detects the inclination angle θ formed between the display surface 31c and the display surface 31b adjacent to each other with the bending position L2 interposed therebetween, and the determination unit 14 determines the inclination detected by the detection unit 11. The threshold value d2 is determined according to the angle θ. According to the above configuration, by determining the threshold value d2 in accordance with the inclination angle θ, it is possible to more appropriately determine a series of touch operations across the bending position L2.

  The preferred embodiments and the modified examples of the present invention have been described above, but the present invention is not limited to the above-described embodiments and the modified examples, and various modifications can be made without departing from the gist thereof.

  For example, in the above embodiment, it is assumed that the user performs a swipe operation as a series of touch operations across the bending position L2. However, as a series of touch operations across the bending position L2, an operation other than the swipe operation (for example, flick) Operation, pinch-in, pinch-out, drag operation, etc.). Even in such a case, according to the information terminal 1 described above, it is possible to appropriately determine a series of touch operations across the bending position L2 as in the case where the user performs a swipe operation.

  Further, in the above embodiment, the touch panel 3 is described as adopting the capacitance type, but the type of the touch panel 3 may be a type other than the capacitance type. For example, when the above-described first process (that is, adjustment of the touch sensitivity of a partial area) is performed, the touch panel 3 may employ an electromagnetic induction type or the like in addition to the capacitance type. When only the second process is executed without executing the first process, the touch panel 3 may adopt, for example, a pressure-sensitive type in addition to the above-described electromagnetic induction type. Further, the touch on the touch panel 3 is not limited to the touch by the user's finger, and may be, for example, a touch by a stylus pen or the like.

  In the above-described embodiment, an example in which the display surface 31c is bent forward with respect to the display surface 31b (an example in which the bending position L2 is a bent valley) is described. However, the display surface 31c is positioned rearward with respect to the display surface 31b. (When the bending position L2 is the peak of the bending), the above-described first processing and second processing can be executed. Here, consider a case where the user performs a series of swipe operations from a certain position on the display surface 31c to a certain position on the display surface 31b when the bending position L2 is a mountain. In this case, it is conceivable that after the user's finger slides on the display surface 31c and reaches the bending position L2, which is a mountain, the finger is separated by the momentum of the slide operation. Therefore, even when the bending direction is opposite to that of the above-described embodiment, by executing the above-described first processing and second processing, it is possible to appropriately determine a series of touch operations across the bending position L2. Becomes

  Further, in the above embodiment, the example in which the touch panel 3 is bent at one bending position L2 as shown in FIG. 2 has been described. However, as shown in FIG. 1, the touch panel 3 is bent at each of the plurality of bending positions L1 and L2. May be bent. In such a case, the above-described first processing and second processing may be executed for each of the bending positions L1 and L2.

  DESCRIPTION OF SYMBOLS 1 ... Information terminal, 2 ... Case, 3 ... Touch panel, 11 ... Detection part, 12 ... Touch detection part, 13 ... Touch information storage part, 14 ... Judgment part, 31, 31a ... Display surface, 31b ... Display surface (No. Display surface (first display surface), L1, L2 bending position, P0, P3 touch position, P1 touch position (first position), P2 touch position (second display surface) Position of).

Claims (5)

An information terminal having a bendable touch panel,
Detecting means for detecting a bent state of the touch panel,
Touch detection means for detecting a user's touch on the touch panel,
Determining means for determining a touch operation of the user based on the touch detected by the touch detection means,
The touch detection hand stage, when the folded state is detected by said detecting means, the detection sensitivity of the touch in the region within a predetermined range from the bending position of the touch panel, than if the bending state is not detected Information terminal to raise the cost. The touch detection means, when the bending state is detected by the detection means, and when a touch approaching the bending position is detected, the touch detection sensitivity in an area within a predetermined range from the bending position is determined by the bending. 2. The information terminal according to claim 1 , wherein the information terminal is higher than a case where a state is not detected. The determination unit detects the bent state by the detection unit, and detects a touch at a first position on a first display surface on one side of the display surface of the touch panel based on the bending position. If a touch is detected at the second position of the second display surface on the other side after the above, the distance between the first position and the second position on the display surface is within a predetermined threshold. a judgment process of determining whether or not said if the distance in the determination process is determined to be within the threshold, a touch of the touch and the second position in the first position is set touch performs determination processing to determine that constituting the operation, when the folded state is not detected does not perform the judgment processing and the determination processing, the information terminal according to claim 1 or 2. The detecting means further detects an inclination angle between the first display surface and the second display surface,
4. The information terminal according to claim 3 , wherein the determination unit determines the threshold according to the tilt angle detected by the detection unit. 5.   An information terminal having a bendable touch panel,
  Detecting means for detecting a bent state of the touch panel,
  Touch detection means for detecting a user's touch on the touch panel,
  Determining means for determining a touch operation of the user based on the touch detected by the touch detection means,
  The determination unit detects the bending state by the detection unit, and detects a touch at a first position on a first display surface on one side of the display surface of the touch panel based on a bending position of the touch panel. When the touch is detected at the second position on the second display surface on the other side after the detection, the distance between the first position and the second position on the display surface is within a predetermined threshold. A determination process is performed to determine whether the touch is at the first position and the touch at the second position is determined when the distance is determined to be within the threshold in the determination process. An information terminal that performs a determination process of determining that the touch operation is configured, and does not perform the determination process and the determination process when the bending state is not detected.

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