JP2010211323A - Input system, portable terminal, input/output device, input system control program, computer-readable recording medium and method for controlling input system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To assign a plurality of processings to one operation position on an operation face without damaging operability. <P>SOLUTION: An input system includes a portable telephone set 100 including: an input device equipped with a position input part 21 for detecting an operation position operated on an operation face; and a click processing execution part 14 for executing processing, and includes: an acceleration detection part 30 for detecting the motion of the portable telephone set 100; and an operation determination part 13 for, when the operation position is detected by the position input part 21, acquiring motion information related with the motion detected by the acceleration detection part 30, wherein the click processing execution part 14 executes processing corresponding to the operation position and the motion information. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an input system that executes processing according to an input, a portable terminal, an input / output device, an input system control program, a computer-readable recording medium, and an input system control method.

  Conventionally, it has been proposed to use a touch panel technology to realize a user interface that can be operated more intuitively than a key device or the like (for example, Patent Document 1). The touch panel technology detects a place on the touch panel that is touched or approached by a user or a touch pen (stylus) using a touch panel provided with a contact type / optical type sensor, and performs predetermined processing according to the detected place. Is to do.

  The touch panel is one of so-called pointing devices. Other pointing devices include a mouse and are commonly used in desktop PCs. A typical mouse includes buttons that can be operated by left click and right click. Normally, different functions are assigned to the left click operation and the right click operation. In addition, a mouse having three or more buttons and having shortcut functions and the like assigned to buttons other than the left click button and the right click button has been developed.

  On the other hand, in a touch panel, when one place is touched, a predetermined function can be assigned according to this, but the number of functions that can be assigned is basically one.

  Therefore, methods for improving the operability by realizing assignment of functions such as a left click operation and a right click operation with a mouse on a touch panel have been studied.

  First, as a method for selectively using a plurality of functions when one place is touched on the touch panel, a method for providing a switch for assigning a function like the mouse in the portable terminal outside the touch panel is conceivable. In other words, the processing is selectively used depending on whether or not the switch is pressed.

  In addition, a technique has been proposed in which it is detected that two places are touched on the touch panel, and an operation similar to that of a mouse can be performed based on the detected content (for example, Patent Document 2).

Japanese Patent Laid-Open No. 4-77913 (published March 12, 1992) JP 2003-280816 A (released on October 2, 2003)

  However, the method of providing a switch causes the following problems. First, since a place for newly providing a switch on a portable terminal is required, miniaturization of the portable terminal is hindered. Since a switch is provided outside the touch panel, a finger that operates the touch panel and a finger that presses the switch are separated, and the operability may be impaired.

  Further, in the method of detecting that two places are touched, the user needs to touch the two places, and is forced to operate with two fingers. In particular, in a terminal that is operated with one hand such as a portable terminal, operability is impaired.

  The present invention has been made in view of the above problems, and an object thereof is to assign a plurality of processes corresponding to the position to one operation position on the operation surface without impairing operability. An input system, a portable terminal, an input / output device, an input system control program, a computer-readable recording medium, and an input system control method are provided.

  In order to solve the above problems, an input system according to the present invention is an input system including an input device including a position detection unit that detects an operation position operated on an operation surface, and a processing device that executes processing. The input device includes a motion detection unit that detects the motion of the input device, and a motion information acquisition unit that acquires motion information related to the motion detected by the motion detection unit when the position detection unit detects the operation position. And the processing device executes processing according to the operation position detected by the position detection unit and the exercise information acquired by the exercise information acquisition means.

  In order to solve the above problems, an input system control method according to the present invention includes an input device including a position detection unit that detects an operation position operated on an operation surface, and a processing device that executes processing. In the input system control method, when the position detection unit detects the operation position, the input device acquires motion information related to the motion detected by the motion detection unit that detects motion of the input device, and the processing device Is characterized in that a process corresponding to the operation position detected by the position detection unit and the acquired motion information is executed.

  According to the above configuration, first, the position detection unit provided on the main body of the input device detects the operation position operated on the operation surface. As the position detection unit of the input device, for example, a touch panel can be used.

  In the input device, the motion detection unit detects the motion of the input device.

  Then, when the position detection unit detects the operation position, the exercise information acquisition unit acquires information regarding the exercise detected by the exercise detection unit.

  In the processing device, the process execution unit executes a process according to the operation position detected by the position detection unit and the exercise acquired by the exercise information acquisition unit.

  For this reason, the process execution means can change the process performed according to the exercise | movement which the exercise | movement information acquisition means acquired, when a certain operation position is detected by the position detection part.

  As a result, it is possible to detect a position where an instruction member such as a touch pen, a user's finger or the like is moved on the operation surface, and assign a plurality of processes corresponding to the detected position based on the movement of the main body.

  Therefore, since there is no need to move the pointing member, fingers, etc. to a plurality of positions simultaneously with respect to the prior art where a plurality of processes are assigned corresponding to the plurality of positions where the plurality of pointing members are moved, respectively, It can prevent impairing operability.

  In the input system according to the present invention, the motion detection unit is preferably an acceleration sensor.

  According to the above configuration, since the acceleration can be detected, it is possible to detect the motion of the input device being shaken, tilted, or moved by measuring the magnitude and direction of the acceleration of the input device.

  In the input system according to the present invention, the acceleration sensor included in the motion detection unit detects acceleration in two directions, and the processing device includes a positive direction and a negative direction in each of the two directions detected by the acceleration sensor. It is preferable to execute four types of processing according to the four directions.

  According to the above configuration, since the acceleration sensor included in the motion detection unit detects acceleration in two directions, a positive direction and a negative direction are detected for each direction.

  Therefore, if processing is assigned to each of the four directions, the processing device can execute four types of processing according to the directions. Thereby, compared with the prior art which required a switch etc. for every process, there exists an effect that three or more types of processes can be allocated easily.

  In the input system according to the present invention, it is preferable that the processing device executes the processing assuming that there is no movement if the magnitude of the movement detected by the movement detection unit is equal to or smaller than a predetermined magnitude.

  According to the above configuration, when the motion detection unit detects the motion of the input device and the magnitude of the motion is equal to or less than the predetermined value, the processing device determines that there is no motion. That is, in this case, the processing device executes processing when there is no exercise.

  This is because, when the magnitude of the movement of the own apparatus is equal to or less than a predetermined magnitude, the movement is likely to be accidental.

  Thus, if the processing device is configured so as not to react to accidental exercise, there is an effect that an erroneous operation can be prevented.

  In the input system according to the present invention, the processing device performs processing only when the position detection unit detects the operation position after the movement information acquisition unit acquires information on the movement. It is preferable to carry out.

  According to the above configuration, the processing device executes the process only when the position detection unit continues to detect the operation position.

  By the way, there may be a time difference from when the position detection unit detects the operation position to when the motion detection unit detects motion. In such a case, it is conceivable that the position detection unit does not detect the operation position before the motion detection unit detects the motion, that is, the user does not touch the operation surface.

  In this case, there is a high possibility that the device itself has exercised not intended by the user. Therefore, by configuring as described above, it is possible to achieve an effect that an erroneous operation can be prevented.

  The present invention can be configured as a portable terminal that includes the input system, and the processing device is a portable terminal that executes a processing function of the portable terminal.

  By providing the input device according to the present invention as an input unit, the mobile terminal can properly use a plurality of processes based on the movement of the input device, that is, the movement of the mobile terminal and the operation position on the operation surface. There is an effect that the operability of the portable terminal can be improved.

The present invention is an input / output device including the input system, wherein the operation surface of the input device and the display screen are integrally formed, and the coordinates of the operation surface, the coordinates of the display screen, Can also be configured as an associated input / output device.
It is preferable.

  The input / output device includes a display unit and the input system according to the present invention. And the display screen which a display part has, and the operation surface of an input device are integrally formed, and both comprise what is called a touch screen. Further, the coordinates of the display screen are associated with the coordinates of the operation surface. According to this configuration, in addition to the intuitive operability of the touch screen, a plurality of processes based on the movement of the input / output device and the operation position on the operation surface can be used properly, and further operability can be expected. .

  The input system may be realized by a computer. In this case, an input system control program for causing the input system to be realized by the computer by operating the computer as the above-described means and a computer readable recording thereof. Various recording media are also within the scope of the present invention.

  In the input system according to the present invention, when the input device detects a motion of the input device and the position detection unit detects an operation position, the input device acquires motion information related to the motion detected by the motion detection unit. The information processing apparatus includes a motion information acquisition unit, and the processing device executes processing according to the operation position detected by the position detection unit and the motion information acquired by the motion information acquisition unit.

  According to the input system control method of the present invention, when the input device detects an operation position, the input device acquires the motion information related to the motion detected by the motion detection unit that detects the motion of the input device, and the processing device Is a control method for executing processing according to the operation position detected by the position detection unit and the acquired motion information.

  As a result, it is possible to detect a position where an instruction member such as a touch pen, a user's finger or the like is moved on the operation surface, and assign a plurality of processes corresponding to the detected position based on the movement of the main body.

  Therefore, since there is no need to move the pointing member, fingers, etc. to a plurality of positions simultaneously with respect to the prior art where a plurality of processes are assigned corresponding to the plurality of positions where the plurality of pointing members are moved, respectively, It can prevent impairing operability.

It is a functional block diagram which shows the principal part structure of the function of the mobile telephone which concerns on one Embodiment of this invention. It is a schematic diagram which shows the schematic apparatus structure of the said mobile telephone. It is the flowchart shown about the flow of the process of the said mobile telephone. It is a block diagram which shows the principal part structure of the mobile telephone which concerns on other embodiment of this invention. It is the figure shown about the displacement which a displacement measurement part measures. It is the flowchart shown about the flow of the process of the said mobile telephone. It is the flowchart shown about the flow of the process of the operation | movement determination in an operation | movement determination part.

(Introduction)
In recent years, for example, mobile terminals such as mobile phones and PDAs (Personal Digital Assistants) have become more sophisticated. At present, portable terminals having functions equivalent to those of a desktop PC (Personal Computer) have been developed.

  On the other hand, the user interface of a portable terminal has to be reduced in size compared to that of a PC for convenience of carrying and carrying, and still tends to be inferior in terms of usability compared to that of a PC.

  For this reason, the appearance of a user interface with better usability is desired in portable terminals. And, as a user interface of a portable terminal, those using a key device such as a numeric key or a cross key are generally used, but in order to obtain a more intuitive operability, a user interface using a touch panel technology is used. On-board mobile terminals have also been developed in recent years.

  In view of such a situation, in the following embodiment, an example will be described in which the operability of the mobile phone is further improved by incorporating the input system according to the present invention into the mobile phone.

[Embodiment 1]
One embodiment of the present invention is described below with reference to FIGS.

(Device configuration of mobile phone)
In this embodiment, the input system according to the present invention is incorporated in a mobile phone, thereby realizing operations such as a left click and right click of a mouse generally used in a desktop PC on the mobile phone. The case will be described. First, referring to FIG. 2, a schematic device configuration of a mobile phone (input system, mobile terminal, input / output device) 100 according to the present embodiment will be described. FIG. 2 is a schematic diagram showing a schematic device configuration of the mobile phone 100.

  The cellular phone 100 is configured to include a control unit 10, a storage unit 50, a touch screen unit 20, an acceleration detection unit 30, a main board 41, and a housing 42.

  The control unit 10 comprehensively controls various functions of the mobile phone 100. The function of the control unit 10 is realized, for example, when a processing device such as a CPU (Central Processing Unit) executes a program stored in a storage unit 50 as a storage element such as a RAM (Random Access Memory) or a flash memory. The Details of the control unit 10 will be described later.

  The storage unit 50 stores various data and programs. Examples of the storage unit 50 include a ROM (Read Only Memory) that is a read-only semiconductor memory that stores programs necessary when the control unit 10 operates, fixed data such as communication control data of the mobile phone 100, and the like. There is a RAM as a so-called working memory that temporarily stores data related to communication, data used for calculations, and calculation results, and a rewritable nonvolatile memory (for example, flash memory) that stores various setting data. Can be mentioned. Details of the storage unit 50 will be described later.

  The touch screen unit 20 provides a user interface such as input operation and screen display in the mobile phone 100, and includes a position input unit 21 and a display unit 22.

  The position input unit 21 detects a touch position on the operation surface, and generates input position information corresponding to the detected position. The position input unit 21 is a so-called touch panel, detects a user's touch operation, and generates input position information. The touch position is a position detected by the position input unit 21 when an instruction member such as a touch pen, a user's finger, or the like is moved on the operation surface. The touch operation is an operation for moving an instruction member such as a touch pen, a user's finger, and the like on the operation surface. The touch operation includes both an operation in which an instruction member, a finger or the like is actually in contact with the operation surface, and an operation in which the instruction member or the like is brought close to the operation surface.

  Further, the position input unit 21 is made of a material that transmits light at a portion corresponding to the display screen so as not to hinder display on the display screen of the display unit 22.

  As a method for the position input unit 21 to detect the touch position, for example, a matrix switch, a resistive film method, a surface acoustic wave method, an infrared method, an electromagnetic induction method, a capacitance method, and an image of an object are detected. And the like (light sensor method). However, the present invention is not limited to this, and various methods can be appropriately applied to the method for detecting the touch position.

  Further, the position input unit 21 may be configured to detect only a single touch position, or may be configured to be able to detect a plurality of touch positions simultaneously. Further, the input position information generated by the position input unit 21 may include, for example, two-dimensional coordinate data indicating a touch position on the operation surface.

  The display unit 22 has a display screen for displaying image data, receives image data from the control unit 10, and displays an image on the display screen based on the received image data. The display unit 22 includes, for example, a display element such as an LCD (Liquid Crystal Display), a PDP (Plasma Display Panel), and an EL (Electroluminescence) display, and a driver circuit that drives the display element based on received image data. It is a display device.

  In the present embodiment, the position input unit 21 has an integral structure superimposed on the display screen of the display unit 22. The coordinates of the display screen correspond to the coordinates of the operation surface. The association between the two coordinates may be stored in the storage unit 50. Accordingly, the user can perform an input operation on the operation surface while confirming the screen displayed on the display screen of the display unit 22. Specifically, for example, the screen displayed on the display unit 22 displays a GUI (Graphical User Interface) screen such as an icon on the display screen. Then, when the operation surface of the position input unit 21 is touched with a user's finger (or touch pen), coordinate information corresponding to the touched icon or image is generated by the position input unit 21.

  However, the present invention is not limited to this, and any structure can be used as long as the display screen and the operation surface are shared.

  The acceleration detection unit 30 detects acceleration in a predetermined direction acting on the mobile phone 100 by an acceleration sensor. Further, the acceleration detection unit 30 may be switched between operation and stop by turning on / off the power supply of the power supply. The acceleration detection unit 30 detects that the mobile phone 100 is accelerating in any direction, for example, a horizontal direction or a vertical direction with respect to the display screen. Acceleration information indicating that is generated as motion information. This operation information can be used as information for determining the movement, movement, and physical operation of the mobile phone 100.

  The acceleration detection unit 30 may be any type of acceleration sensor of one axis, two axes, and three axes. Moreover, the acceleration detection part 30 does not need to produce | generate acceleration information, when the acceleration of the mobile telephone 100 is not detected.

  The main board 41 constitutes a circuit that electrically connects the control unit 10, the storage unit 50, the touch screen unit 20, and the acceleration detection unit 30 to each other.

  The housing 42 is for housing the main substrate 41 and for fitting the touch screen unit 20, and is a main body case of the mobile phone 100.

(Functional configuration of mobile phone)
Next, with reference to FIG. 1, a configuration of main parts of functions of mobile phone 100 according to the present embodiment will be described. FIG. 1 is a functional block diagram showing a main configuration of functions of the mobile phone 100. In the figure, the same components as those in FIG. 2 are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIG. 1, the storage unit 50 includes an input position information storage unit 51, an operation reference value storage unit 52, and a display coordinate information storage unit 53 in more detail.

  The input position information storage unit 51 stores the input position information generated by the position input unit 21.

  The operation reference value storage unit 52 stores an operation reference value indicating a reference for the operation determination unit (exercise information acquisition means) 13 to determine that the mobile phone 100 has physically operated. In the present embodiment, a reference value for the magnitude of movement of the mobile phone 100 is stored as an operation reference value.

  The display coordinate information storage unit 53 stores display coordinate information indicating the coordinates of icons included in image data that the display control unit 11 displays on the display screen of the display unit 22. The display coordinate information may include two-dimensional coordinate data indicating a specific position on the image data.

  More specifically, the control unit 10 includes a display control unit 11, an input position information acquisition unit 12, an operation determination unit 13, a click processing execution unit (processing device) 14, and an icon specification unit 15. .

  The display control unit 11 generates image data to be displayed on the display unit 22 and causes the display unit 22 to display the generated image. The image data includes icons for selecting and executing processing by an input operation.

  When the image data includes icons, the display control unit 11 stores display coordinate information indicating the coordinates of the icons in the image data in the display coordinate information storage unit 53.

  Note that the icons are symbols, symbols, and the like indicating application programs, data stored in files, and the like. Icon designs, symbols and the like generally occupy a certain area on the display screen. For this reason, the display coordinate information may indicate representative coordinates in the area occupied by the icon on the display screen. For example, in the case of an icon having a rectangular display area, the upper right coordinate of the display area can be set as a representative coordinate. Further, a certain area may be included in the display coordinate information with this representative coordinate as a base point.

  The user can select an icon and execute processing of an application program assigned to the selected icon on the mobile phone 100 or browse the contents of the file.

  When a plurality of icons are included in the image data, the display coordinate information may be composed of a set of icon identification information and its two-dimensional coordinate data.

  The input position information acquisition unit 12 acquires input position information from the position input unit (position detection unit, input device) 21 and performs processing based on the acquired input position information.

  If the input position information acquisition unit 12 cannot acquire the input position information from the position input unit 21 at a certain time, the input position information acquisition unit 12 determines that the touch position on the operation surface is not detected at that time. That is, in this case, it is determined that the touch operation is not performed. Further, the input position information acquisition unit 12 records the acquired input position information in the input position information storage unit 51.

  The motion determination unit 13 determines the movement of the telephone 100 based on the motion information acquired from the acceleration detection unit (motion detection unit) 30.

  More specifically, the operation determination unit 13 determines the physical operation of the mobile phone 100 as follows. First, the motion determination unit 13 calculates a value indicating the magnitude of movement of the mobile phone 100 based on the acceleration information included in the motion information. A known method can be used to calculate the value indicating the magnitude of the movement.

  Then, the motion determination unit 13 reads the motion reference value from the motion reference value storage unit 52, and compares the calculated value indicating the magnitude of motion with the motion reference value. Here, when the value indicating the magnitude of the calculated motion is equal to or greater than the motion reference value, the motion determination unit 13 determines that “the mobile phone 100 has physically operated”. On the other hand, when the value indicating the magnitude of the calculated motion is smaller than the motion reference value, the motion determination unit 13 determines that “the mobile phone 100 is not physically operating”.

  The click process execution unit 14 acquires an operation determination result from the operation determination unit 13 and executes a process according to the acquired determination result.

  When the determination result of the operation determination unit 13 is “the mobile phone 100 is not physically operating”, the click process execution unit 14 executes a process corresponding to the determination result. Hereinafter, for convenience of explanation, this corresponding process is referred to as “left click process” in accordance with a process assigned to a general left button of a mouse.

  On the other hand, when the determination result is “the mobile phone 100 has physically operated”, the click process execution unit 14 executes a process corresponding to the determination result. Hereinafter, for convenience of explanation, this corresponding processing is referred to as “right click processing” in accordance with the processing assigned to the right button of a general mouse as before.

  A process for calling a function assigned to an icon is assigned to the “left click process”. In addition, a process for displaying an operation associated with an icon in a menu format is assigned to the “right click process”. Examples of operations associated with icons include editing operations such as copying, cutting, and pasting. The menu format is a format in which selection items including “keywords”, “icons” indicating the operation, or combinations thereof are displayed side by side. In addition, a selection item displayed in the menu format can be selected by an input operation, and an operation corresponding to the selection item can be executed.

  Note that the click processing execution unit 14 specifies which icon is the target of processing via the icon specifying unit 15. Further, the present invention is not limited to this, and left click processing corresponding to the case where “the mobile phone 100 is not physically operated” and right click processing corresponding to the case where “the mobile phone 100 is physically operated” Arbitrary processing can be assigned.

  Further, the right click process and the process assigned to the right click process may be stored in the storage unit 50 in association with each other. Then, by rewriting this correspondence, the process assigned to the right click process may be changed. The same applies to the left click process.

  The icon specifying unit 15 specifies what icon is displayed at the place where the touch operation is performed. In other words, the icon specifying unit 15 is for specifying which icon is touched.

  Specifically, the icon specifying unit 15 specifies an icon touched as follows.

  First, the icon specifying unit 15 acquires the input position information from the input position information acquiring unit 12, and the icon specifying unit 15 reads the display coordinate information from the display coordinate information storage unit 53. Then, it is determined whether an icon is displayed at a position corresponding to the coordinates indicated by the acquired input position information. That is, the icon specifying unit 15 determines whether the position indicated by the acquired input position information matches the position indicated by the read display coordinate information.

  If the icon specifying unit 15 determines that these positions match, the icon specifying unit 15 further specifies which icon matches. This specification may be performed by icon identification information included in the display coordinate information. When the icon identifying unit 15 identifies the icon being touched, the icon identifying unit 15 notifies the operation determining unit 13 of the fact.

  As described above, in the present embodiment, the mobile phone 100 includes the input system according to the present invention. The input system according to the present invention is configured to include an input device and a processing device. However, in this embodiment, the input device and the processing device are integrally configured.

  Specifically, in the present embodiment, the input device and the processing device are configured to share the control unit 10 and the storage unit 50. More specifically, the input device includes a position input unit 21, an acceleration detection unit 30, an input position information acquisition unit 12, an operation determination unit 13, an icon specification unit 15, an input position information storage unit 51, an operation And a reference value storage unit 52. The processing device includes a click process execution unit 14 and a display coordinate information storage unit 53.

  However, the design of the input device and the processing device can be changed as appropriate. Each of the input device and the processing device may include a unique control unit 10 and storage unit 50. Further, the input device may be configured as a peripheral device of the processing device. The connection form between the input device and the processing device may be wired or wireless.

(Processing flow of mobile phone)
Next, a processing flow of the mobile phone 100 will be described with reference to FIG. FIG. 3 is a flowchart showing a processing flow of the mobile phone 100.

  As a premise, it is assumed that the display control unit 11 displays a plurality of icons on the display unit 22, and the display coordinate information storage unit 53 stores the display coordinate information of the plurality of displayed icons. .

  First, the input position information acquisition unit 12 determines whether or not the user is performing a touch operation on the operation surface (S101). This determination is performed by the input position information acquisition unit 12 determining whether or not the input position information has been acquired from the position input unit 21. When the input position information can be acquired from the position input unit 21, the input position information acquisition unit 12 determines that “the user is performing a touch operation on the operation surface”. On the other hand, if the input position information cannot be acquired from the position input unit 21, the input position information acquisition unit 12 determines that “the user is not performing a touch operation on the operation surface”. The same applies to the following.

  When it is determined that “the user is not performing a touch operation on the operation surface” (NO in S101), the input position information acquisition unit 12 waits for a user's touch operation (returns to S101). That is, the input position information acquisition unit 12 retries acquisition of input position information until the input position information can be acquired from the position input unit 21. On the other hand, when the input position information acquisition unit 12 determines that “the user is performing a touch operation on the operation surface” (YES in S101), the icon specifying unit 15 inputs from the input position information storage unit 51. The position information is acquired, and the coordinates of the touch position on the operation surface are acquired from the acquired input position information (S102).

  Subsequently, the icon specifying unit 15 reads display coordinate information from the display coordinate information storage unit 53. Then, the icon specifying unit 15 determines whether or not the coordinates of the touch position on the operation surface indicated by the input position information match the coordinates of the icon indicated by the display coordinate information (S103).

  If the coordinates of the touch position do not match the coordinates of the icon as a result of the determination by the icon specifying unit 15 (NO in S103), the user's touch operation is awaited again (return to S101). On the other hand, as a result of the determination by the icon specifying unit 15, when the coordinates of the touch position and the coordinates of the icon match (YES in S <b> 103), the icon specifying unit 15 includes a plurality of displayed icons. It is identified which icon matches (S104).

  When receiving the notification that the input position information has been acquired from the input position information acquisition unit 12, the operation determination unit 13 turns on the power supply to the acceleration detection unit 30 (S105).

  When the power supply to the acceleration detection unit 30 is “ON”, the motion determination unit 13 determines whether or not a movement has been detected in the mobile phone 100 (S106). This determination is performed based on whether or not the operation determination unit 13 has acquired the operation information from the acceleration detection unit 30. The motion determination unit 13 determines that “movement has been detected” when the motion information from the acceleration detection unit 30 can be acquired. When the motion determination unit 13 cannot acquire the motion information from the acceleration detection unit 30, it determines that “no motion was detected”.

  Here, first, a case will be described where the motion determination unit 13 determines in S106 that "no motion was detected" (NO in S106). In this case, the input position information acquisition unit 12 further determines whether or not the user is performing a touch operation on the operation surface (S108). When the input position information acquisition unit 12 determines that “the user does not perform a touch operation on the operation surface” (NO in S108), the click process execution unit 14 executes “left click process” ( S110). Thereafter, the control unit 10 turns off the power supply to the acceleration detection unit 30 (S112), and returns to the process of S101.

  On the other hand, when the input position information acquisition unit 12 determines that “the user is touching the operation surface” (YES in S108), the process returns to S106.

  The reason why such a process is performed in S108 is as follows. That is, in S108, when the input position information acquisition unit 12 determines that “the user is performing a touch operation on the operation surface”, the user continues to operate the operation surface after starting the process. It ’s likely that you ’re still touching.

  That is, in this case, it is assumed that the user is going to move the mobile phone 100 for the “right click process”. However, it may take some time until the mobile phone 100 is moved after the user performs the touch operation. For this reason, if the “left click process” is executed while the user is performing a touch operation, an operation unintended by the user may be executed.

  Therefore, the operation determination unit 13 is configured to wait for the user to move the mobile phone 100 while the user is performing a touch operation. In other words, in this embodiment, in order for the user to cause the mobile phone 100 to execute the “left click process”, the user intentionally stops the touch operation.

  Next, a case will be described in which the motion determination unit 13 determines that “movement has been detected” in S106 (NO in S106). In this case, the motion determination unit 13 calculates a value indicating the magnitude of the movement of the mobile phone 100 based on the acceleration information included in the acquired motion information. Then, the motion determination unit 13 determines whether the calculated value indicating the magnitude of the motion is greater than or equal to the motion reference value (S107).

  The motion determination unit 13 determines that “the mobile phone 100 is not physically operating” when the calculated value indicating the magnitude of the motion is not equal to or greater than the motion reference value (NO in S107). Then, the process returns to S106. As described above, when the value indicating the magnitude of the movement of the mobile phone 100 is small, the reason for returning to S106 again may be that the movement is not intended by the user or is accidental. This is because the nature is high.

  If the value indicating the magnitude of the calculated motion is equal to or greater than the motion reference value (YES in S107), the motion determination unit 13 determines that “the mobile phone 100 has physically operated”, and according to this determination The click process execution unit 14 causes the input position information acquisition unit 12 to determine whether the user is performing a touch operation on the operation surface (S109). When the input position information acquisition unit 12 determines that “the user is performing a touch operation on the operation surface” (YES in S109), the click process execution unit 14 executes “right click process” (S111). To do. That is, the click process execution unit 14 displays the operation associated with the icon specified in S104 on the display unit 22 via the display control unit 11 in a menu format.

  Thereafter, the control unit 10 turns off the power supply to the acceleration detection unit 30 (S112), and returns to the process of S101.

  On the other hand, when the input position information acquisition unit 12 determines that “the user does not perform a touch operation on the operation surface” (NO in S109), the click process execution unit 14 performs “right click process” and “left click”. Do not execute any process of "Process". Then, the control unit 10 turns off the power supply to the acceleration detection unit 30 (S112), and returns to the process of S101.

  In S109, unlike in S108, when it is determined that “the user is performing a touch operation on the operation surface”, the click process execution unit 14 executes the “right click process” for the following reason. It is. That is, in such a case, there is a high possibility that the mobile phone 100 has a sudden movement and the user has performed an unintended touch operation.

  As described above, in S105, the power supply to the acceleration detection unit 30 is turned “ON”, and in S112, the power supply to the acceleration detection unit 30 is turned “OFF” only when necessary. This is to supply power to the detection unit 30. Thereby, unnecessary power consumption is suppressed.

(Action / Effect)
As described above, the mobile phone 100 according to the present embodiment includes a mobile phone including the input device including the position input unit 21 that detects the operation position operated on the operation surface, and the click processing execution unit 14 that executes the process. In the telephone 100, an acceleration detection unit 30 that detects the movement of the mobile phone 100, and a movement determination unit 13 that acquires movement information related to the movement detected by the acceleration detection unit 30 when the position input unit 21 detects an operation position. The click processing execution unit 14 is configured to execute processing according to the operation position and the exercise information.

  As a result, it is possible to detect a position where an instruction member such as a touch pen, a user's finger or the like is moved on the operation surface, and assign a plurality of processes corresponding to the detected position based on the movement of the main body.

  Accordingly, it is not necessary to move the pointing member to a plurality of positions at the same time as in the prior art in which a plurality of processes are assigned corresponding to the plurality of positions where the plurality of pointing members are moved. It is possible to prevent damage.

(Modification)
A preferred modification of the present embodiment will be described below.
(1) In the present embodiment, the acceleration detection unit 30 generates the acceleration information. However, the present invention is not limited to this. Instead of the acceleration detection unit 30, an operation detection unit (not shown) for detecting other physical quantities may be provided. This motion detection unit may detect, for example, the angular velocity of the mobile phone 100, and may be configured to calculate the magnitude of shaking, tilting, and rotation of the mobile phone 100. Accordingly, the operation determination unit 13 may determine the operation of the mobile phone 100 based on the physical quantity detected by the operation detection unit.
(2) The input position information acquired by the input position information acquisition unit 12 in S109 and the input position information acquired by the input position information acquisition unit 12 in S101 may not indicate the same coordinates. . This is because it is conceivable that the user's touch position is shifted along the way when the user shakes the mobile phone 100 left and right and moves the mobile phone 100.
(3) In S107 of the above flow, the motion determination unit 13 may be configured to perform the processing of S108 when the calculated value indicating the magnitude of motion is not equal to or greater than the motion reference value (NO in S107). . That is, if a certain amount of movement is not detected, the “left click” process may be determined.
(4) The mobile phone 100 is provided with a notification unit (not shown) for performing notification by beep sound, voice, light emission / flashing, etc., and the operation determination unit 13 indicates that the value indicating the magnitude of the calculated motion is If it is equal to or greater than the reference value (YES in S107), the notification unit may notify the user accordingly. With this configuration, the user can easily recognize that the mobile phone 100 has determined that “the mobile phone 100 has physically operated”. Further, the notification unit may notify that the “right click process” has been executed.
(5) If the value indicating the magnitude of the calculated motion is greater than or equal to a predetermined threshold in S107, the process may return to the first process. This is because if a motion that is higher than expected is detected, the motion is likely to be abrupt. This threshold value is determined within the range of movement caused to the mobile phone 100 by the normal action of the user.

[Embodiment 2]
A further embodiment of the present invention will be described below with reference to FIGS. In the present embodiment, a case will be described in which a plurality of processes are selectively used depending on the direction in which the user shakes or rotates the mobile phone (input system, mobile terminal, input / output device) 200.

(Device configuration of mobile phone)
First, with reference to FIG. 4, a configuration of main parts of the mobile phone 200 according to the present embodiment will be described. FIG. 4 is a block diagram showing a main configuration of the mobile phone 200 according to the present embodiment. Compared to the mobile phone 100 shown in FIG. 1, the mobile phone 200 shown in the figure replaces the operation reference value storage unit 52 with a displacement threshold value information storage unit 61, replaces the acceleration detection unit 30 with a displacement measurement unit 62, and Instead of the operation determination unit 13, an operation determination unit 63 is provided, and instead of the click process execution unit 14, a shortcut process execution unit 64 is provided. Moreover, the icon specific | specification part 15 is removed. A displacement information storage unit 65 is provided. Other configurations are the same as those in FIG. In addition, the same code | symbol is attached | subjected to the structure which has the function similar to the structure demonstrated in the said embodiment, and the description is abbreviate | omitted.

  The displacement threshold information storage unit 61 stores displacement threshold information used when the operation determination unit 63 determines the direction in which the mobile phone 100 has operated. Specifically, the displacement threshold information storage unit 61 stores displacement threshold information including two values: an X-axis threshold that is a threshold for the X-axis and a Y-axis threshold that is a threshold for the Y-axis. .

  The displacement information storage unit 65 is for storing the displacement information generated by the displacement measurement unit 62.

  The displacement measuring unit 62 measures the displacement of the position of the mobile phone 200 in the two axial directions of the X axis and the Y axis, and generates displacement information indicating the measured displacement. Specifically, the displacement measuring unit 62 can be realized by providing an acceleration sensor or the like that can detect biaxial acceleration, detecting the acceleration, and calculating the displacement based on the detected acceleration. The function for calculating the displacement may be realized by either hardware or software. Here, the displacement measured by the displacement measuring unit 62 will be described with reference to FIG. FIG. 5 is a diagram illustrating the displacement measured by the displacement measuring unit 62.

  As shown in FIG. 5, the touch screen portion 20 of the mobile phone 200 faces the front side of the drawing. The direction from the upper end P1 of the mobile phone 200 to the lower end P2 is the direction of gravitational acceleration. The longitudinal direction of the casing 42 of the mobile phone 200 coincides with the direction of gravity acceleration.

  Here, a direction parallel to the surface of the touch screen unit 20 and perpendicular to the direction of gravitational acceleration is defined as the X axis. In addition, a direction perpendicular to the surface of the touch screen unit 20 and perpendicular to the direction of gravitational acceleration is defined as the X axis.

  That is, the X-axis direction is the left-right direction of the drawing, and the Y-axis direction is the direction from the front side of the drawing to the back side. The positive direction of the X axis is the direction from the left to the right of the drawing, and the positive direction of the Y axis is the direction from the front side of the drawing to the back side.

  For convenience of explanation, it is assumed that the lower end P2 of the mobile phone 200 is fixed and the upper end P1 is displaced. The direction of displacement is the direction of arrows a, b, c and d. The arrow a points to the negative direction of the Y axis, the arrow b points to the positive direction of the Y axis, the arrow c points to the negative direction of the X axis, and the arrow d Points to the negative direction of the axis.

  The displacement is expressed by how much the upper end P1 and the lower end P2 are displaced. In order to simplify the explanation, the displacement in the direction of gravitational acceleration is not measured. When the straight line connecting the upper end P1 and the lower end P2 is parallel to the direction of gravitational acceleration, (X, Y) = (0, 0). That is, the displacement is expressed as coordinate data composed of an X coordinate and a Y coordinate.

  Here, if the X coordinate is a positive value, it indicates that the mobile phone 200 itself has been displaced in the direction of the arrow d, and if it is a negative value, the mobile phone 200 itself has been displaced in the direction of the arrow c. It shows that. Similarly, if the Y coordinate is a positive value, it indicates that the mobile phone 200 itself is displaced in the direction of the arrow b, and if the Y coordinate is a negative value, the mobile phone 200 itself is displaced in the direction of the arrow a. It shows that. The displacement measuring unit 62 measures the displacement of the mobile phone 200 in the directions of arrows a to d.

  Further, the displacement measuring unit 62 stores displacement information generated from the measured displacement in the displacement information storage unit 65. Further, the displacement measuring unit 62 may be switched between operation / stop by turning ON / OFF the power supply.

  The operation determination unit 63 determines the direction of the operation of the mobile phone 200 based on the displacement information generated by the displacement measurement unit 62. That is, when the user shakes or rotates the mobile phone 200, the operation determination unit 63 causes the mobile phone 200 to change the “direction of arrow a”, “direction of arrow b”, “direction of arrow c”, Also, it is determined which of the “directions of the arrow d” the operation is performed. Further, when the mobile phone 200 does not move in any direction, that is, when the mobile phone 200 is not displaced beyond a certain level, the motion determination unit 63 determines that it is “still state”. Further, the motion determination unit 63 determines “unknown” when the motion direction cannot be specified.

  The motion determination by the motion determination unit 63 is performed by determining how much the position of the mobile phone 200 has been displaced with reference to the displacement information generated at a certain point in time. Details of the operation determination will be described in “Operation determination processing flow” described later.

  The shortcut process execution unit 64 executes a predetermined process assigned to the direction of the operation for the target object touch-operated on the display screen according to the result of the operation determination by the operation determination unit 63. . Here, the object refers to an icon, a selected item, and the like. The target object also includes a screen background and the like. The shortcut process execution unit 64 is configured to execute a “normal process” when the operation determination of the operation determination unit 63 is “still state”. “Normal processing” means, for example, processing such as opening a file, opening a folder, or executing a program.

  The following processing is assigned to the direction of each operation. That is, “cut” processing is assigned to “direction of arrow a”, and “paste” processing is assigned to “direction of arrow b”. Further, a “copy” process is assigned to “the direction of arrow c”, and a “delete” process is assigned to “the direction of arrow d”. These assignments may be stored in the storage unit 50 as setting information.

  Note that the shortcut process execution unit 64 is stored in the input position information storage unit 51 when executing the “normal process”, “cut”, “paste”, “copy”, and “delete” processes. The input position information is read out, and those processes are executed on the object displayed at the coordinates on the display screen corresponding to the coordinates indicated by the read input position information.

  It is assumed that what kind of object is displayed on the display screen is stored in the display coordinate information storage unit 53. For example, when the file icon is displayed at the coordinates of the display screen corresponding to the coordinates indicated by the input position information, the “normal processing” is executed with the file as an object.

  Further, the shortcut process execution unit 64 may not perform the touch operation on the icon in order to execute the shortcut process. For example, the shortcut process execution unit 64 can execute a process such as “paste” even in a screen area where no icon is displayed.

(Processing flow of mobile phone)
Next, a processing flow of the mobile phone 200 will be described with reference to FIG. FIG. 6 is a flowchart showing the processing flow of the mobile phone 200.

  As a premise, it is assumed that the display control unit 11 displays a plurality of icons on the display unit 22, and the display coordinate information storage unit 53 stores the display coordinate information of the plurality of displayed icons. .

  First, the input position information acquisition unit 12 determines whether or not the user is performing a touch operation on the operation surface (S201). When it is determined that “the user does not perform a touch operation on the operation surface” (NO in S201), the input position information acquisition unit 12 waits for the user's touch operation (returns to S201). That is, the input position information acquisition unit 12 retries acquisition of input position information until the input position information can be acquired from the position input unit 21.

  On the other hand, if the input position information acquisition unit 12 determines that “the user is performing a touch operation on the operation surface” (YES in S201), the input position information is analyzed and the coordinates of the touch position on the operation surface are analyzed. And the acquired input position information is stored in the input position information storage unit 51 (S202).

  When receiving the notification that the input position information has been acquired from the input position information acquisition unit 12, the operation determination unit 63 turns on the power supply to the displacement measurement unit 62 (S203).

When the power supply is turned “ON”, the displacement measuring unit 62 measures the initial displacement (X, Y) = (X ₀ , Y ₀ ) of the mobile phone 200. Then, the displacement measuring unit 62 generates reference displacement information (X ₀ , Y ₀ ) from the measured displacement. The reference displacement information (X ₀ , Y ₀ ) generated by the displacement measuring unit 62 is stored in the displacement information storage unit 65 by the control unit 10 (S204).

Thereafter, the displacement measuring unit 62 further measures the displacement (X, Y) = (X ₁ , Y ₁ ) of the mobile phone 200 and generates measured displacement information (X ₁ , Y ₁ ) from the measured displacement. In the displacement measuring unit 62, the measured displacement information (X ₁ , Y ₁ ) is stored in the displacement information storage unit 65 by the control unit 10 (S205).

Subsequently, the motion determination unit 63 reads the reference displacement information (X ₀ , Y ₀ ) and the measured displacement information (X ₁ , Y ₁ ) from the displacement information storage unit 65, and the difference value ΔX = X ₁ −X _0. And a difference value ΔY = Y ₁ −Y ₀ is calculated (S206).

  Then, the operation determination unit 63 performs an operation determination to determine in which direction the mobile phone 200 has operated (S207).

  Here, the shortcut process execution unit 64 causes the input position information acquisition unit 12 to determine whether or not the user is still performing a touch operation on the operation surface (S208).

  When the input position information acquisition unit 12 determines that “the user does not perform a touch operation on the operation surface” (NO in S208), the shortcut processing execution unit 64 executes “normal processing” (S209). In such a case, the “normal processing” is executed in order to prevent malfunction due to sudden shaking or the like that is not intended by the user, as described above. Thereafter, the control unit 10 turns off the power supply to the displacement measuring unit 62 (S211), and returns to the first process (returns to S201).

  On the other hand, when the input position information acquisition unit 12 determines that “the user is performing a touch operation on the operation surface” (YES in S208), the shortcut processing execution unit 64 determines that the shortcut processing execution unit 64 performs an operation determination. The result of the operation determination is acquired from the unit 63, and the determination result is analyzed (S210).

  When the result of the operation determination by the operation determination unit 63 is “direction of arrow a”, the shortcut process execution unit 64 executes the process of “cut” assigned to “direction of arrow a” (S211). ).

  When the result of the operation determination by the operation determination unit 63 is “the direction of the arrow b”, the shortcut processing execution unit 64 executes the “paste” process assigned to the “direction of the arrow b” ( S212).

  If the result of the operation determination by the operation determination unit 63 is “direction of arrow c”, the shortcut process execution unit 64 executes the process of “copy” assigned to “direction of arrow c” (S213). ).

  If the result of the operation determination by the operation determination unit 63 is “the direction of the arrow d”, the shortcut process execution unit 64 executes the “delete” process assigned to the “direction of the arrow d” (S214). ).

  If the result of the motion determination by the motion determination unit 63 is “still state”, the user may be moving the mobile phone 200 from now on, so the displacement of the mobile phone 200 is detected again. Therefore, the process returns to S205.

  If the result of the operation determination by the operation determination unit 63 is “unknown”, it is necessary to detect the displacement of the mobile phone 200 again, and the process returns to S205.

  After the shortcut process execution unit 64 executes any one of S212 to S215, the control unit 10 turns off the power supply to the displacement measurement unit 62 (S215), and returns to the first process (S201). Back to).

(Flow of operation judgment processing)
Next, the flow of operation determination processing in the operation determination unit 63 will be described with reference to FIG. FIG. 7 is a flowchart showing the flow of operation determination processing in the operation determination unit 63.

  First, the motion determination unit 63 reads the displacement threshold information from the displacement threshold information storage unit 61, and determines whether the absolute value of ΔX calculated in S206 is larger than the X-axis threshold (S301).

  When the absolute value of ΔX is larger than the X-axis threshold value (YES in S301), the operation determination unit 63 determines whether the absolute value of ΔY calculated in S206 is larger than the Y-axis threshold value (S302).

Here, when the absolute value of ΔY is larger than the Y-axis threshold (YES in S302),
This is a case where there is a predetermined displacement or more in either the X-axis direction or the Y-axis direction. In this case, since the operation of the mobile phone 200 cannot be specified, the operation determination unit 63 returns “unknown” as a result of the operation determination (S306).

  On the other hand, if the absolute value of ΔY is equal to or smaller than the Y-axis threshold value (YES in S302), it means that mobile phone 200 has moved in the X-axis direction. Therefore, the operation determination unit 63 further determines whether or not the value of ΔX is a positive value (S303). If the value of ΔX is a positive value (YES in S303), it is determined that mobile phone 200 has operated in the direction of arrow d, and operation determination unit 63 returns “direction of arrow d” as the result of the operation determination. (S304). On the other hand, if the value of ΔX is a negative value (NO in S303), it is determined that mobile phone 200 has operated in the direction of arrow c, and operation determination unit 63 determines “direction of arrow c” as the result of the operation determination. Is returned (S305).

  When the absolute value of ΔX is equal to or smaller than the X-axis threshold value (YES in S301), the operation determination unit 63 determines whether the absolute value of ΔY calculated in S206 is larger than the Y-axis threshold value (S307).

  Here, when the absolute value of ΔY is larger than the Y-axis threshold value (YES in S307), it means that mobile phone 200 has operated in the Y-axis direction. Therefore, the operation determination unit 63 further determines whether or not the value of ΔY is a positive value (S308). If the value of ΔY is a positive value (YES in S308), it is determined that mobile phone 200 has operated in the direction of arrow b, and operation determination unit 63 returns “the direction of arrow b” as the result of the operation determination. (S310). On the other hand, if the value of ΔY is a negative value (NO in S308), it is determined that mobile phone 200 has operated in the direction of arrow a, and operation determination unit 63 determines “direction of arrow a” as the result of the operation determination. Is returned (S309).

  On the other hand, when the absolute value of ΔY is equal to or smaller than the Y-axis threshold value (NO in S307), it means that the mobile phone 200 is not operating more than a predetermined displacement. As a result, “stationary state” is returned (S311).

(Action / Effect)
Conventionally, a so-called shortcut key function for assigning a function to a specific key can be used for a keyboard input of a desktop PC. However, functions can be assigned to specific buttons even on mobile phones, etc., but when interlocking with the touch panel, it is necessary to operate specific buttons in addition to touch panel operations, making operation with one hand difficult. .

  On the other hand, the mobile phone 200 according to the present embodiment does not need to operate a specific button when realizing such a shortcut key function.

  As described above, the mobile phone 200 according to the present embodiment has an effect that three or more types of processing can be easily assigned as compared with the related art.

(Other variations)
The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  In addition, the processing flow described with reference to the flowcharts of FIGS. 3, 6, and 7 does not necessarily have to be executed in the order shown, and these are shown as examples only. Yes, the execution order can be changed as appropriate.

  Finally, each block of the mobile phones 100 and 200, in particular, the display control unit 11, the input position information acquisition unit 12, the operation determination unit 13, the click process execution unit 14, the icon specification unit 15, and the operation determination unit 63. In addition, the shortcut processing execution unit 64 may be configured by hardware logic, or may be realized by software using a CPU as follows.

  That is, the cellular phones 100 and 200 include a CPU (central processing unit) that executes instructions of a control program that realizes each function, a ROM (read only memory) that stores the program, and a RAM (random access memory) that expands the program. ), A storage device (recording medium) such as a memory for storing the program and various data. An object of the present invention is a recording medium in which program codes (execution format program, intermediate code program, source program) of a control program for mobile phones 100 and 200 which are software for realizing the functions described above are recorded so as to be readable by a computer. Can also be achieved by reading the program code recorded on the recording medium and executing it by the computer (or CPU or MPU).

  Examples of the recording medium include tapes such as magnetic tapes and cassette tapes, magnetic disks such as floppy (registered trademark) disks / hard disks, and disks including optical disks such as CD-ROM / MO / MD / DVD / CD-R. Card system such as IC card, IC card (including memory card) / optical card, or semiconductor memory system such as mask ROM / EPROM / EEPROM / flash ROM.

  Further, the mobile phones 100 and 200 may be configured to be connectable to a communication network, and the program code may be supplied via the communication network. The communication network is not particularly limited. For example, the Internet, intranet, extranet, LAN, ISDN, VAN, CATV communication network, virtual private network, telephone line network, mobile communication network, satellite communication. A net or the like is available. Also, the transmission medium constituting the communication network is not particularly limited. For example, even in the case of wired such as IEEE 1394, USB, power line carrier, cable TV line, telephone line, ADSL line, etc., infrared rays such as IrDA and remote control, Bluetooth ( (Registered trademark), 802.11 wireless, HDR, mobile phone network, satellite line, terrestrial digital network, and the like can also be used. The present invention can also be realized in the form of a computer data signal embedded in a carrier wave in which the program code is embodied by electronic transmission.

  The present invention can assign a plurality of processes to one position on the operation surface without impairing operability. Therefore, the present invention can be widely and suitably applied to improve operability in portable terminals such as PDAs (Personal Digital Assistants) and remote input systems.

DESCRIPTION OF SYMBOLS 10 Control part 11 Display control part 12 Input position information acquisition part 13 Motion determination part (exercise information acquisition means)
14 Click processing execution unit (processing device)
15 Icon identification part 20 Touch screen part 21 Position input part (position detection part, input device)
22 Display unit 30 Acceleration detection unit (motion detection unit)
DESCRIPTION OF SYMBOLS 50 Memory | storage part 51 Input position information memory | storage part 52 Operation | movement reference value memory | storage part 53 Display coordinate information memory | storage part 61 Displacement threshold value information memory | storage part 62 Displacement measurement part 63 Motion determination part 64 Shortcut process execution part 65 Displacement information memory | storage part 100 Mobile phone (input) System, portable terminal, input / output device)
200 Mobile phone (input system, mobile terminal, input / output device)

Claims (10)

In an input system including an input device including a position detection unit that detects an operation position operated on an operation surface, and a processing device that executes processing,
The input device is
A motion detector for detecting the motion of the input device;
When the position detection unit detects the operation position, it comprises exercise information acquisition means for acquiring exercise information related to the exercise detected by the exercise detection unit,
The input system according to claim 1, wherein the processing device executes processing according to the operation position detected by the position detection unit and the exercise information acquired by the exercise information acquisition means.   The input system according to claim 1, wherein the motion detection unit is an acceleration sensor. The acceleration sensor included in the motion detection unit detects acceleration in two directions,
3. The input system according to claim 2, wherein the processing device executes four types of processing according to four directions of a positive direction and a negative direction in each of two directions detected by the acceleration sensor. .   2. The input system according to claim 1, wherein the processing device executes processing assuming that there is no motion if the motion detected by the motion detection unit is less than or equal to a predetermined size. 3. .   The processing apparatus performs processing only when the position detection unit detects the operation position after the motion information acquisition unit acquires information on the motion. Item 5. The input system according to any one of Items 1 to 4.   A mobile terminal comprising the input system according to claim 1, wherein the processing device executes a processing function of the mobile terminal. A display unit having a display screen;
An input / output device comprising the input system according to any one of claims 1 to 5,
The input / output device, wherein the operation surface of the input device and the display screen are integrally formed, and the coordinates of the operation surface and the coordinates of the display screen are associated with each other.   An input system control program for operating the input system according to any one of claims 1 to 5, wherein the input system control program causes a computer to function as each of the above means.   A computer-readable recording medium on which the input system control program according to claim 8 is recorded. In an input system control method including an input device including a position detection unit that detects an operation position operated on an operation surface, and a processing device that executes processing,
When the position detection unit detects the operation position, the input device acquires movement information related to the movement detected by the movement detection unit that detects the movement of the input device,
The processing apparatus executes a process according to the operation position detected by the position detection unit and the acquired motion information.

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