KR20070001694A - Apparatus for controlling a display of a portable electronic equipment and a method the same - Google Patents

Abstract

A display control device of portable electronic equipment and a method thereof are provided to mount an inertial sensor on the portable electronic equipment to sense each movement of the electronic equipment, thereby controlling a pointer located on a display of the equipment as setting a menu indicated by the pointer. A sensor unit(130) senses spatial movement of a portable electronic equipment. A memory unit(120) stores data related to a spatial reference angle of equipment in order to set a reference right position in a space of the equipment. A controller(150) is applied with a signal sensed from the sensor unit(130) by hand-handling of the equipment based on the spatial reference angle, and changes a position of a pointer located on a display(140), then selects a predetermined menu indicated by the pointer.

Description

Display control apparatus and method of portable electronic device {APPARATUS FOR CONTROLLING A DISPLAY OF A PORTABLE ELECTRONIC EQUIPMENT AND A METHOD THE SAME}

1 is a block diagram schematically showing the configuration of a mobile phone according to an embodiment of the present invention;

2 is a view illustrating a relationship between an acceleration signal and an angle caused by the sensor unit of FIG. 1;

3 is a perspective view showing that the spatial reference angle is set in the mobile phone of FIG.

4 is a perspective view illustrating a case in which the mobile phone of FIG. 3 is inclined in space;

5 is a perspective view illustrating a case in which the mobile phone of FIG. 3 moves on a Z axis, and

6 is a flowchart illustrating an operation process of a mobile phone according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: mobile phone 110: key input unit

111: reference angle setting button 120: memory

130: sensor unit 131: first acceleration sensor

132: second acceleration sensor 133: third acceleration sensor

134: gravity sensor 140: display

141: pointer 150: control unit

151: communication module 152: reference angle setting module

153: tilt change recognition module 154: pointing position calculation module

155: menu setting module 160: signal processor

161: filter unit 162: converter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable electronic device, and more particularly, by installing an inertial sensor on the portable electronic device, whereby the pointer on the display of the portable electronic device is repositioned to select a menu indicated by the pointer. The present invention relates to a display control apparatus and method of the present invention.

In recent years, with the rapid development of wireless communication field and mobile phone, wireless communication users not only make phone calls whenever and wherever with their own mobile phone, but also wireless Internet service, text service, games, multimedia functions and additional services, PDA The use of mobile computing via mobile is also exploding.

In this situation, in order to use a function such as text input or menu selection by a mobile phone user, a user needs to continuously press a key because the input method through a button is used, and input efficiency is low. There was this.

In particular, a method of controlling a pointer indicating a menu through an auxiliary input device such as a mouse, which is widely used in a general desktop computer, has been very inconvenient to use because it cannot be used in a mobile phone.

In addition, in the case of the PDA, a pointer on the display is controlled by using an electronic pen, and a method of inputting or writing characters is an intuitive method using the electronic pen. However, in this case, input is performed by using both hands. Therefore, when both hands are not free or inconvenient, there was a problem that the use of PDA is very limited.

Accordingly, the present invention has been made to solve the above problems, and an object of the present invention is to mount an inertial sensor on the portable electronic device to detect each movement of the portable electronic device, thereby providing a pointer on the display of the portable electronic device. The present invention provides a display control apparatus and method for a portable electronic device for controlling a control and setting a menu indicated by a pointer.

An apparatus for controlling a display of a portable electronic device according to a first aspect of the present invention for achieving the above object, the sensor unit for detecting the movement of the portable electronic device in the space, the reference position on the space of the portable electronic device The display unit receives a signal sensed by the sensor unit by a memory unit for storing data about a spatial reference angle of the portable electronic device and a handheld of the portable electronic device based on the spatial reference angle to set the display. And a controller for repositioning the pointer and selecting a predetermined menu indicated by the pointer.

Preferably, the portable electronic device further comprises a key input unit for resetting data for the spatial reference angle stored in the memory unit.

Preferably, the sensor unit includes an inertial sensor for detecting at least one degree of freedom in any combination including degrees of freedom of translational and rotational motion of the portable electronic device, and a gravity sensor for sensing gravity of the portable electronic device. It is characterized by including.

Preferably, the inertial sensor is a first inertial sensor for detecting the movement of the horizontal axis of the portable electronic device, a second inertial sensor for detecting the movement of the vertical axis of the portable electronic device and the horizontal and vertical axis of the portable electronic device It characterized in that it comprises a third inertial sensor for detecting a direction perpendicular to the plane formed by.

Preferably, the first inertial sensor, the second inertial sensor, and the third inertial sensor change the position of the pointer on the display by signals detected by the first inertial sensor and the second inertial sensor, 3 sets or cancels a menu indicated by the pointer according to a signal sensed by the inertial sensor.

Preferably, the control unit is a reference angle setting module for setting the spatial reference angle of the portable electronic device by receiving the signal sensed by the sensor unit, by the handheld based on the spatial reference angle of the portable electronic device Executing a menu indicated by the tilt change recognition module for calculating a changed tilt value, a pointing position calculation module for changing the position of the pointer on the display by the calculated tilt value, and the pointer changed by the pointing position calculation module; And a menu setting module for canceling.

Preferably, the reference angle setting module is configured by the angle between the vector value of gravity measured by the gravity sensor and the vector value measured by the first inertial sensor and the vector value of gravity and the second inertial sensor. The angle formed by the measured vector value is set as a spatial reference angle.

Preferably, the inclination variation recognition module is an angle formed by the vector value of gravity measured by the gravity sensor and the vector value measured by the first inertial sensor handheld and the vector value of the gravity handheld The variation value is calculated due to the difference between the inclination by the angle formed by the vector value measured by the second inertial sensor and the spatial reference angle.

Preferably, the pointing position calculation module is configured to set an angle difference between the changed tilt value and the spatial reference angle as a parameter for changing the pointer position of the display unit.

Preferably, the menu setting module selects or cancels a menu according to a predetermined vector value measured by the third inertial sensor.

According to a second aspect of the present invention, there is provided a method for controlling a display of a portable electronic device, the method comprising: (a) storing a spatial reference angle of the portable electronic device in a memory, (b) the portable electronic device Handheld the device to apply a signal sensed by the sensor unit of the portable electronic device to the control unit; (c) calculating a result of comparing the angle formed by vectorization of the detected signal with the spatial reference angle; (d) repositioning the pointer of the display unit according to the result value; and (e) selecting or canceling a menu indicated by the pointer, or repositioning a position on the space of the handheld portable electronic device at the spatial reference angle. Characterized in that it comprises a step for setting.

Preferably, the step (b) is (b-1) detecting the movement and gravity of the horizontal and vertical axes by the sensor unit of the portable electronic device, (b-2) the detected signal is a filter of the signal processor And (b-3) converting the filtered signal by an AD converter of the signal processor.

Preferably, the step (c) includes (c-1) converting a signal received from the sensor unit into a vector value, and (c-2) extracting data for a spatial reference angle stored in the memo unit. And (c-3) comparing the vector value with the extracted data to calculate an angle difference.

Preferably, the step (d) is characterized in that the movement direction of the pointer is set according to the tilting direction of the portable electronic device due to the result value.

Preferably, the step (d) is characterized in that the inclination direction of the portable electronic device and the moving direction of the pointer is set equal or opposite.

Preferably, the step (d) is to calculate the degree of inclination of the portable electronic device due to the result value, characterized in that for setting the position of the pointer corresponding to the calculated value.

Preferably, the step (d) is to calculate the degree of inclination of the portable electronic device due to the result value, characterized in that the movement speed of the pointer is set in proportion to the calculated value.

Preferably, in order to select or cancel the menu in the step (e), (e-1a) detecting a predetermined menu setting signal in the sensor unit to set a menu indicated by the pointer; and (e- 2a) transmitting the command signal for selecting or canceling the menu to the display unit by applying the detected signal to the control unit.

Preferably, the step (e-1a) is characterized in that the sensor unit detects the movement in the vertical direction on the plane formed by the horizontal axis and the vertical axis of the portable electronic device.

Preferably, the vertical movement of the step (e-1a) is a series of handhelds in which a vertically downward vector value is converted into a vertically upward vector value or a vertically upward vector value is a vertically downward vector value. And selecting or canceling the menu by a series of changing handhelds.

Preferably, in order to reset the spatial reference angle in the step (e), (e-1b) resetting the spatial reference angle with the reference angle setting button in the key input unit while the portable electronic device is handheld. Generating a signal and (e-2b) setting a spatial reference angle in the controller to which the reset signal is applied and storing the signal in the memory.

Hereinafter, a preferred embodiment of a portable electronic device according to the present invention with reference to the accompanying drawings in detail as follows.

1 is a block diagram illustrating important functions of a mobile phone 100 according to an embodiment of the present invention.

As shown in FIG. 1, the mobile phone 100 is on the display of the mobile phone 100 due to a change in the sensed signal of the sensor unit 130 and the sensor unit 130 that detects movement in the space of the mobile phone 100. The display 140 in which the pointer 141 shown in FIG. 1 changes in position, and the signal detected from the sensor unit 130 to set a point on the display that is a reference point when the pointer 141 of the display 140 moves. Variation rate of the detected signal applied based on the data of the memory reference 120 and the spatial reference angle of the mobile phone 100 stored in the memory unit 120, the data stored for the spatial reference angle of the mobile phone 100 The controller 150 may include a controller 150 for changing the position of the pointer 141 of the display 140 and selecting a menu indicated by the pointer 141.

The sensor unit 130 is provided to detect the spatial movement of the mobile phone 100, by detecting one or more degrees of freedom in any movement combination including the degree of freedom of translational and rotational movement of the mobile phone 100 The mobile phone 100 is provided with an inertial sensor (not shown) for recognizing the degree of movement or the direction of movement.

In addition, the inertial sensor is preferably made of any one of an acceleration sensor, an angular velocity sensor, and an inclination sensor, and predetermined parameters that can be compared with the pointer 141 of the display 140 by grasping the movement of the mobile phone 100. If a sensor can provide a value, it may be possible to substitute another sensor.

In the present embodiment, among the various inertial sensors listed, the mobile phone 100 according to the present invention will be described in detail by employing the acceleration sensors 131 to 133.

The sensor unit 130 provided with the acceleration sensors 131 to 133 detects the movement of the horizontal axis (hereinafter referred to as 'X axis') of the display 140 of the mobile phone 100 in the spatial movement of the mobile phone 100. The first acceleration sensor 131 for detecting, the second acceleration sensor 132 for detecting the movement of the vertical axis (hereinafter referred to as the 'Y' axis) of the display 140 of the mobile phone 100, and the mobile phone 100 And a third acceleration sensor 133 for detecting an axis (hereinafter, referred to as 'Z axis') perpendicular to a plane formed of an X axis and a Y axis on the display.

Setting the X-axis, Y-axis, and Z-axis based on the display 140 of the mobile phone 100 is to facilitate the description of the present embodiment, and the sensor unit 130 embedded in the mobile phone 100. A predetermined spatial reference may be set in the process of setting or reading a signal applied from the sensor unit 130 by the controller 150. Therefore, the movement of the main body of the mobile phone 100 may be referred to.

In addition, the sensor unit 130 is not limited to being provided with three acceleration sensors 171, 172, and 173 along the X-axis, the Y-axis, and the Z-axis, and may sense spatial movement of the mobile phone 100. Depending on the various spatial coordinates present, the arrangement or the number of the installable accelerometers may vary.

In addition, the role of each of the acceleration sensors 131 to 133 for recognizing the movement of the mobile phone 100 by the signals detected by the acceleration sensors 131 to 133 is the first acceleration sensor 131 and the second acceleration sensor ( It is used as a parameter for repositioning the pointer 141 of the display 140 due to the vector value of the signal detected from the 132. When the vector value of the signal detected from the third acceleration sensor 133 is selected or canceled by a menu indicated by the pointer 141 which changes its position due to the first acceleration sensor 131 and the second acceleration sensor 132. It is preferably used as an initial setting signal.

In addition, the sensor unit 130 is provided with a gravity sensor 134 for measuring the gravity to grasp the movement in the space of the mobile phone 100 together with the acceleration sensors (131 to 133), acceleration sensors (131 to 133) It is preferable to set the pointer 141 of the display 140 to move the position by using the angle formed by the gravity sensor 134 as a basic parameter.

The signal processor 160 may include a filter unit 161 for removing noise of a sensing signal applied from the sensor unit 130, and an AD converter 165 for converting the analog signal filtered by the filter unit 161 into a digital signal. Is the default configuration.

The filter of the filter unit 161 is preferably provided with the number of each sensor of the sensor unit 130. Accordingly, a first filter (not shown) for filtering the signal sensed by the first acceleration sensor 131, a second filter (not shown) for filtering the signal detected by the second acceleration sensor 132, and A third filter (not shown) filters the signal sensed by the third acceleration sensor 133.

In addition, the filter unit 161 is preferably provided as a low-pass filter to remove noise generated when the user of the mobile phone 100 is shaken or used in a moving vehicle.

The sensing signals applied from the acceleration sensors 131 to 133 are respectively filtered and applied to the controller 150 through the AD converter 165. In addition, although the sensor unit 130 or the signal processing unit 160 mentioned above is a configuration that primarily senses the spatial movement of the mobile phone 100, it is a reasonable configuration to be embedded in the mobile phone 100, It may be provided as an external structure to enable connection through an external serial port.

In order to enable the controller 150 to recognize the spatial movement of the mobile phone 100 due to the detection signal by the acceleration sensors 131 to 133 of the sensor unit 130, the reference position of the mobile phone 100 is spaced. As it should be, the spatial reference angle of the mobile phone 100 set in the memory unit 120 is stored. The stored spatial reference angle can be basically set when the mobile phone 100 or the display 140 of the mobile phone 100 is placed horizontally, and the mobile phone 100 is operated by the user according to the user's convenience. It is the structure that can change and set the spatial reference angle.

The pointer 141 of the display 140 is controlled by a control command of the control unit 150 that has undergone a predetermined algorithm between the spatial reference angle stored in the memory unit 120 and the digital signal applied from the output terminal of the signal processor 160. Will change location.

The controller 150 calculates and processes a signal applied from the signal processor 160 to change the position of the pointer 141 of the display 140 and execute or cancel a menu indicated by the pointer 141. 152, a tilt variation recognition module 153, a pointing position calculation module 154, and a menu setting module 155.

The reference angle setting module 152 is used when the user arbitrarily sets the spatial reference angle in addition to the stored spatial reference angle by default in the memory unit 120. As shown in FIG. 2, the sensor unit 130 Is a diagram showing the angle formed by the vector value of the acceleration signal and the vector value of the gravity signal.

As shown in FIG. 2, when an acceleration signal detected from the first acceleration sensor 131 and the second acceleration sensor 132 of the sensor unit 130 is converted into a digital signal and applied to the reference angle setting module 152. It is computed by the acceleration value a _{x which} is a vector amount of an X-axis, and the acceleration value a _y which is a vector amount of a Y-axis. Similarly, the gravity signal sensed by the gravity sensor 174 is also calculated as the acceleration value g of the vector amount toward the G axis.

Next, an algorithm for comparing and calculating the calculated X-axis acceleration value (a _x ) and the Y-axis acceleration value (a _y ) and the gravity acceleration value (g) is performed. An angle θ _x formed between g) and the X-axis acceleration value a _x is set. In addition, the angle θ _y formed by the gravity acceleration value g and the Y-axis acceleration value a _y is also set, and these two angles θ _{x and} θ _y are set as spatial reference angles of the mobile phone 100. .

Further, since the spatial reference angle is not limited to the angles θ _{x and} θ _y formed between the X-axis acceleration value a _x and the Y-axis acceleration value a _y and the gravity acceleration value g, the X-axis acceleration The angle (θ _x, θ _z ) or the Y-axis acceleration value (a _y ) and the Z-axis acceleration value (a _z ) between the value (a _x ) and the Z-axis acceleration value (a _z ) and the gravity acceleration value (g) The angles θ _{y and} θ _{z of the} gravitational acceleration value g may be set as spatial reference angles.

The spatial reference angle set in this way is stored in the memory unit 120, and replaces the existing spatial reference angle already stored in the memory unit 120. FIG. 3 shows that the mobile phone 100 of FIG. 1 is located at a set spatial reference angle, and is shown before being handheld.

As shown in FIG. 3, the spatial coordinates are formed based on the display 140 of the mobile phone 100, and the vector value of the signal detected by the gravity sensor 134 and the acceleration of the X-axis based on the display 140. The angle formed by the vector value by the sensor 131 and the vector value of the signal detected by the gravity sensor 134 and the vector value by the acceleration sensor 132 on the Y-axis are set as the spatial reference angle.

In addition, although it is preferable to use it as a parameter for moving the pointer 141 of the display 140 by the angle between the gravity vector value and the vector value of the signal detected on the axis, the display 140 may be calculated by calculating the sum of the vectors. It will also be possible to move the pointer 141 of.

The tilt variation recognition module 153 calculates acceleration signals applied from the first acceleration sensor 131 and the second acceleration sensor 132 as acceleration values which are vector amounts. In addition, the gravity signal applied by the gravity sensor 134 of the sensor unit 130 is calculated as a gravity acceleration value which is a vector amount. Therefore, the angle formed by the X-axis acceleration value and the gravity acceleration value and the angle formed by the Y-axis acceleration value and the gravity acceleration value are compared with the spatial reference angle stored in the memory unit 120, and the tilt value changed by the spatial reference angle and the handheld. By recognizing the difference in the angle of the mobile phone 100 having a can determine the movement in the space of the mobile phone 100.

In addition, FIG. 4 is a diagram illustrating a case where the mobile phone 100 of FIG. 4 located at a spatial reference angle is handheld and tilted in space.

 As shown in FIG. 4, the mobile phone 100 inclined in space has an angle formed by a vector acceleration value by the X-axis acceleration sensor 131 and a vector acceleration value by the gravity sensor 134, and a Y-axis acceleration sensor ( Due to the angle formed by the vector acceleration value by the 132 and the vector acceleration value by the gravity sensor 134, the tilt variation recognition module 153 compares the spatial reference angle stored in the memory to the spatial reference angle of the mobile phone 100. Measure the tilt.

In addition, the pointing position calculation module 154 receives the mobile phone position change signal from the tilt change recognition module 153 for recognizing the tilt value changed based on the spatial reference angle from the tilt change recognition module 153 and displays the display 140. It is provided to change the position of the pointer 141 at. Here, the mobile phone position change signal may be set in various ways, but sets the angle difference based on the difference between the spatial reference angle and the tilt value changed by the handheld of the mobile phone 100 as a basic parameter for changing the position of the pointer 141. It is desirable to.

Here, the relationship between the difference in angle and the movement of the pointer 141 may be variously set similarly to the position change signal of the mobile phone 100 mentioned above. The tilting direction of the mobile phone 100 and the moving direction of the pointer 141 may be the same or may be opposite directions. The position of the pointer 141 may be set to an absolute value by the degree of inclination, and the speed at which the pointer 141 moves may be set according to the degree of inclination of the mobile phone 100.

The menu setting module 155 is a device for setting whether or not to select or cancel a menu indicated by the pointer 141 of the display 140 by being processed by the pointing position calculation module 154. The acceleration signal detected by the third acceleration sensor 133 for detecting the movement of the mobile phone 100 on the Z axis may be applied as a menu setting signal.

FIG. 5 is a perspective view illustrating a case in which the user moves on the Z axis to set a menu indicated by the pointer 141 of the display 140 of the mobile phone of FIG. 3.

As illustrated in FIG. 5, the Z-axis acceleration sensor 173 detects this movement due to the operation of lowering the mobile phone 100 down along the Z axis and then up the signal, thereby detecting a signal detected by the menu setting module 155. Is applied. In addition, the menu setting module 155 selects a menu due to this signal, and the acceleration sensor 133 of the Z axis detects this movement due to the operation of raising and lowering the mobile phone 100 along the Z axis. . Therefore, the detected signal is applied to the menu setting module 155. Here, the menu setting module 155 preferably generates a command signal for canceling the menu indicated by this signal. In addition, this setting can be made in various ways from the viewpoint of those skilled in the art.

In addition, the key input unit 110 is for changing data corresponding to the spatial reference angle stored in the memory unit 120. That is, when the spatial position of the mobile phone 100 is to be reset to the spatial reference angle according to the user's convenience, the memory unit 120 is stored using the reference angle setting button 111 located in the external housing of the mobile phone 100. Reset the spatial reference angle.

Hereinafter, the operation of the portable electronic device according to the present invention with reference to the accompanying drawings in more detail as follows.

6 is a flowchart illustrating a method of operating the mobile phone 100 according to an embodiment of the present invention.

The user changes the position on the space of the mobile phone 100 by hand tilting the mobile phone 100 in which the spatial reference angle is initialized. (S100, S102)

The acceleration signal detected by the first acceleration sensor 131 on the X axis and the second acceleration sensor 132 on the Y axis and the gravity sensor 134 for measuring gravity due to the tilting handheld that the user arbitrarily moves is a signal processor. The filter is filtered through the filter unit 161 of 160 and noise is removed. The analog signal from which the noise is removed is converted into a digital signal by the AD converter 164 and applied to the controller 150. (S104, S106)

The signal applied as described above is calculated as an acceleration value having a vector amount in the tilt variation recognition module 153, and the angle between the acceleration value of the X axis and the gravity acceleration value and the angle between the acceleration value and the gravity acceleration value of the Y axis are the memory unit 120. The calculated slope value is calculated by comparing with the spatial reference angle stored in. The tilt angle and direction of the mobile phone 100 are recognized due to the changed tilt value, and a signal for a difference in angle corresponding to the changed tilt value is applied to the pointing position calculation module 154.

The pointer position calculation module 154 receives a signal due to the difference in angle and utilizes the pointer 141 located on the display 140 as a basic parameter for changing the position, thereby depending on the degree of tilt handheld of the mobile phone 100. An operation algorithm for changing the position of operation 141 is performed (S110).

Thus, by entering the mode for executing the menu indicated by the pointer 141 of the display 140 by the handheld of the mobile phone 100 or reset the spatial reference angle which is a reference for the spatial movement of the mobile phone 100. (S112)

First, when entering the mode for setting the menu indicated by the pointer 141 of the display 140 while reaching the pointing position calculation module 154, the mobile phone 100 changes the spatial position along the Z axis to The acceleration signal detected by the third acceleration sensor 133 is filtered and applied to the menu setting module 155 via the AD converter 164.

The menu setting module 155 calculates the applied acceleration signal as an acceleration value having a vector amount to give a control command for selecting or canceling a menu indicated by the pointer 141 on the display 140. In order to generate a control signal for substantially selecting or canceling a menu according to one method, the mobile phone 100 is handheld up and down along the Z axis, and a third acceleration sensor ( 133 detects this and applies the sensed acceleration signal to the menu setting module 155, and the applied signal is converted into an acceleration value having a vector amount to select and execute a menu indicated by the pointer 141.

In addition, when the handheld of the mobile phone 100 is lowered down along the Z axis and then lifted up, the third acceleration sensor 133 detects this and the detected acceleration signal is applied to the menu setting module 155. The applied signal is converted into an acceleration value having a vector amount to give an execution command for canceling the menu indicated by the pointer 141. (S118 to S122)

Due to the menu execution command as described above, the event corresponding to the menu is executed or canceled (S124).

In addition, if the user does not enter the menu setting mode from above, but enters the mode for resetting the space reference angle, the mobile phone 100 is changed to the pointing position calculation module 154 and the new space according to the user's convenience. By setting the reference angle, the user presses the reference angle setting button 111 located in the external housing of the mobile phone 100 to set the spatial reference angle. The set spatial reference angle replaces the data of the existing spatial reference angle stored in the memory, and becomes a reference for the user to handhel the mobile phone later (S112 to S116).

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below. I can understand that you can.

Therefore, the present invention includes an inertial sensor capable of sensing the movement of the portable electronic device in space, and implements a control unit having a variation signal detected from the inertial sensor as a basic parameter by handheld of the portable electronic device. By allowing the position of the pointer on the display to be changed, there is an advantage that the user can use a variety of input methods by assisting the interface using a button or an electronic pen-based interface of the existing portable electronic device.

In addition, when a user of a portable electronic device is difficult to execute a predetermined menu by pressing a button, or when both hands must be used when an electronic pen is used, all control operations can be performed only by hand-held operation. There is this.

Claims (28)

An apparatus for controlling a display of a portable electronic device, Sensor unit for detecting the movement in the space of the portable electronic device; A memory unit for storing data regarding a spatial reference angle of the portable electronic device to set a reference position on the space of the portable electronic device; And A control unit for changing the position of the pointer of the display by receiving a signal sensed by the sensor unit by the handheld of the portable electronic device based on the spatial reference angle, and selecting a predetermined menu indicated by the pointer; Display control device for a portable electronic device comprising a. According to claim 1, The portable electronic device, And a key input unit for resetting data for the spatial reference angle stored in the memory unit. The method of claim 1, wherein the sensor unit, And an inertial sensor for detecting at least one degree of freedom in any combination including degrees of freedom of translational and rotational motion of the portable electronic device, and a gravity sensor for sensing gravity of the portable electronic device. Display control of electronic equipment. The method of claim 3, wherein the inertial sensor, Display control device of a portable electronic device, characterized in that any one of an acceleration sensor, an angular velocity sensor and a tilt sensor. The method of claim 3, wherein the inertial sensor, A first inertial sensor for detecting a movement of a horizontal axis of the portable electronic device; A second inertial sensor for detecting movement of a vertical axis of the portable electronic device; And And a third inertial sensor for detecting a direction perpendicular to a plane formed by a horizontal axis and a vertical axis of the portable electronic device. The method of claim 5, wherein the two inertial sensors of the first inertial sensor, the second inertial sensor and the third inertial sensor, And a sensing signal for changing a position of the pointer on the display. The method of claim 5, wherein the inertial sensor of any one of the first inertial sensor, the second inertial sensor and the third inertial sensor, And a detection signal for setting or canceling a menu indicated by the pointer on the display. The method of claim 5, wherein the first inertial sensor, the second inertial sensor and the third inertial sensor, Reposition the pointer on the display according to the signals sensed by the first inertial sensor and the second inertial sensor, and set or cancel a menu indicated by the pointer according to the signal sensed by the third inertial sensor. Display control device of a portable electronic device. The method of claim 1, wherein the control unit, A reference angle setting module for setting a spatial reference angle of the portable electronic device by receiving a signal sensed by the sensor unit; A tilt variation recognition module for calculating a changed tilt value of the portable electronic device based on the spatial reference angle by handheld; A pointing position calculation module for changing the position of the pointer on the display by the calculated tilt value; And And a menu setting module for executing or canceling a menu indicated by the pointer changed by the pointing position calculation module. The method of claim 5 or 9, wherein the control unit, Portable electronics, characterized in that for processing the signal received from the first inertial sensor, the second inertial sensor and the gravity sensor in the reference angle setting module, the tilt change recognition module, and the pointing position calculation module. Display control device. The method of claim 5 or 9, wherein the reference angle setting module, The spatial reference is an angle formed between the vector value of gravity measured by the gravity sensor and the vector value measured by the first inertial sensor, and the angle between the vector value of gravity and the vector value measured by the second inertial sensor. Display control device for a portable electronic device, characterized in that the setting at an angle. 10. The method of claim 5 or 9, wherein the tilt variation recognition module, An angle between a vector value of gravity measured by the gravity sensor and a vector value measured by the first inertial sensor and a vector value measured by the vector value of gravity and the second inertial sensor handheld Display control device for a portable electronic device, characterized in that for calculating the variation value due to the difference between the inclination and the spatial reference angle. The method of claim 5 or 9, wherein the pointing position calculation module, And an angle difference between the changed inclination value and the spatial reference angle is set as a parameter for changing the pointer position of the display. The method of claim 5 or 9, wherein the menu setting module, And selecting or canceling a menu according to a predetermined vector value measured by the third inertial sensor. The method of claim 1, wherein the sensor unit, A filter for removing noise detected by the sensor unit; And And a signal processing unit including an AD converter for converting the analog signal passed through the filter into a digital signal. The method of claim 15, wherein the filter, Display control device for a portable electronic device, characterized in that provided with a low pass filter. The method of claim 1, wherein the sensor unit, Display control device of the portable electronic device, characterized in that built in the portable electronic device, or connected to the external serial port of the portable electronic device. A method for controlling a display of a portable electronic device according to claim 1, (a) storing a spatial reference angle of the portable electronic device in a memory; (b) handheld the portable electronic device and applying a signal detected by a sensor unit of the portable electronic device to a controller; (c) calculating a result of comparing the angle formed by vectorizing the detected signal with the spatial reference angle; (d) repositioning the pointer of the display according to the result value; And (e) selecting or canceling a menu indicated by the pointer, or resetting a position on the space of the handheld portable electronic device to the spatial reference angle. Way. The method of claim 18, wherein step (b), (b-1) detecting the movement and gravity of the horizontal and vertical axes by the sensor unit of the portable electronic device; (b-2) removing the noise by the detected signal from the filter of the signal processor; And and (b-3) converting the filtered signal by an AD converter of the signal processing unit. The method of claim 18, wherein step (c) is (c-1) converting the signal received from the sensor unit into a vector value; (c-2) extracting data on a spatial reference angle stored in the memo unit; And and (c-3) comparing the vector value with the extracted data and calculating a difference between angles. The method of claim 18, wherein step (d) The display control method of the portable electronic device, characterized in that the movement direction of the pointer is set according to the tilting direction of the portable electronic device due to the result value. The method of claim 21, wherein step (d) The display control method of the portable electronic device, characterized in that the inclination direction of the portable electronic device and the moving direction of the pointer is set equal or opposite. The method of claim 18, wherein step (d) The display control method of the portable electronic device, characterized in that for calculating the inclination degree of the portable electronic device by the result value, and setting the position of the pointer corresponding to the calculated value. The method of claim 18, wherein step (d) The display control method of the portable electronic device, characterized in that for calculating the inclination degree of the portable electronic device, the moving speed of the pointer is set in proportion to the calculated value. The method of claim 18, wherein in order to select or cancel the menu in the step (e), (e-1a) detecting a predetermined menu setting signal in the sensor unit to set a menu indicated by the pointer; and (e-2a) transmitting the command signal for selecting or canceling the menu to the display by applying the sensed signal to the controller. The method of claim 25, wherein step (e-1a), And the sensor unit detects a movement in a direction perpendicular to a plane formed by a horizontal axis and a vertical axis of the portable electronic device. The method of claim 26, wherein the vertical movement of the step (e-1a), Selecting or canceling the menu by a series of handhelds in which the vertically downward vector value is converted into a vertically upward vector value or a series of handhelds in which the vertically upward vector value is converted into a vertically downward vector value. Display control method of portable electronic device. 19. The method of claim 18, wherein in order to reset the spatial reference angle in (e), (e-1b) generating a reset signal of the spatial reference angle with a reference angle setting button in a key input unit in a state where the portable electronic device is handheld; and and (e-2b) setting a spatial reference angle in the controller to which the reset signal is applied and storing the spatial reference angle in the memory.

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