KR100951419B1 - Three dimension mouse - Google Patents

Abstract

Three-dimensional mouse according to the present invention, the inner space is formed a housing; A mouse body mounted in the inner space; A side sensing unit configured to sense a contact pressure between the mouse main body and the housing when a lateral external force is applied to the mouse main body, thereby generating X and Y axis movement signals of the mouse cursor; And a lift detecting unit for detecting a contact pressure between the mouse main body and the housing when an external force is applied to the mouse main body and generating a Z-axis movement signal of the mouse cursor.

Using the three-dimensional mouse according to the present invention, since the mouse cursor can be moved not only in the X, Y axis but also in the Z axis by simply moving the mouse body without pressing a separate button, the mouse cursor can be moved within the virtual space. There is an advantage that the operation of moving in three dimensions becomes very simple.

Mouse 3D Z Axis Mouse Cursor Moving Stereo

Description

Three-dimensional mouse}

The present invention relates to a three-dimensional mouse configured to move the mouse cursor in three axial directions, that is, three-dimensionally.

A user input and output device for a user interface is used in an information processing system or a control system such as a computer. A keyboard, a mouse, a touch screen, etc. are mainly used as the user input device. As an output device, a monitor screen, a printer, and the like are widely used.

Among the above-mentioned input devices, the mouse is most widely used. In the conventional mouse, the mouse cursor can be moved only in the plane of the monitor screen, that is, the mouse cursor only moves in a two-dimensional area consisting of X-axis coordinates and Y-axis coordinates. It is configured to be.

At this time, due to the development of computer graphics, three-dimensional three-dimensional graphics, that is, 3D graphics, are used more widely than two-dimensional flat graphics in various games as well as general works on computers. The conventional mouse, which can only move in dimensions, has a problem in that the mouse cursor cannot be moved in three dimensions on a 3D graphic.

In order to solve the above problems, various methods for moving the mouse cursor in the Z axis direction as well as the X axis and the Y axis have been proposed in various ways. As a method, there is a method of moving a mouse while pressing a specific key of the keyboard, a method of pressing a separate button installed on the mouse, and the like.

However, as described above, the method of moving the mouse cursor in the Z-axis direction is completely different from the method of moving the mouse cursor in the X-axis direction or the Y-axis direction, and thus there is a disadvantage in that the operation is inconvenient.

In addition, the method of moving the mouse cursor in the Z-axis direction as described above, the user can not control the speed of the mouse cursor moving in the Z-axis, there is a lot of inconvenience in use.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide a three-dimensional mouse configured to easily move the mouse cursor to the Z axis as well as the X, Y axis without pressing a separate button. have.

Three-dimensional mouse according to the present invention for achieving the above object,

A housing in which an inner space is formed;

A mouse body mounted in the inner space;

A side sensing unit configured to sense a contact pressure between the mouse main body and the housing when a lateral external force is applied to the mouse main body, thereby generating X and Y axis movement signals of the mouse cursor; And

A lift detecting unit detecting a contact pressure between the mouse main body and the housing when an external force is applied to the mouse main body to generate a Z-axis movement signal of the mouse cursor;

It is configured to include.

The lateral detection unit generates a mouse cursor movement signal so that the movement speed of the mouse cursor can be changed according to the contact pressure magnitude between the mouse body and the housing.

The lateral detection unit is provided on any one of a lateral outer surface of the mouse body and a lateral inner surface of the inner space.

A housing in which an inner space is formed;

A mouse body mounted in the inner space;

A movement detecting unit which senses movement of the housing and generates X and Y axis movement signals of a mouse cursor; And

A lift detecting unit detecting a contact pressure between the mouse main body and the housing when an external force is applied to the mouse main body to generate a Z-axis movement signal of the mouse cursor;

It is configured to include.

The movement detecting unit is provided on the bottom of the housing.

The lifting detecting unit includes a rising detecting unit and a falling detecting unit detecting the rising and falling of the mouse body, and configured to move the mouse cursor in the opposite direction according to the rising and falling of the mouse body.

The rising detection unit is provided on any one of the ceiling surface of the inner space and the upper surface of the mouse body, the falling detection unit is provided on any one of the bottom surface of the inner space and the bottom of the mouse body.

A recessed groove is formed at the side of the mouse body, and a protruding end inserted into the recessed groove is formed in the inner space of the housing.

  The rising detection part is provided on any one surface of the bottom surface of the projecting end and the bottom surface of the concave groove, the lower detection part is provided on any one surface of the upper surface of the projecting end and the ceiling surface of the concave groove.

The lifting detecting unit generates a mouse cursor movement signal so that the movement speed of the mouse cursor can be changed according to the contact pressure between the mouse body and the housing.

When contact pressure is simultaneously generated in the lateral sensing unit and the elevating sensing unit, a mouse cursor movement signal is generated such that the mouse cursor is moved in the direction in which the mouse cursor movement vectors in the X, Y, and Z axes are combined.

It further includes elastic means for supporting the position of the mouse body so that the mouse cursor movement signal is not generated unless an external force is applied.

The elastic means is provided between the inner surface of the inner space and the outer surface of the mouse body.

The mouse body has a handle portion protruding outward of the housing.

The handle portion extends laterally to cover a portion of the upper surface of the housing,

The lifting detecting unit includes a rising detecting unit and a falling detecting unit detecting a rising and falling of the mouse body and configured to move the mouse cursor in the opposite direction according to the rising and falling of the mouse body. It is provided on any one of the ceiling surface of the inner space and the upper surface of the mouse body, the lowering detection unit is provided on any one of the lower surface of the handle portion and the upper surface of the housing.

The cover may further include a cover covering a space between a bottom surface of the handle part and an upper surface of the housing so that the falling detection part is not exposed to the outside.

The handle portion is formed with an insertion groove into which the user's finger can be inserted.

The handle portion is formed in the side of the recess in which the user's finger can be seated.

The handle portion is formed in the shape of a joystick.

The handle part is formed in a ring shape into which a user's finger can be inserted.

It further includes a rotation key for converting the viewpoint of the screen on which the mouse cursor is located.

A housing in which an inner space is formed;

A mouse body mounted in the inner space;

A side sensing unit configured to sense a contact pressure between the mouse main body and the housing when a lateral external force is applied to the mouse main body, thereby generating X and Y axis movement signals of the mouse cursor; And

A lift detecting unit configured to sense a contact pressure between the mouse body and the housing when an external force is applied to the mouse body to generate a signal to enlarge or reduce the screen, or to generate a signal to scroll the screen in both directions;

It is configured to include.

Using the three-dimensional mouse according to the present invention, since the mouse cursor can be moved not only in the X, Y axis but also in the Z axis by simply moving the mouse body without pressing a separate button, the mouse cursor can be moved within the virtual space. There is an advantage that the operation of moving in three dimensions becomes very simple.

Hereinafter, an embodiment of a three-dimensional mouse according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a three-dimensional mouse according to the present invention, Figure 2 is a cross-sectional perspective view of a housing included in the three-dimensional mouse according to the present invention, Figure 3 is a perspective view of a mouse body included in the three-dimensional mouse according to the present invention 4 is a cross-sectional view of a three-dimensional mouse according to the present invention.

As shown in FIGS. 1 to 3, the three-dimensional mouse according to the present invention includes a housing 100 in which an inner space 110 is formed, and a lower portion of the mouse body 200 mounted in the inner space 110. And, the side detection unit 320 for detecting when the external force is applied to the mouse body 200 in the lateral direction, that is, the front and rear direction to generate a mouse cursor movement signal to move the mouse cursor in the X-axis and Y-axis direction And, the lifting detection unit for detecting when the external force is applied to the mouse main body 200 generates a mouse cursor movement signal to move the mouse cursor in the Z-axis direction perpendicular to the X-axis and Y-axis ( 310).

At this time, the through hole 120 is formed on the upper side of the housing 100, and the mouse body 200 protrudes to the outside of the housing 100 (upper side in the present embodiment) through the through hole 120. The handle portion 210 is provided. In addition, the mouse main body 200 has a horizontal cross-sectional area of the portion inserted into the housing 100 is larger than the through-hole 120, and is formed to contact the ceiling surface of the housing 100 when raised.

Therefore, when the user grasps the handle portion 210 protruding upwards of the housing 100 by hand and moves it to the front and rear and left and right directions, the mouse main body 200 moves to move closer to the lateral inner wall of the inner space 110. When the handle 210 is moved in the vertical direction, the mouse body 200 is moved so that the upper surface is closer to the ceiling surface of the inner space 110 or the bottom surface is closer to the bottom surface of the inner space 110.

The side sensing unit 320 is a component for sensing whether an external force is applied to the mouse body 200 in the front, rear, left and right directions, and generates a mouse cursor movement signal when a contact pressure is generated by contacting another object. It is configured so that, when the mouse body 200 is moved in the front and rear and left and right directions, the mouse body 200 and the housing 100 is mounted to a portion in contact with each other.

Therefore, when the external force toward the left side is applied to the handle portion 210 in the state shown in FIG. 4 and the mouse body 200 located in the internal space 110 of the housing 100 moves to the left side, the side detection The unit 320 generates contact pressure by contacting a side of the outer circumferential surface of the mouse body 200 to the side wall of the inner space 110, thereby generating a mouse cursor movement signal for moving the mouse cursor to the left. Occurs. At this time, the side detection unit 320 for generating a mouse cursor movement signal as the contact pressure is generated, since it is substantially the same as the pressure sensor used in the contact type signal generator, the detailed configuration and operation description thereof Omit it.

In this embodiment, only the case where the side sensing unit 320 is mounted on the outer circumferential surface of the mouse body 200, but the side sensing unit 320 is generated when the external force is applied to the mouse body 200 As long as the contact pressure between the mouse body 200 and the housing 100 can be measured, it can be mounted on any part. For example, the side sensing unit 320 may be mounted on an inner wall of the inner space 110 of the housing 100.

In addition, the side detection unit 320 is a mouse to increase or decrease the movement speed of the mouse cursor according to the magnitude of the external force applied to the mouse main body 200, that is, the contact pressure between the mouse main body 200 and the housing 100. It is preferable that the structure is configured to generate a cursor movement signal. As described above, when the side sensing unit 320 is configured to change the moving speed of the mouse cursor, the user pushes the mouse body 200 firmly and moves the mouse cursor slowly when the user wants to move the mouse cursor quickly. When the mouse body 200 is weakly pushed, there is an advantage that the movement of the mouse cursor can be freely adjusted.

In addition, even if the mouse body 200 is moved in any direction in the horizontal direction other than the front and rear and left and right directions, such as right front and left rear, so that the mouse body 200 can accurately detect the moving direction of the mouse body 200, The lateral outer surface of the portion inserted into the housing 100 is formed in a curved shape, that is, a cylindrical or disk shape, the side sensing unit 320 is provided over the outer circumference of the outer peripheral surface of the mouse body 200 desirable.

The lifting detecting unit 310 is a component for detecting whether an external force is applied to the mouse body 200 in the up and down direction, and generates a mouse cursor movement signal when contact pressure is generated by contacting with another object. It is composed of a rising detection unit 312 for detecting the rise of the mouse body 200 and the falling detection unit 314 for detecting the falling of the mouse body 200.

The lift detecting unit 312 is a portion where the mouse main body 200 and the housing 100 are in contact with each other when the mouse main body 200 is moved upward, that is, of the housing 100 of the mouse main body 200. It is mounted on the upper surface of the portion inserted into the internal space 110, the lowering detection unit 314 is the mouse body 200 and the housing 100 is in contact with each other when the mouse body 200 is moved upwards That is, the mouse body 200 is mounted on the bottom surface of the part inserted into the internal space 110 of the housing 100.

In the present embodiment, only the case where the rising detection unit 312 and the falling detection unit 314 is mounted on the upper and lower surfaces of the mouse body 200, respectively, when the mouse body 200 is raised and lowered If the contact pressure can be generated may be mounted on various parts such as the ceiling surface or the bottom surface of the internal space (110). In addition, the lifting detection unit 310 is similar to the side detection unit 320, the mouse cursor to change the movement speed of the mouse cursor in the Z direction according to the magnitude of the contact pressure generated as the mouse main body 200 is raised and lowered. It is preferable that the structure is configured to generate a movement signal.

In addition, when contact pressures are simultaneously generated in the lateral sensing unit 310 and the elevating sensing unit 320, the lateral sensing unit 310 and the elevating sensing unit 320 may be formed in the X-axis, Y-axis, and Z-axis directions. A mouse cursor movement signal is generated such that the mouse cursor is moved in the direction in which the mouse cursor movement vectors are added.

For example, when a user does not lift or lower the mouse body 200 but simply pushes the mouse body 200 forward, that is, the lifting detection unit 320 does not generate contact pressure. When contact pressure is generated only in the side sensing unit 310, the mouse cursor moves in a diagonal direction between the X and Y axes on a plane formed by the X and Y axes. In addition, when the user lifts the mouse body 200 and pushes it to the right front, that is, when a contact pressure is generated in both the side sensing unit 310 and the lifting detecting unit 320, the mouse cursor and the X axis It moves in the diagonal direction of space formed between the Y axis and the Z axis.

At this time, if the contact pressures in the X-axis, Y-axis, and Z-axis are all equal, the mouse cursor moves in a direction exactly 45 degrees to the X-, Y-, and Z-axes, respectively. When the contact pressure in any one of the axial directions is increased, the mouse cursor moves in a direction biased toward the axis where the contact pressure is large.

In the present exemplary embodiment, the lifting detecting unit 310 and the side sensing unit 320 are initially spaced apart from the housing 100, and then move by an external force to generate a mouse cursor movement signal at the point of contact with the housing 100. Although configured, the elevation detecting unit 310 and the side sensing unit 320 may be configured to maintain a contact with the housing 100 from the beginning.

That is, the lifting detecting unit 310 and the side sensing unit 320 are configured to generate a mouse cursor movement signal when the contact pressure is raised above the reference value by external force after being initially in contact with the housing 100. May be In this case, the contact pressure reference value at which the mouse cursor movement signal is generated may be variously set according to various conditions.

When the external force applied to the handle portion 210 is released (that is, the user no longer contacts the handle portion 210) in a state in which contact pressure is generated in the side sensing unit 320 or the lifting detecting unit 310. When no force is applied), if the contact pressure generated in the lateral sensing unit 320 and the elevating sensing unit 310 is maintained as it is, there is a problem that the mouse cursor continuously moves regardless of the intention of the user. Accordingly, in the 3D mouse according to the present invention, the mouse cursor movement signal is not generated unless an external force is applied, that is, the side sensing unit 320 or the lifting detecting unit 310 is spaced apart from the housing 100. It further includes an elastic means 400 for returning the mouse body 200 to the initial state.

The elastic means 400 is an inner surface of the inner space 110 and the mouse so that the mouse body 200 can maintain a floating state in the inner space 110 of the housing 100 as shown in FIG. It is preferable that a plurality is provided between the outer surfaces of the main body 200. In addition, the elastic means 400 may be applied to the coupling coil spring, one end is coupled to the inner surface of the inner space 110 and the other end is coupled to the outer surface of the mouse body 200 as shown in this embodiment It may also be replaced by pin springs, leaf springs or other elastic materials.

5 shows an example of use of a three-dimensional mouse according to the present invention.

As mentioned above, the rising detection unit 312 and the falling detection unit 314 are configured to move the mouse cursor in the opposite direction as the mouse body 200 rises and falls.

Accordingly, when the user presses the handle 210 downward, the mouse main body 200 is lowered and a contact pressure is generated on the lowering detection part 314 mounted on the bottom of the mouse main body 200. As described above, the mouse cursor 30 moves in the -Z axis direction on the virtual space 20 of the monitor 10. On the contrary, when the user lifts up the handle part 210 and the contact pressure is generated in the lift detecting part 312, the mouse cursor 30 moves in the + Z axis direction on the virtual space 20 of the monitor 10. do.

At this time, if the handle portion 210 is moved only in the horizontal direction such as front and rear, left and right without pressing down or lifting up, the mouse cursor is on the virtual space 20 of the monitor 10 as in the case of using a general mouse. It will only move in the X- and Y-axis directions.

As described above, when the three-dimensional mouse according to the present invention is used, the mouse cursor can be freely moved in the X, Y, and Z axes only by applying a force to the handle portion 210 without pressing a separate key. There is an advantage that the mouse cursor can be moved in three dimensions in the virtual space.

6 and 7 are cross-sectional views of a third embodiment and a third embodiment of a three-dimensional mouse according to the present invention.

When the handle portion 210 is formed in a shape extending in the lateral direction to cover a portion of the upper surface of the housing 100, that is, the horizontal cross-sectional area larger than the through-hole 120 formed in the housing 100, the As illustrated in FIG. 6, the falling detection part 314 may be mounted on the bottom surface of the handle part 210 or the top surface of the housing 100.

At this time, when the falling detection unit 314 is exposed to the outside as it is, there is a fear that the falling detection unit 314 is easily damaged by an external foreign matter or the like. Therefore, the three-dimensional mouse according to the present invention, as shown in Figure 7 so that the falling detection unit 314 is not exposed to the outside between the bottom surface of the handle portion 210 and the upper surface of the housing 100 The cover 130 may be further provided to cover the space.

8 is a cross-sectional view of a third embodiment of a three-dimensional mouse according to the present invention.

The three-dimensional mouse according to the present invention may be configured such that the rising detection unit 312 and the falling detection unit 314 are located inside the mouse body 200.

That is, as shown in Figure 8, the mouth groove 202 is formed on the side of the mouse main body 200, the protrusion is inserted into the recess groove 202 in the inner space 140 of the housing 100. When the end 140 is formed, the rising detection unit 312 is provided on the bottom surface of the recess groove 202, the falling detection unit 314 is provided on the ceiling surface of the recess groove (202). Can be configured.

As such, when the rising detecting unit 312 and the falling detecting unit 314 are provided inside the mouse main body 200, the rising detecting unit 312 and the falling detecting unit 314 may be damaged by an external impact. It is reduced, there is an advantage that it is easier to mount other components, such as elastic means 400, etc. on the outer surface of the mouse body 200.

In this case, the rising detection unit 312 and the falling detection unit 314 may be provided on the bottom and the upper surface of the protruding end 140, respectively.

6 to 8, when there is no need to mount the falling detection unit 314 on the bottom of the mouse body 200, the elastic means 400 to the lower surface of the mouse body 200 Since the dog body can be mounted, the operation of returning the mouse body 200 to the original position when the external force is released can be made more stably, and the durability of the elastic means 400 can be improved.

9 is a cross-sectional view of a fifth embodiment of a three-dimensional mouse according to the present invention.

3D mouse according to the present invention, the structure for moving the mouse cursor on the X-axis and Y-axis is configured in the same manner as a conventional mouse, and configured to be further provided with only a structure for moving the mouse cursor on the Z-axis Can be.

That is, as shown in Figure 9, the movement detecting unit 330 for detecting the movement of the housing 100 to generate the X-axis and Y-axis movement signals of the mouse cursor is mounted on the bottom of the housing 100, The mouse main body 200 located in the inner space 110 of the housing 100 may be configured to mount only the lifting detecting unit 310 for generating a Z-axis movement signal of the mouse cursor. In this case, the movement detecting unit 330 may detect a horizontal movement of the housing 100 such as a bolt rack of an optical mouse or an optical sensor of an optical mouse to generate a mouse cursor movement signal. May also be applied.

In this case, the user moves the mouse cursor to the X-axis and Y-axis by moving the entire housing 100 in front, rear, left and right directions, and moves the mouse cursor in the Z-axis direction by lifting the handle 210 up or down. You can move it to.

Therefore, when the three-dimensional mouse according to the present invention is configured as shown in Fig. 9, the mouse cursor can be moved on the X-axis and the Y-axis by the same operation as the conventional general mouse operation. There is an advantage that it can be used easily without great objection.

10 is a cross-sectional view of a sixth embodiment of a three-dimensional mouse according to the present invention.

3D mouse according to the present invention, as shown in Figure 10 is provided with an execution button 500 for generating various execution signals, such as a click on the side of the handle portion 210 of the upper surface of the housing 100 The wrist rest 130 may be provided at a portion where the user's wrist is located.

In this case, the user operates the handle 210 using the thumb, the index finger, and the middle finger, and operates the execution button 500 using the ring finger and the finger, thereby generating various execution signals simultaneously with the movement of the mouse cursor. You can do it.

In this case, the execution button 500 may be provided on the outer surface of the handle portion 210 of the portion corresponding to the detection and the stop of the user so as to provide convenience for the user familiar with the conventional mouse.

11 to 14 show another embodiment of the handle portion 210 included in the three-dimensional mouse according to the present invention.

When the handle portion 210 included in the present invention is formed in a simple cylindrical or disc shape, in order to lift the handle portion 210, the user needs to grasp the handle portion 210 with force, which may be inconvenient to use. Can be.

Accordingly, the handle 210 may have an insertion groove 212 into which the user's finger can be inserted, as shown in FIG. 11, and seated in a shape in which a part of the user's finger is buried as shown in FIG. 12. A concave portion 214 may be formed on the side so as to be possible.

When the insertion groove 212 is formed in the handle portion 210, the user can move the mouse cursor in the Z-axis direction only by inserting a finger into the insertion groove 212 and then lifting the finger up. Rather, the mouse cursor can be moved to the X-axis and the Y-axis only by moving the finger up, down, left, and right, and thus there is an advantage that the use becomes very convenient.

In addition, when the recessed portion 214 is formed on the outer surface of the handle portion 210, the user inserts the handle portion 210 between two fingers (for example between the index finger and middle finger) and then two When lifting a finger, there is an advantage that the handle portion 210 can be lifted more easily. In this case, the depth of the concave portion 214 may be freely changed according to various conditions such as the physical condition of the user.

When the 3D mouse according to the present invention is utilized for a game, the handle 210 may be formed in a joystick shape as shown in FIG. 13. At this time, the handle portion 210 is preferably provided with an execution button 500 on the side like a normal joystick.

In addition, the handle may be formed in a ring shape in which the user's finger can be inserted, as shown in FIG. 14, when miniaturization and simplification of the shape are required. As such, when the handle is formed in a ring shape, the user may freely manipulate the handle in front, rear, left and right directions with only one finger. At this time, even when the handle is formed in a ring shape, the execution button 500 may be provided on the side.

15 is a perspective view of a seventh embodiment of a three-dimensional mouse according to the present invention.

In addition, the three-dimensional mouse according to the present invention further includes a rotation key 600 for converting the viewpoint of the screen where the mouse cursor is located, that is, to rotate the screen of the virtual space displayed on the monitor to the left or right or up and down. It can be configured to.

The rotation key 600 may be formed in a wheel shape protruding outward over the entire outer circumferential surface of the handle portion 600 as shown in this embodiment, or may be formed in a shape such as a scroll key applied to a general mouse. It may be. In addition, the rotation key 600 may be provided in the handle portion 210, as shown in Figure 15, may be provided in the housing 100.

At this time, the display driving method for rotating the screen of the virtual space to the left and right or up and down is already widely used in a three-dimensional game, a 3D design program, etc., and a detailed description thereof will be omitted.

In addition, the side sensing unit 320 and the elevating detecting unit 310 included in the three-dimensional mouse according to the present invention, as described above, can be used to move the mouse cursor in three dimensions as well as in various ways to suit the computer working characteristics. Application is possible.

For example, in the case of a game, the side sensing unit 320 and the elevating sensing unit 310 may be utilized for horizontal movement (X, Y) and shandong (Z +, Z-) of a cursor, and on a small display such as a mobile phone. The side detection unit 320 may be used for a general mouse cursor movement, and the elevation detecting unit 310 may be used to generate a data signal that is opposite to the rising and falling, that is, a signal that enlarges or reduces the screen. In addition, on the Internet web browser, the side detection unit 320 may be used for a general mouse cursor movement, and the elevation detection unit 310 may be used to generate a signal for scrolling the screen up and down.

As mentioned above, although this invention was demonstrated in detail using the preferable embodiment, the scope of the present invention is not limited to a specific embodiment, Comprising: It should be interpreted by the attached Claim. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

1 is a perspective view of a three-dimensional mouse according to the present invention.

2 is a cross-sectional perspective view of a housing included in a three-dimensional mouse according to the present invention.

3 is a perspective view of a mouse body included in a three-dimensional mouse according to the present invention.

4 is a cross-sectional view of a three-dimensional mouse according to the present invention.

5 shows an example of use of a three-dimensional mouse according to the present invention.

6 is a cross-sectional view of a third embodiment of a three-dimensional mouse according to the present invention.

7 is a cross-sectional view of a third embodiment of a three-dimensional mouse according to the present invention.

8 is a cross-sectional view of a third embodiment of a three-dimensional mouse according to the present invention.

9 is a cross-sectional view of a fifth embodiment of a three-dimensional mouse according to the present invention.

10 is a cross-sectional view of a sixth embodiment of a three-dimensional mouse according to the present invention.

11 to 14 show another embodiment of the handle included in the three-dimensional mouse according to the present invention.

15 is a perspective view of a seventh embodiment of a three-dimensional mouse according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: housing 110: internal space

120: through hole 200: mouse body

210: handle portion 310: lifting detection unit

312: rising detection unit 314: falling detection unit

320: side detection unit 330: movement detection unit

400: elastic means 500: run button

Claims (21)

A housing 100 in which the internal space 110 is formed; A mouse body 200 mounted in the internal space 110; When the lateral external force is applied to the mouse main body 200, the side sensing unit 320 for detecting the contact pressure between the mouse main body 200 and the housing 100 to generate the X-axis and Y-axis movement signals of the mouse cursor. ); And Lifting detection unit 310 for detecting the contact pressure between the mouse main body 200 and the housing 100 when the external force is applied to the mouse main body 200 to generate a Z-axis movement signal of the mouse cursor; Three-dimensional mouse, characterized in that comprises a. The method of claim 1, The side detection unit 320, the mouse cursor 200 and three-dimensional mouse, characterized in that for generating a mouse cursor movement signal so that the movement speed of the mouse cursor can be changed according to the magnitude of the contact pressure between the housing (100). The method of claim 1, When contact pressure is simultaneously generated in the lateral sensing unit 320 and the elevating sensing unit 310, the mouse cursor moves to move the mouse cursor in the direction in which the mouse cursor movement vectors in the X, Y, and Z directions are combined. Three-dimensional mouse, characterized in that for generating a signal. The method of claim 1, The side detection unit 320, the three-dimensional mouse, characterized in that provided on any one side of the lateral outer surface of the mouse body 200 and the lateral inner surface of the inner space (110). A housing 100 in which the internal space 110 is formed; A mouse body 200 mounted in the internal space 110; A movement detecting unit 330 which detects movement of the housing 100 and generates X and Y axis movement signals of a mouse cursor; And Lifting detection unit 310 for detecting the contact pressure between the mouse main body 200 and the housing 100 when the external force is applied to the mouse main body 200 to generate a Z-axis movement signal of the mouse cursor; Three-dimensional mouse, characterized in that comprises a. The method of claim 5, The movement detecting unit 330 is characterized in that provided on the bottom of the housing 100. The method according to any one of claims 1 to 6, The lifting detecting unit 310 includes a rising detecting unit 312 and a falling detecting unit 314 for detecting the rising and falling of the mouse main body 200, and the rising and falling of the mouse main body 200. And move the mouse cursor in the opposite direction. The method of claim 7, wherein The rising detection unit 312 is provided on any one surface of the ceiling surface of the internal space 110 and the upper surface of the mouse body 200, the falling detection unit 314 is the bottom surface of the internal space (110) And three-dimensional mouse, characterized in that provided on any one of the bottom surface of the mouse body (200). The method of claim 7, wherein A concave indentation groove 202 is formed in the side of the mouse body 200, a protruding end 140 is inserted into the concave indentation groove 202 in the inner space 140 of the housing 100,   The rising detection unit 312 is provided on any one surface of the bottom surface of the protruding end 140 and the bottom surface of the concave groove 202, the falling detection unit 314 and the upper surface of the protruding end 140 Three-dimensional mouse, characterized in that provided on any one of the ceiling surface of the recess groove (202). The method according to any one of claims 1 to 6, The lifting detecting unit 310, the mouse cursor 200 and the three-dimensional mouse, characterized in that for generating a mouse cursor movement signal to change the movement speed of the mouse cursor according to the magnitude of the contact pressure between the housing (100). The method according to any one of claims 1 to 6, 3D mouse, characterized in that it further comprises an elastic means (400) for supporting the position of the mouse body 200 so that the mouse cursor movement signal is not generated unless an external force is applied. The method of claim 11, The elastic means 400, the three-dimensional mouse, characterized in that provided between the inner surface of the inner space 110 and the outer surface of the mouse body (200). The method according to any one of claims 1 to 6, The mouse body 200, the three-dimensional mouse, characterized in that it comprises a handle 210 protruding to the outside of the housing (100). The method of claim 13, The handle portion 210 extends laterally to cover a portion of the upper surface of the housing 100, The lifting detecting unit 310 includes a rising detecting unit 312 and a falling detecting unit 314 for detecting the rising and falling of the mouse main body 200 according to the rising and falling of the mouse main body 210. Is configured to move the mouse cursor in the opposite direction, the rising detection unit 312 is provided on any one surface of the ceiling surface of the inner space 110 and the upper surface of the mouse main body 200, the falling detection unit 314 is a three-dimensional mouse, characterized in that provided on any one of the bottom surface of the handle portion 210 and the top surface of the housing (100). The method of claim 14, 3D characterized in that it further comprises a cover 130 for covering the space between the bottom surface of the handle portion 210 and the upper surface of the housing 100 so that the falling detection unit 314 is not exposed to the outside mouse. The method of claim 13, The handle 210 is a three-dimensional mouse, characterized in that the insertion groove 212 is formed that the user's fingers can be inserted. The method of claim 13, The handle 210 is a three-dimensional mouse, characterized in that the concave portion on which the user's fingers can be seated (214) is formed on the side. The method of claim 13, The handle 210 is a three-dimensional mouse, characterized in that formed in the shape of a joystick. The method of claim 13, The handle 210 is a three-dimensional mouse, characterized in that formed in a ring shape that the user's fingers can be inserted. The method according to any one of claims 1 to 6, And a rotation key (600) for converting the viewpoint of the screen on which the mouse cursor is located. A housing 100 in which the internal space 110 is formed; A mouse body 200 mounted in the internal space 110; When the lateral external force is applied to the mouse main body 200, the side sensing unit 320 for detecting the contact pressure between the mouse main body 200 and the housing 100 to generate the X-axis and Y-axis movement signals of the mouse cursor. ); And When the external force is applied to the mouse main body 200 in a vertical direction, the contact pressure between the mouse main body 200 and the housing 100 is sensed to generate a signal that enlarges or reduces the screen or scrolls the screen in both directions. Lift detection unit 310 for generating a signal; Three-dimensional mouse, characterized in that comprises a.

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