KR20050053472A - Optical mouse operable in 3 dimensional space - Google Patents

Abstract

In the spatial optical mouse device of the present invention, a plate serving as a mouse pad is mounted on a main body of the optical mouse, and the plate is moved in the XY axis direction, thereby being displayed on the monitor of the terminal even when there is no bottom surface serving as a mouse pad. It is an object of the present invention to provide a spatial optical mouse device that can easily control a cursor with only a finger, and thereby precisely control the cursor without being affected by human movement.

In order to achieve the object of the present invention, the present invention, in the optical mouse device added to the terminal, by irradiating light to obtain the reflected light reflected on the reflective surface, and converts the reflected light into an electrical optical signal An optical signal generator; A main processor for calculating a coordinate value of a cursor displayed on the monitor of the terminal by the optical signal and transmitting the coordinate value to the terminal; And an input unit for a spatial mode mounted on the reflective plate and activating a driving signal for driving the optical signal generator.

Description

Spatial optical mouse device {OPTICAL MOUSE OPERABLE IN 3 DIMENSIONAL SPACE}

The present invention relates to a spatial optical mouse device, and more particularly, to a spatial optical mouse device capable of supporting three-dimensional spatial user input.

In general, the optical mouse device irradiates light from a light emitting diode mounted inside the mouse body, obtains reflected light reflected through a reflective surface serving as a pad, and obtains the reflected light through the X-axis of the mouse. And by detecting the amount of movement of the Y-axis to move the cursor displayed on the monitor of the terminal, for this purpose it is necessary to the bottom surface or the mouse pad to reflect the light emitted essentially.

Therefore, the optical mouse input device to date is difficult to use in a place where the bottom surface is narrow or an uneven surface, and it is impossible to use it in the space without the bottom surface which functions as a pad.

In order to solve this problem and reflect the movement in the three-dimensional space to the cursor, a spatial mouse or the like for moving the cursor displayed on the monitor of the terminal by receiving the three-dimensional movement has been developed.

1 is a block diagram illustrating a conventional three-dimensional user input device, which will be described below.

The X coordinate detector 100 detects or detects a movement of the user input device in the X axis direction. In addition, the Y coordinate detector 110 detects or detects a movement of the user input device in the Y axis direction perpendicular to the X axis direction. Meanwhile, the Z coordinate detector 120 detects or detects the movement of the user input device in the Z axis direction perpendicular to each of the X axis direction and the Y axis direction. In addition, the posture detection unit 130 serves to detect a posture in space with respect to reference axes in the X, Y, and Z axis directions of the user input device itself. Meanwhile, the A / D converter 140 converts an analog signal input from the X coordinate detector 100, the Y coordinate detector 110, the Z coordinate detector 120, and the attitude detector 130 into a digital signal and outputs the digital signal. Play a role. In addition, the data transmitter 150 transmits the motion detected from each detector to the data receiver 170. Meanwhile, the data receiver 170 receives data transmitted from the data transmitter 150 and transmits the data to the coordinate calculator 180. In addition, the coordinate calculator 180 calculates or calculates a coordinate value of a user input device on an actual space based on a value input from the data receiver 170. On the other hand, the coordinate output unit 190 serves to output the coordinate value calculated by the coordinate calculation unit 180.

However, according to the above-described conventional technology, not only the gyrosensor or the accelerometer which performs the detection operation additionally needs to be mounted on the optical mouse device, but also the movement of the wrist in 3D is sensed. Since the cursor is operated, there is a problem in which the movement of a person is reflected in the movement of the cursor during the operation of the mouse.

The present invention has been made in order to solve the above problems, by mounting a plate to act as a mouse pad on the body of the optical mouse, and by moving it in the XY axis direction, even if there is no bottom surface acting as a mouse pad It is an object of the present invention to provide a spatial optical mouse device that can easily control a cursor displayed on a monitor using only a finger, and thereby precisely control the cursor without being affected by human movement.

In order to achieve the object of the present invention, the spatial optical mouse device of the present invention, in the optical mouse device is added to the terminal, to obtain the reflected light reflected by the light on the reflective surface by irradiating the light, An optical signal generator converting the optical signal; A main processor for calculating a coordinate value of a cursor displayed on the monitor of the terminal by the optical signal and transmitting the coordinate value to the terminal; And an input unit for a spatial mode mounted on the reflective plate and activating a driving signal for driving the optical signal generator.

In addition, in order to achieve the object of the present invention, the spatial optical mouse device of the present invention, in the optical mouse device added to the terminal, to obtain the reflected light reflected by the light on the reflective surface by irradiating the light, An optical signal generator converting the electrical optical signal; A button and wheel signal input unit for mounting a button and a wheel and generating an operation signal according to a button or wheel selection; A main processor for calculating a coordinate value of a cursor displayed on the monitor of the terminal by the optical signal, transmitting the coordinate value to the terminal, and generating a control signal according to the operation signal; An input unit for a spatial mode mounted on the reflective plate and activating a driving signal for driving the optical signal generator; And a data transceiver for performing an interface between the main processor and the terminal.

Hereinafter, the most preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily implement the technical idea of the present invention. .

First, Figure 2 is a block diagram showing a spatial optical mouse device according to an embodiment of the present invention, the spatial optical mouse device of the present invention, the optical signal generating unit 210, button and wheel signal input unit 220, The space mode input unit 230, a main processor 240, and a data transceiver 250 are included.

The optical signal generator 210 is activated by the control of the main processor 240 to be described later, obtains the reflected light by reflecting the light on the reflective surface by irradiating light, and converts the reflected light into an electrical optical signal. The optical signal is input to the main processor 240 which will be described later. Here, the optical signal generator 210 will be described in detail as follows.

The light emitter 211 mounted in the optical signal generator 210 serves to irradiate light.

In addition, the light receiving unit 212 mounted in the optical signal generating unit 210 serves to obtain the reflected light reflected by the light emitted by the light emitting unit 211 to the reflecting surface.

On the other hand, the image sensor 213 mounted in the optical signal generator 210 converts the reflected light input from the light receiver 212 into an electrical optical signal, and transmits the optical signal to the main processor 240 which will be described later. It plays a role of input.

In addition, the button and wheel signal input unit 220 mounts the button and the wheel, generates an operation signal according to the button or wheel selection, and serves to output the operation signal to the main processor 240 to be described later.

Meanwhile, the space mode input unit 230 mounts a movable plate which is the reflective surface, activates a driving signal for driving the optical signal generator 210, and transmits the driving signal to the optical signal generator 210. It prints in).

In addition, the main processor 240 calculates coordinate values of a cursor displayed on a monitor of a terminal (for example, a PC) by using the optical signal, transmits the coordinate values to the terminal, and transmits the coordinates to the operation signal. The control signal is generated, and the coordinates are initialized when the driving signal is deactivated.

Meanwhile, the data transceiver 250 serves to perform an interface between the main processor 240 and the terminal. Here, the data transmission and reception unit 250 will be described in detail as follows.

The data transmitter 251 mounted in the data transceiver 250 serves to transmit a signal input from the main processor 240 to the terminal.

In addition, the data receiver 252 mounted in the data transceiver 250 serves to transmit a signal input from the terminal to the main processor 240.

3A and 3B are exemplary views illustrating the input unit 230 for the spatial mode of FIG. 2, which will be described below.

The plate 310 mounted in the space mode input unit 230 serves as the reflective surface. Here, the movement range of the plate 310 is preferably set within the limit that can reflect the light emitted from the light emitting unit 211, but is not limited thereto.

In addition, the coupling means 320 mounted in the input unit 230 for the space mode serves to couple the plate to the body housing of the optical mouse device. Here, the coupling means 320 may be a spring having an elasticity capable of restoring the plate 310 to an initial position or a mechanism capable of performing the same function, but is not limited thereto.

Meanwhile, the pressure detector 330 mounted in the space mode input unit 230 activates the driving signal when pressure is applied to the plate 310. That is, the driving signal is activated only when the pressure is applied to the plate 310 so that the movement of the plate 310 is reflected in the cursor displayed on the monitor, and when the pressure is not applied to the plate 310 The movement of the plate 310 is not reflected in the cursor displayed on the monitor. Here, the pressure sensor 330 may be a pressure sensor capable of detecting a predetermined pressure, but is not limited thereto. In addition, it is apparent that the sensing plate of the pressure sensing unit 330 has a size including a moving range of the plate 310 so that the plate 310 can be detected at any position.

Here, the pressure sensing unit 330 may be replaced with a switch for switching the activation / deactivation of the driving signal, but is not limited thereto. That is, when the drive signal is activated by the switch, the movement of the plate 310 is reflected in the cursor displayed on the monitor. When the drive signal is deactivated by the switch, the movement of the plate 310 is lost. It will not be reflected in the cursor displayed on the monitor.

4 is an exemplary view showing a use case of the spatial optical mouse device according to an embodiment of the present invention. Referring to this, the operation of the spatial optical mouse device according to the present invention will be described below.

First, the user grabs the mouse body, which is a form in which a general optical mouse device is inverted, and activates a driving signal. At this time, the mouse body housing is preferably invented to be easily held in the user's hand in the space.

Here, the method of activating the drive signal is that the pressure is applied to the plate 310 when the pressure sensing unit 330 is mounted, and when the switch is mounted, the user switches directly to the direction of activating the drive signal. .

Thereafter, when the user moves the plate 310 while applying pressure in the case of the pressure sensing method, or the user moves the plate 310 in the case of the switch switching method, the movement of the plate 310 is performed by the optical signal generator ( The cursor is reflected on the optical signal generation of 210 to move the cursor displayed on the monitor.

If you do not want to reflect the movement of the plate 310 to the movement of the cursor, or if you want to return the plate 310 to the initial position without the movement of the cursor, by removing the pressure applied to the plate 310 or by operating the switch The drive signal can be deactivated.

Here, the communication between the spatial optical mouse device and the terminal (for example, a desktop computer, a laptop, etc.) of the present invention may use both wireless or wired communication as shown in FIG. A PC serial port, a PS2 port, a USB port, an IEEE port, an infrared ray (IRDA) port, etc. may be used in communication with a terminal (for example, a desktop computer, a notebook computer, etc.), but is not limited thereto.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited to the drawings shown.

The present invention is equipped with a plate that acts as a mouse pad on the main body of the optical mouse, and by moving it in the XY axis direction, the cursor displayed on the monitor of the terminal is easy with only a finger, even in the absence of a bottom surface acting as a mouse pad. Control, and there is an advantage that can precisely control the cursor without being affected by the movement of the person.

1 is a block diagram showing a conventional three-dimensional user input device;

2 is a block diagram showing a spatial optical mouse device according to an embodiment of the present invention;

3A and 3B are exemplary views illustrating an input unit for the spatial mode of FIG. 2;

Figure 4 is an exemplary view showing a use example of the spatial optical mouse device according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

210: optical signal generator

220: button and wheel signal input unit

230: input unit for space mode

240: main processing unit

250: data transmission and reception unit

Claims (12)

In the optical mouse device added to the terminal, An optical signal generator configured to irradiate light to obtain reflected light reflected by the light on the reflective surface, and convert the reflected light into an electrical optical signal; A main processor for calculating a coordinate value of a cursor displayed on the monitor of the terminal by the optical signal and transmitting the coordinate value to the terminal; And An input unit for a spatial mode mounted on the reflective plate and activating a driving signal for driving the optical signal generator; Spatial optical mouse device comprising a. The method of claim 1, The main processor is configured to initialize the coordinate value when the driving signal is inactivated. Spatial optical mouse device, characterized in that. The space mode input unit according to claim 1 or 2, A plate serving as the reflective surface; Coupling means for coupling the plate to the body housing of the optical mouse device; And Pressure sensing unit for activating the drive signal when pressure is applied to the plate Spatial optical mouse device comprising a. The space mode input unit according to claim 1 or 2, A plate serving as the reflective surface; Coupling means for coupling the plate to the body housing of the optical mouse device; And Switch unit for switching the activation and deactivation of the drive signal Spatial optical mouse device comprising a. The method of claim 3, wherein the coupling means, Capable of shrinking and stretching, and having elasticity to return the plate to its initial position Spatial optical mouse device, characterized in that. The method of claim 4, wherein the coupling means, Capable of shrinking and stretching, and having elasticity to return the plate to its initial position Spatial optical mouse device, characterized in that. In the optical mouse device added to the terminal, An optical signal generator configured to irradiate light to obtain reflected light reflected by the light on the reflective surface, and convert the reflected light into an electrical optical signal; A button and wheel signal input unit for mounting a button and a wheel and generating an operation signal according to a button or wheel selection; A main processor for calculating a coordinate value of a cursor displayed on the monitor of the terminal by the optical signal, transmitting the coordinate value to the terminal, and generating a control signal according to the operation signal; An input unit for a spatial mode mounted on the reflective plate and activating a driving signal for driving the optical signal generator; And Data transceiver for performing an interface between the main processor and the terminal Spatial optical mouse device comprising a. The method of claim 7, wherein The main processor is configured to initialize the coordinate value when the driving signal is inactivated. Spatial optical mouse device, characterized in that. The method of claim 7 or 8, wherein the spatial mode input unit, A plate serving as the reflective surface; Coupling means for coupling the plate to the body housing of the optical mouse device; And Pressure sensing unit for activating the drive signal when pressure is applied to the plate Spatial optical mouse device comprising a. The method of claim 7 or 8, wherein the spatial mode input unit, A plate serving as the reflective surface; Coupling means for coupling the plate to the body housing of the optical mouse device; And Switch unit for switching the activation and deactivation of the drive signal Spatial optical mouse device comprising a. The method of claim 9, wherein the coupling means, Capable of shrinking and stretching, and having elasticity to return the plate to its initial position Spatial optical mouse device, characterized in that. The method of claim 10, wherein the coupling means, Capable of shrinking and stretching, and having elasticity to return the plate to its initial position Spatial optical mouse device, characterized in that.