JPH08320758A - Pointing device - Google Patents

Abstract

PURPOSE: To obtain the pointing device which is small-sized, lightweight, and superior in portability and gives a real feeling of the movement of a cursor. CONSTITUTION: This device is provided with a magnet 2, plural magnetic sensors 4 which are arranged fixedly to the magnet 2 and detect the magnetic force of the magnet 2, a distance calculating means 6 which is connected to the outputs of the magnetic sensors 4 and calculates the distances between the magnet 2 and magnetic sensors 4, a position calculating means 8 which calculates the position of the magnet 2 in a movement range which is allowed for the movement of the magnet 2 among intersections of circles having their centers at the respective magnetic sensors 4 from the respective distances outputted from the distance calculating means 6, and a converting means 10 which converts the relative distances between the positions of the magnet 2 when the magnet 2 moves into the movement distances of the cursor on a display device.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pointing device using a magnet. A pointing device is a man-machine interface used in an information processing apparatus or the like. For such a pointing device, particularly in a notebook type personal computer (hereinafter referred to as a personal computer), there is a demand for weight reduction and size reduction of the pointing device itself in response to the demand for weight reduction and size reduction. There is still room for improvement in the technology of notebook-type personal computers, and even with regard to pointing devices alone, each vendor is still developing various ideas.

[0002]

2. Description of the Related Art The following are known as pointing devices. The first one is
It's a mouse. This mouse rotates a ball rotatably provided on its back surface, reads the rotation angle by a sensor, converts the information into xy-axis information by a conversion means, and converts the xy-axis information into a screen of a display device. It is used to determine the position of the cursor displayed in. One example of reading the rotation angle is to provide wings at some places and read how many times the wings hit the slot. This pointing device is the opposite of its mouse movement and cursor movement.

The second is a trackball. The principle is the same as the mouse. The trackball is built into the computer body. The third is the TrackPoint. The principle is to determine the position of the cursor by converting the change in resistance due to pressure into xy-axis information by an electrical conversion means (IC controller).
A strain sensor is used to change the resistance due to pressure.

The fourth type is a track pad. The change in the capacitance when the finger is slid on a plate of a material capable of forming the capacitance between the finger and the finger is used to move the cursor on the display screen of the display device. The fifth is a pen. This is to use the position when the pen is in contact with the panel for moving the cursor on the screen of the display device. The position can be detected by using static electricity or by using a resistive film on the panel side.

The sixth one is a pointing device using a magnet (Japanese Patent Laid-Open No. 5-204540). The principle is that when the magnet is moved in a certain direction, the cursor continues to move in the direction on the screen corresponding to that direction, and to stop the movement of the cursor, the magnet must be returned to its original home position. I won't.

[0006]

Each of the pointing devices described above has the following drawbacks.

The mouse requires a separate panel and cannot be used without some flat surface. Therefore,
It is difficult to use in a limited space, such as in an airplane, car or train. In addition, since it is not built in the main body, it is bulky when carried and may be lost. Since the trackball itself is large and heavy, and it is built in the personal computer, the capacity and weight of the main body of the personal computer must be increased. Also, because the direction of hand rotation and the direction of movement of the cursor on the computer screen do not match, it is difficult to feel the movement of the cursor and it is difficult to handle until you get used to it.

The track point has a very limited range of movement, and is about several millimeters at most. Therefore, the ratio of the movement of the device actually moved by hand and the movement of the cursor is greatly different, and the movement of the cursor displayed on the screen of the display device cannot be realized. Since the track pad itself is large and heavy, and is built in the personal computer, the capacity and weight of the personal computer must be increased. Moreover, the movable range is very limited, and is about several millimeters at most. Therefore, the ratio of the movement of the device actually moved by hand and the movement of the cursor is greatly different, and the movement of the cursor displayed on the screen of the display device cannot be realized.

Since the pen directly touches the screen of the display device, its contact pressure must be delicately adjusted, and the operating position is higher than that of other pointing devices, which makes the arm tired. There is also a problem. Moreover, it is necessary to provide a panel separately, and it cannot be used unless there is some flat surface. Therefore, it is difficult to use in a narrow limited space such as an airplane, a car or a train.
In addition, since it is not built in the main body, it is bulky when carried and may be lost.

In the sixth aspect, when the magnet is moved in a certain direction, the cursor continues to move in the direction on the screen corresponding to that direction, and in order to stop the movement, the magnet is returned to its original fixed position. Since it is necessary, the movement of the magnet is not reflected in the movement of the cursor as it is, and there is a feeling of strangeness when the cursor is stopped. Also, it takes time to bring the cursor to the target position.

The present invention has been made in view of the above technical problems, and an object of the present invention is to provide a pointing device which is small and light in weight, excellent in portability, and capable of actually feeling the movement of a cursor.

[0012]

FIG. 1 shows a principle block diagram of the invention according to claims 1 to 4.

As shown in FIG. 1, a magnet 2 and a plurality of magnetic sensors 4 fixedly arranged with respect to the magnet 2 for detecting the magnetic force of the magnet 2 are provided. A distance calculating unit 6 connected to the output of the magnetic sensor 4 for calculating the distance between the magnet 2 and the magnetic sensor 4, and each magnetic sensor 4 based on the respective distances output from the distance calculating unit 6 The relative position between the position calculation means 8 for calculating the position of the magnet 2 within the movement range allowed for the movement of the magnet 2 among the intersections of the circles, and the position of the magnet 2 when the magnet 2 moves. The conversion means 10 for converting the target distance into the movement distance of the cursor of the display device is provided.

According to a second aspect of the present invention, as shown in FIG. 1, in the pointing device according to the first aspect, the magnetic force is a magnetic field component perpendicular to the moving surface of the magnet 2.
The movement range is within the movement plane.

According to a third aspect of the present invention, as shown in FIG. 1, in the pointing device according to the first or second aspect, the magnetic sensor 4, the distance calculating means 6,
The position calculating means 8 and the converting means 10 are housed in one housing. According to a fourth aspect of the present invention, as shown in FIG. 1, in the pointing device according to the first to third aspects, the magnet 2 is operated on a flat surface formed on the housing. To do.

[0016]

According to the invention described in claim 1, the movement of the magnet 2 causes
The magnetic force of the magnetic sensor 4 is detected. A signal indicating the magnetic force is supplied to the distance calculating means 6 to calculate the distance between the magnet 2 and the magnetic sensor 4. Then, the calculated distance is used by the position calculating means 8 to obtain the position of the magnet 2.

After that, when the magnet 2 is moved, the position of the magnet 2 after the movement is similarly obtained. The relative distance between the positions of the magnet 2 before and after the movement is converted into the moving distance of the cursor of the display device by the converting means 10 and used for displaying the cursor of the display device. The invention according to claim 2 is such that, in the invention according to claim 1, the magnetic force uses a magnetic field component perpendicular to the moving surface of the magnet 2.

According to a third aspect of the present invention, in the first or second aspect of the invention, the magnetic sensor 4, the distance calculating means 6, the position calculating means 8 are provided in one housing.
Also, the conversion means 10 is accommodated. According to a fourth aspect of the invention, in the first to third aspects of the invention, the magnet 2 is operated on a flat surface formed on the housing.

[0019]

FIG. 2 shows an embodiment of the invention described in claims 1 to 3. This example shows an example implemented in a personal computer. In FIG. 2, reference numeral 20 denotes a personal computer body, and 22 denotes two magnetic sensors provided on the personal computer body. 24 is a magnet. The magnet 24 is configured so that it can be housed at an appropriate position inside the personal computer body. The magnet 24 is a finger on the plane on which the computer main body is placed,
Or, it can be moved by hand and the direction 2 perpendicular to the plane.
At 6 the magnetic field is running. The magnet 24 can be moved in any direction.

The magnetic sensor 22, as shown in FIG.
Each of them is individually connected to the distance calculating means 30 and 32. The magnetic sensor 22 generates a magnetic force from the magnet 24 (for example, the strength of a magnetic field, which will be described below).
To measure. The distance calculating means 30, 32 calculates the distance between the magnet 24 and the magnetic sensor 22 from the strength of the magnetic field measured by the magnetic sensor 22, respectively. The outputs of the distance calculating means 30 and 32 are connected to the position calculating means 34. The position calculating means 34 obtains the intersection of circles, that is, the position of the magnet centering on each magnetic sensor 22 from the distance. The output of the position calculating means 34 is connected to the converting means 36. The conversion means 36 converts the relative distance between the positions of the magnets when the magnets are moved into the amount of movement of the cursor displayed on the display screen of the display device. Conversion means 36
Is connected to the display device 38.

In FIG. 2 and FIG. 3, the magnet 24 is the same as in FIG.
1 and the magnetic sensor 22 corresponds to the magnetic sensor 4 of FIG. The distance calculating means 30 and 32 correspond to the distance calculating means 6 in FIG. 1, and the position calculating means 34 corresponds to the position calculating means 8 in FIG. The conversion means 36 is shown in FIG.
Corresponding to the conversion means 10. The operation of the above embodiment configured as described above will be described below.

Now, assume that the magnet 24 is placed at a certain position A. Magnet 24 and magnetic sensor 22 at that time
The distance between and is calculated by the distance calculating means 30, 32 which receives a signal indicating the strength of the magnetic field from the magnetic sensor 22. The distance is sent to the position calculating means 34, and the circle centering on the magnetic sensor 22 at each distance is calculated by the position calculating means 34 to calculate the intersection of each circle. The position A (XA, YA) on the xy coordinates of the intersection is calculated. The coordinate position a of the cursor on the screen of the display device at that time is
It is assumed that it is (xa, yb) on the screen.

Then, it is assumed that the magnet 24 is moved by a certain distance L. Also at this time, a signal indicating the strength of the magnetic field is sent from the magnetic sensor 22 to the distance calculating means 30, 32, and the distance between the magnet 24 and the magnetic sensor 22 is calculated by the distance calculating means 30, 32. The respective distances are sent to the position calculating means 34, where the magnetic sensors 2 of the respective distances are
A circle centered on 2 is calculated by the position calculating means 34 and the intersection of each circle is calculated. Position B on the xy coordinate of the intersection
(XB, YB) is calculated.

The distance moved from the position A to the position B is calculated by the conversion means 36. That is, the moved distance becomes XB-XA in the X coordinate component and YB in the Y coordinate component.
-YA. These X coordinate component (XB-XA) and Y coordinate component (YB-YA) are the x coordinate component (xb-xa) and the y coordinate component (yb-ya) of the moving distance of the cursor on the display screen of the display device. ) Is converted to. Where xb
And yb are the x coordinate component and the y coordinate component of the coordinate position b to which the cursor on the screen of the display device should be moved.

The signals of the x-coordinate component (xb-xa) and the y-coordinate component (yb-ya) of the moving distance thus converted are supplied from the converting means 36 to the display device 38 and used for displaying the cursor. To be Therefore, the cursor on the display screen of the display device is moved from the coordinate position a before the magnet 24 is moved to the coordinate position b. Although the magnet 24 is operated outside the personal computer main body in the above-described embodiment, the personal computer main body may be provided with a flat plane on which the magnet 24 can be operated so as to operate on the flat plane.
Further, the number of magnetic sensors 22 may be three or the like.

[0026]

As described above, according to the present invention, there is no unnaturalness when the pointing device is operated, it can be carried with the main body, and it can be used anywhere, and the main body of the apparatus itself. It also enables downsizing.

[Brief description of drawings]

FIG. 1 is a block diagram of the principle of the invention according to claims 1 to 4.

FIG. 2 is a diagram showing an external configuration of an embodiment of the invention described in claims 1 to 4.

FIG. 3 is a diagram showing a movement amount calculating portion built in the apparatus main body of the embodiment shown in FIG.

[Explanation of symbols]

 2 magnet 4 magnetic sensor 6 distance calculating means 8 position calculating means 10 converting means 22 magnetic sensor 24 magnet 30 distance calculating means 32 distance calculating means 34 position calculating means 36 converting means 38 display device

Claims (4)

[Claims] 1. A magnet, a plurality of magnetic sensors fixedly arranged with respect to the magnet, for detecting a magnetic force of the magnet, and a distance between the magnet and the magnetic sensor connected to an output of the magnetic sensor. And a position of the magnet within a movement range allowed for the movement of the magnet among intersections of circles centered on the respective magnetic sensors from respective distances output from the distance calculation means. A pointing device comprising: a position calculating means for calculating the position of the magnet; and a converting means for converting a relative distance between the positions of the magnet when the magnet moves into a moving distance of a cursor of the display device. 2. The pointing device according to claim 1, wherein the magnetic force is a magnetic field component perpendicular to a moving surface of the magnet, and the moving range is within the moving surface. 3. The pointing device according to claim 1, wherein the magnetic sensor, the distance calculating means, the position calculating means, and the converting means are housed in one housing. Pointing device. 4. The pointing device according to claim 1, wherein the magnet is operated on a flat surface formed on a housing.