JPH05110965A - Cursor controller in television receiver - Google Patents

Abstract

PURPOSE:To easily operate a cursor, which is displayed on a picture, in the feeling that the cursor is moved in the direction indicated by a finger by moving a remote controller. CONSTITUTION:An infrared signal is transmitted by a remote controller 12 and is received by light reception parts 16, 18, and 20. An X coordinate detecting circuit 22 calculates the coordinate in the horizontal direction of the remote controller 12 based on signals from first and second light reception parts 16 and 18, and a Y coordinate detecting circuit 24 calculates the coordinate in the vertical direction of the remote controller 12 based on signals from second and third light reception parts 18 and 20. A cursor display circuit 36 displays the cursor on the picture in accordance with coordinates of the remote controller 12.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cursor control device in a television receiver, and more particularly to a cursor in a television receiver for controlling an icon displayed on the screen or a cursor for selecting a plurality of screens. Regarding the control device.

[0002]

2. Description of the Related Art In a conventional cursor control device of this type,
The remote controller was provided with up, down, left, and right arrow keys, and the cursor was moved by operating this key.

[0003]

In the prior art, there was the problem that the operability was poor and the direct feeling of the operation was absent because the key had to be operated. Therefore, a main object of the present invention is to provide a cursor control device for a television receiver, which has good operability.

[0004]

SUMMARY OF THE INVENTION According to the present invention, in a cursor control device for a television receiver for controlling the movement of a cursor displayed on a screen, transmitting means for transmitting infrared rays and a front surface of the television receiver are provided. A plurality of light receiving means provided at different positions, each of which collects infrared rays to form a spot and outputs a value according to the position of the spot, and a value corresponding to the position of the spot output from the plurality of light receiving means A cursor control device for a television receiver, comprising: a calculating means for calculating the coordinates of the transmitting means based on the display means; and a display means for displaying a cursor on the screen based on the coordinates.

[0005]

In each case, two light receiving means each including, for example, a lens and a detector are arranged in the horizontal and vertical directions, respectively. The lens collects infrared rays transmitted from a transmission means such as a remote controller to form a spot on the detector, and the detector outputs a value according to the position of the spot. The calculation means calculates the horizontal coordinate of the remote controller based on the respective values output from the two light receiving means arranged in the horizontal direction, and outputs the respective coordinates output from the two light receiving means arranged in the vertical direction. Calculate the vertical coordinate of the remote controller based on the value. Then, the display means displays a cursor on the screen according to the horizontal and vertical coordinates of the remote controller.

[0006]

According to the present invention, since the cursor can be moved depending on the position of the transmitting means such as the remote controller, the operability can be improved as compared with the conventional one using the cursor key. Further, it is possible to obtain a direct operation feeling such that the cursor is moved in the direction in which the transmitting means is moved.

The above-mentioned objects, other objects, features and advantages of the present invention will become more apparent from the following detailed description of the embodiments with reference to the drawings.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A cursor control device 1 of this embodiment shown in FIG.
0 includes a remote controller 12. The remote controller 12 transmits an infrared signal, and this infrared signal is transmitted to the television receiver 14
It is given to each of the 1st light receiving part 16, the 2nd light receiving part 18, and the 3rd light receiving part 20 arrange | positioned at the front surface of (FIG. 3).

The first light receiving portion 16 and the second light receiving portion 18 are
The horizontal position information of the remote controller 12 is detected, and this position information is given to the X coordinate detection circuit 22. On the other hand, the second light receiving portion 18 and the third light receiving portion 20 detect vertical position information of the remote controller 12, and this position information is given to the Y coordinate detection circuit 24. Then, each of the X coordinate detection circuit 22 and the Y coordinate detection circuit 24 calculates the horizontal coordinate (X) and the vertical coordinate (Y) of the remote controller 12 based on the given position information.

Now, the principle of calculating the coordinate (X) will be described with reference to FIG. In FIG. 2, the X-axis (FIG. 3) passing through the first light receiving unit 16 and the second light receiving unit 18 and the center of a line segment connecting the first light receiving unit 16 and the second light receiving unit 18 are passed and respectively. Only the X-Z1 coordinate system based on the Z1 axis (FIG. 3) perpendicular to the surface including the light receiving portions 16 to 20 is shown.
The first light receiving unit 16 and the second light receiving unit 18 include detectors 26 and 28, respectively.
Lenses 30 and 32 are arranged in front of 8 respectively. Lenses 30 and 32 focus infrared light to form spots P ₁ and P ₂ on detectors 26 and 28.

Here, the optical axes of the lenses 30 and 32 are X.
The angle formed with the axis is θ, the distance from the origin to the centers of the lenses 30 and 32 is A, and the coordinates of the remote controller 12 (light emitting unit) are Q.
(X, Z1), a straight line connecting the coordinate Q (X, Z1) and the center of the lens 30, a straight line connecting the coordinate Q (X, Z1) and the center of the lens 32, and the straight line and the optical axis of the lens 30. Is α, the angle between the straight line and the optical axis of the lens 32 is β, the distance from the center of each of the lenses 30 and 32 to the detectors 26 and 28 is h, and the intersection of the optical axis of the lens 30 and the detector 26 the distance to the spot P ₁ a, and the distance from the intersection of the optical axis and the detector 28 of the lens 32 to the spot P ₂ and b from

[0012]

## EQU1 ## It can be expressed as α = tan ^-1 (a / h) β = tan ^-1 (b / h). Also, the equations for and are

[0013]

Z = tan (θ + α) X−A tan (θ + α) ... Z = −tan (θ + β) X−A tan (θ + α). Therefore, the coordinate Q (X, Z1)
Is given by the solution of simultaneous equations that find the intersection of two straight lines and, and the coordinate (X) in the horizontal direction is the variables a and b.
It can be represented by an expression using. The horizontal coordinate (X) of the remote controller 12 can be obtained by detecting the values of the variables a and b.

On the other hand, the coordinate (Y) in the vertical direction of the remote controller 12 can be obtained by using the YZ2 coordinate system (FIG. 3) according to the same principle, and therefore will not be repeated here. Actually, in the X coordinate detection circuit 22 and the Y coordinate detection circuit 24, the initial position O ₁ (0, 0) shown in FIG. Remote control 1 from initial position O ₁ (0,0)
The horizontal and vertical shifts of 2 are detected, and the result is used to determine the coordinates (X, Y).

Further, in this embodiment, the second light receiving portion 18 is used which can detect two-dimensional position information in the horizontal and vertical directions.
May be replaced with two light receiving units capable of detecting only one-dimensional position information. Returning to FIG. 1, the coordinates (X, Y) of the remote controller 12 thus obtained are given to the cursor display circuit 36 via the coordinate correction circuit 34.
In the cursor display circuit 36, the remote controller 12 has an initial position O ₁
When the coordinate is (X, Y) = (0, 0), a cursor (not shown) is displayed at the center of the screen. When the position of the remote controller 12 is moved, each light receiving unit 16
Since the output values from .about.20 change, the coordinates sent to the cursor display circuit 36 change, and the cursor moves accordingly.

The moving area 38 of the remote controller 12 required for moving the cursor to the entire screen is wide enough to allow the remote controller 12 to be moved only by the movement of the wrist in consideration of operability. Is set. And
For example, the position O ₂ (X _i , shown in FIG. 1 outside the region 38,
When operating the remote controller 12 within the area 40 centered around Y _i ), the correction switch 12a provided on the remote controller 12
In response to the operation (FIG. 1 or FIG. 3), the position O
_{At 2} (X _i , Y _i ), a correction signal (an infrared signal modulated) is transmitted from the remote controller 12. This correction signal is received by any one or more of the first to third light receiving units 16 to 20 (only the first light receiving unit 16 in this embodiment),
It is given to the correction signal detection circuit 42. The correction signal detection circuit 42 is configured to detect the coordinate correction circuit 34 according to the detected correction signal.
A correction command signal is given to. Then, the coordinate correction circuit 34
Is the coordinate (X _i , Y _i ) of the remote controller 12 calculated by the X coordinate detection circuit 22 and the Y coordinate detection circuit 24, and
Correction is performed so that (X _i , Y _i ) = (0, 0). Therefore, the cursor display circuit 36 displays the cursor at the center of the screen assuming that the remote controller 12 is at the coordinates (0,0). After that, the cursor is moved according to the displacement of the remote controller 12 from the position O ₂ (X _i , Y _i ).

The area 44 in FIG.
Each of the light receiving units 16 to 20 can receive the infrared signal from
Area, and area 46 is as described above.
If the coordinates are corrected by moving the
Indicates the area that can be moved across the surface. Therefore, the remote control
12 is outside the area 46, for example, at the position O₃(X_j，
Y _j), Move the cursor to the entire screen.
A portion of the region 48 that can
If you correct the coordinates, the operability will be bad.
It gets worse. Therefore, in this embodiment, the remote controller 1
The coordinates can only be corrected when 2 is inside region 46.
Thus, the coordinate determination circuit 50 is provided.

The coordinate determining circuit 50 uses the coordinates of the boundary of the region 46 as a threshold value. When the coordinates from the X coordinate detecting circuit 22 and the Y coordinate detecting circuit 24 are within the threshold value, the coordinate determining circuit 50 activates the coordinate correcting circuit 34. Output a signal and make the coordinates correctable. On the other hand, if it is out of the threshold value, the active signal is not output, and the coordinates cannot be corrected even if the correction command signal is input from the correction signal detection circuit 42 to the coordinate correction circuit 34.

If the coordinate is corrected by using the change of the signal (active signal) given from the coordinate judging circuit 50 to the coordinate correcting circuit 34 as a trigger, the remote controller 12 can control the area without transmitting the correcting signal. Since the coordinates can be automatically corrected at the time of entering the area 46, the operability can be further improved. Even in this case, if it is desired to operate the remote controller 12 near the center of the screen, the remote controller 12 may be moved to near the center of the screen and the above-described correction signal may be transmitted to further correct the coordinates.

The regions 44 and 46 are determined by the characteristics of the lenses and detectors of the light receiving parts 16 to 20 or the arrangement of the light receiving parts 16 to 20 and can be measured in advance.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

2 is an illustrative view showing a principle of calculating a position of a remote controller in the embodiment of FIG. 1. FIG.

FIG. 3 is an illustrative view showing a coordinate system used for detecting coordinates of a remote controller.

[Explanation of symbols]

 10 ... Cursor control device 12 ... Remote control 12a ... Correction switch 16, 18, 20 ... Light receiving part

Claims (3)

[Claims] 1. A cursor control device in a television receiver for controlling movement of a cursor displayed on a screen, transmitting means for transmitting infrared rays, the transmitting means being provided at different positions on a front surface of the television receiver. A plurality of light receiving means each forming a spot by condensing the infrared rays and outputting a value according to the position of the spot, based on a value according to the position of the spot output from the plurality of light receiving means A calculation means for calculating the coordinates of the transmission means, and a display means for displaying the cursor on the screen based on the coordinates.
Cursor control device for television receiver. 2. A correction signal transmitting unit which is provided in the transmitting unit and which transmits a correction signal, and a first correction which corrects the coordinates so as to display the cursor at the center of the screen in response to the correction signal. The cursor control device in the television receiver according to claim 1, further comprising means. 3. Coordinate determining means for generating a signal when the coordinate falls within a predetermined threshold value, and secondly correcting the coordinate so as to display the cursor at the center of the screen in response to the signal. The cursor control device in the television receiver according to claim 1, further comprising a correction unit.