JPH07104920A - Optical coordinate detector - Google Patents

Abstract

(57) [Summary] [Object] The present invention relates to an optical coordinate detecting device used for a wireless mouse, and particularly to an optical coordinate detecting device that does not require a power source such as a battery for a mouse body. [Structure] Scanning units A and B, which detect the reflection angles Θ ₁ and Θ ₂ from the mouse main body by scanning a ray emitted from a razor light source horizontally in a fan shape and inject the rays from the scanning units A and B. Optical coordinate detection device including a mouse body having a cylindrical reflecting mirror that reflects in a direction, a position calculation mechanism for calculating the position of the mouse body based on the reflection angles Θ ₁ , Θ ₂ detected by the scanning units A and B .

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical coordinate detecting device for use in a wireless mouse, and more particularly to an optical coordinate detecting device in which the mouse body does not require a power source such as a battery.

[0002]

2. Description of the Related Art Conventionally, a wireless mouse used as an input device of a computer has been known, and the mouse acquires movement amount information and transmits it to another receiver.

[0003]

In such a mouse, since the mouse body requires a power source, it is heavy and requires replacement of the power source. Therefore, there has been an urgent need to develop a lightweight mouse that does not require a power source for the mouse body.

The present invention has been eagerly developed in order to meet such a demand, and the mouse body does not require a power source.
An optical coordinate detecting device for a mouse having a light weight is provided.

[0005]

In order to achieve the above object in the present invention, first, in the first invention, the light beam emitted from the razor light source (30) is horizontally fan-shaped and the mouse body ( A scanning unit A (20) for detecting the reflection angle Θ ₁ from the mouse 60, similarly scans the light beam emitted from the razor light source (50) horizontally in a fan shape, and reflects the reflection angle Θ from the mouse body (60). ₂ scanning unit B (40), scanning unit A (20) and scanning unit B (4
0), a mouse body (60) provided with a cylindrical reflecting mirror (64) for reflecting the light beam from the incident direction, a scanning unit A (20) and a scanning unit B (4).
Position calculation mechanism (8) for calculating the position of the mouse body (60) based on the reflection angles Θ ₁ and Θ ₂ detected by
0) and the like.

In the second invention, the laser light source (3
Half mirror (26), which scans the light beam emitted from (0) in the horizontal direction in a fan shape and detects the reflection angle Θ ₁ from the mouse body (60), the stepping motor (22),
A scanning unit A (20) including a light receiving element (32) and the like, similarly scans a light beam emitted from a razor light source (50) in a horizontal direction in a fan shape, and a mouse body (6
Half mirror (4) for detecting the reflection angle Θ ₂ from (0)
6), stepping motor (42), light receiving element (5
2) a scanning unit B (40) including
A mouse body (60) having a cylindrical reflecting mirror (64) that reflects the light rays from the scanning unit A (20) and the scanning unit B (40) in the incident direction,
The reflection angles Θ ₁ and Θ ₂ detected by the scanning unit A (20) and the scanning unit B (40)
This is an optical coordinate detection device including a position calculation mechanism (80) for calculating the position of the mouse body (60) based on the above.

Furthermore, in the third aspect of the invention, the scanning unit A (20) for scanning the light beam emitted from the razor light source (30) horizontally in a fan shape and detecting the reflection angle Θ ₁ from the mouse body (60). ), Similarly, a scanning unit B (40) and a scanning unit A (20) that horizontally scan a light beam emitted from the razor light source (50) in a fan shape and detect a reflection angle Θ ₂ from the mouse body (60). ) And scanning unit B (4
0), a mouse body (60) provided with a cylindrical reflecting mirror (64) for reflecting the light beam from the incident direction, a scanning unit A (20) and a scanning unit B (4).
Determination unit (8) that calculates the position of the mouse body (60) based on the reflection angles Θ ₁ and Θ ₂ detected by
2) An optical coordinate detection device including a position calculation mechanism (80) including a relative movement amount detection unit (84).

[0008]

According to the present invention as described above, since the mouse body does not need a power source and the mouse housing is provided with the cylindrical reflecting mirror, the mouse body can be made lightweight.

[0009]

The present invention will be described in detail with reference to the following examples.
As shown in FIGS. 1 and 2, the scanning unit A (20)
Is to scan a light beam emitted from the razor light source (30) horizontally in a fan shape and detect a reflection angle Θ ₁ from the mouse body (60). That is, the light beam emitted from the razor light source (30) is emitted by the half mirror (2
6) via a stepping motor (22) to be directed to a rotating mirror (44), and the rotation of the rotating mirror (44) causes the light beam to be horizontally scanned in a fan shape. The light beam scanned in a fan shape in the horizontal direction is reflected by the cylindrical reflection mirror (64) of the mouse body (60). Since the cylindrical reflecting mirror (64) has a cylindrical shape and reflects in the incident direction, the light beam returns to the optical path where it came, and is directed to the light receiving element (32) by the half mirror (26) to receive the light receiving element (32). Is received by. The rotation angle of the rotating mirror (24) when it is received by the light receiving element (32) can be known from the pulse number of the stepping motor (22). ) Is reflected angle Θ ₁ is detected.

Similarly, the scanning unit B (40)
Then, the light beam emitted from the razor light source (50) is horizontally fan-shaped and is received by the light receiving element (52), whereby the reflection angle Θ ₂ from the mouse body (60) is detected.

The mouse body (60) is provided with a cylindrical reflecting mirror (64) in the mouse housing (62), and as described above, the light rays from the scanning unit A (20) and the scanning unit B (40) are cylindrically reflected. The light is reflected by the mirror (64) in the incident direction.

The position calculation mechanism (80) comprises a judgment unit (82) and a relative movement amount detection unit (84), and the reflection angle Θ detected by the scanning unit A (20) and the scanning unit B (40). The position of the mouse body (60) is calculated based on ₁ and Θ ₂ . More specifically, the coordinates (X.Y) are calculated as follows. That is, as shown in FIG. 3, the distance (d) between the rotation axes of the rotating mirror (24) and the rotating mirror (44) is constant, and if the reflection angles Θ ₁ and Θ ₂ are determined, the cylindrical reflection mirror (64). The coordinates (XY) of the central axis of the cylinder are calculated by calculating the following formula. X = d · tan Θ ₁ · tan Θ ₂ / (tan Θ ₁ + t
an Θ ₂ ) Y = d · tan Θ ₁ / (tan Θ ₁ + tan Θ ₂ ).

Further, in order to obtain the movement amounts ΔX and ΔY in the X and Y directions, the following calculation is performed. First, in the determination unit (82), the reflection angle Θ ₁ obtained from the scanning unit A (20) and the scanning unit B (40),
Determine the data integrity of Θ ₂ . That is, Θ ₁ + Θ ₂ ≧
When 180 [deg], the abnormal signal (S) is given by Θ ₁ + Θ
_{When 2} <180 [deg], the normal signal (S) is output. In the relative movement amount detection unit (84), Θ ₁ and Θ ₂ and the scanning unit A (2
0), the following calculation is performed from the distance d between the scanning units B (40). Xnow = d · tan Θ ₁ · tan Θ ₂ / (tan Θ
₁ + tan Θ ₂ ) Ynow = d · tan Θ ₁ / (tan Θ ₁ + tan Θ
₂ ) ΔX = Xnow−Xlast ΔY = Ynow−Ylast is output from the difference between this data and the data Xlast and Ylast stored in the previous storage device (86). After that, Xnow → Xlast Ynow → Ylast is stored, and Xnow and Ynow are newly calculated,
The movement amounts ΔX and ΔY in the X and Y directions are continuously output.

In the present invention, the rotary mirror (24) and the rotary mirror (44) may be polygon mirrors, for example.

[0015]

Since the present invention has the above-mentioned constitution, it has the following effects. That is, the conventional wireless mouse used for the input device of the computer is heavy because the mouse body needs a power source, and the power source needs to be replaced. The mouse body does not require a power source, and thus can be a lightweight mouse.

[Brief description of drawings]

FIG. 1 shows a scanning unit A according to an embodiment of the present invention.
It is isometric view explanatory drawing which shows the detail of B and a mouse main body.

FIG. 2 shows a configuration of position calculation according to the embodiment of the present invention,
It is a schematic explanatory drawing.

FIG. 3 is an explanatory diagram showing a position detection configuration according to the embodiment of the present invention.

[Explanation of symbols]

 10: Optical coordinate detection device 20: Scanning unit A 22: Stepping motor 24: Rotating mirror 26: Half mirror 30: Laser light source 32: Light receiving element 40: Scanning unit B 42: Stepping motor 44 ... Rotating mirror 46 ... Half mirror 50 ... Razor light source 52 ... Light receiving element 60 ... Mouse body 62 ... Mouse housing 64 ... Cylindrical reflection mirror 80 ... Position calculation mechanism 82 ... Judgment unit 84 ...・ ・ ・ Relative movement amount detection unit 86 ・ ・ ・ Memory device S ‥‥ Normal and abnormal signal

Claims (3)

[Claims] _1. A scanning unit A for horizontally scanning a light beam emitted from a razor light source (30) in a fan shape and detecting a reflection angle Θ ₁ from a mouse body (60).
(20) Similarly, a light beam emitted from the razor light source (50) is horizontally scanned in a fan shape, and the mouse body (6)
0) includes a scanning unit B (40) for detecting the reflection angle Θ ₂ , a scanning unit A (20), and a cylindrical reflection mirror (64) for reflecting the light beam from the scanning unit B (40) in the incident direction. A position calculation mechanism (80) for calculating the position of the mouse body (60) based on the reflection angles Θ ₁ and Θ ₂ detected by the mouse body (60), the scanning unit A (20) and the scanning unit B (40), etc. Optical coordinate detection device consisting of. 2. A half mirror (26) and a stepping motor (22) for scanning a light beam emitted from a razor light source (30) horizontally in a fan shape and detecting a reflection angle Θ ₁ from a mouse body (60). , A scanning unit A (20) including a light receiving element (32), and the like, similarly scans a light beam emitted from a razor light source (50) horizontally in a fan shape, and reflects the angle of reflection Θ ₂ from the mouse body (60).
Scanning unit B (40) and scanning unit A (2) equipped with a half mirror (46) for detecting light, a stepping motor (42), a light receiving element (52), and the like.
0) and a mouse body (60) having a cylindrical reflecting mirror (64) for reflecting the light beam from the scanning unit B (40) in the incident direction, the scanning unit A (2).
0) and the reflection angles Θ ₁ and Θ ₂ detected by the scanning unit B (40), the mouse body (60)
An optical coordinate detection device including a position calculation mechanism (80) for calculating the position of the. 3. A scanning unit A for scanning a light beam emitted from a razor light source (30) horizontally in a fan shape and detecting a reflection angle Θ ₁ from a mouse body (60).
(20) Similarly, a light beam emitted from the razor light source (50) is horizontally scanned in a fan shape, and the mouse body (6)
0) includes a scanning unit B (40) for detecting the reflection angle Θ ₂ , a scanning unit A (20), and a cylindrical reflection mirror (64) for reflecting the light beam from the scanning unit B (40) in the incident direction. A determination unit (82) that calculates the position of the mouse body (60) based on the reflection angles Θ ₁ and Θ ₂ detected by the mouse body (60), the scanning unit A (20) and the scanning unit B (40), and a relative unit. An optical coordinate detection device comprising a position calculation mechanism (80) including a movement amount detection unit (84).