DE10149272A1 - Optical mouse with a simplified structure - Google Patents

Abstract

An optical mouse 50 comprises a one-piece lower housing (60, 220), a lens component (80, 230) and a circuit board (90, 210) for control and monitoring. The lower housing (60, 220) has an opening (62) and a light source holder (66, 225). The lens component (80, 230) lies above the opening (62). The circuit board (90, 210) has a light source (70, 240) and a light sensor (100, 215) which are fastened on the circuit board (90, 210). The circuit board (90, 210) is fastened within the lower housing (60, 220) above the lens component (80, 230) and secures the lens component (80, 230) within the lower housing (60, 220). The light source (70, 240) is located within the light source holder (66, 225). The light source bracket (66, 225) serves to set the angular orientation of the light source (70, 240) within the lower housing (60, 220) so that light from the light source (70, 240) passes through an opening (62) onto the surface (51), on which the optical mouse (50) slides, is guided. The light reflected from the surface (51) is directed through the lens component (80, 230) onto the light sensor (100, 215).

Description

The present invention relates to an optical mouse according to the pre-characterizing sentence of claim 1.

The traditional mechanical mouse uses a ball that is inside the housing of the mouse and with a Surface is in contact. While the mechanical mouse Moving over the surface, the ball and sensors roll in recognize this rolling within the mouse and break it down into two vertical components. This structure has been wide for years widespread and still in use today. On Disadvantage is that the rolling ball tends to get dirt on it increase. This dirt settles on the sensors and disrupts their operation. Without regular cleaning, a me Chan mouse react incorrectly, d. H. it either stays stuck along one of the movement axes or the movement the mouse is not traced fluently.

Optical mice have been introduced to solve this problem. Unlike the mechanical mouse, where the movement is easy When a ball is measured, the optical mouse takes a quick one Sequence of images of the surface and then compares each other the images with each other, the direction and the Ent distance to determine the movement of the optical mouse. The Ver drive and the construction of optical mice are state of the art Technology known and are therefore not explained here in more detail tert. One of the advantages of optical mice is the larger one Reliability because there are no moving parts that bre can stick or glue, and a more fluid tracking of Move.

An optical mouse according to the prior art works wall-free, but has a relatively complicated structure. In particular includes an optical mouse according to the prior art Optical component with a variety of reflectors. The optics  component is relatively expensive and increases the total cost of the optical mouse so that it faces the mechanical mouse is less competitive in the market.

Taking into account the above, it is a goal of present invention, a correspondingly simplified opti to provide a system for an optical mouse.

This goal is achieved with an optical mouse according to An saying 1. The subclaims contain corresponding further developments and improvements.

As detailed in the detailed description below can be taken, illuminates the light source of the claimed optical mouse directly the surface without being reflective Surfaces in between are necessary. The lens component is there constructed by much simpler and can therefore be considerably less expensive be manufactured more economically. This in turn reduces the Total cost of the optical mouse.

The invention is illustrated below using examples and Reference to the accompanying drawings explained in more detail. It shows

Fig. 1 is a perspective view of an optical mouse of the prior art,

Fig. 2 is a partial exploded view of an optical system for an optical mouse of the prior art,

Fig. 3 is a side view diagram of the optical system of Fig. 2,

Fig. 4 is a perspective bottom view of a erfindungsge MAESSEN optical mouse

Fig. 5 is a partial exploded view of an optical system for the optical mouse of Fig. 4,

Fig. 6 is a side view diagram of the optical system of Fig. 5, and

FIG. 7 is a partial exploded view of a second embodiment of the optical system for the optical mouse from FIG. 4.

Referring to Fig. 1, reference. Fig. 1 is a perspective view from below of an optical mouse 5 according to the prior art. The optical mouse 5 has a lower housing 20 with an opening 25 . Through this opening 25 , the optical mouse 5 "sees" the surface over which it slides. Information about the change of location is passed on to a computer (not shown) via a cable 3 . The cable 3 can end in one of many standard adapters, such as. B. a PS / 2 adapter, a universal serial bus (USB) adapter, etc.

Reference is made to Figure 2.. FIG. 2 is a partial exploded view of an optical system 10 for an optical mouse 5 according to the prior art. Optical system 10 is disclosed in the Agilent Technologies data sheet. An optical component 30 is fastened over the opening 25 in the lower housing 20 . The optical component 30 comprises a lens 32 , a first reflecting surface 34 and a second reflecting surface 36 . A circuit board 40 is attached above the optics component 30 . The board 40 has an opening 48 positioned over the lens 32 and a light sensor 42 mounted on the board 40 above the opening 48 .

The light sensor 42 takes pictures of the surface over which the optical mouse 5 slides and further comprises a circuit component (not shown in the figure) which analyzes the pictures not taken by the light sensor 42 to determine the movements of the optical mouse 5 , A Lichtemit terdiode (LED) 44 is also attached to the circuit board 40 . The LED 44 is used as a light source for the light sensor 42 . The first reflective surface 34 protrudes through the opening 48 , so that the first reflective surface 34 is between the LED 44 and the light sensor 42 be. Finally, a light shield 46 is also attached to the circuit board 40 . The light shield 46 prevents unwanted light from the LED 44 from accidentally reaching the light sensor 42 .

Referring to Fig. 3 in conjunction with FIG. 2 reference. Fig. 3 is a greatly simplified side view of the optical system 10 of FIG. 2. Light 11 is output by the LED 44 ben. The shield 46 blocks a portion of the light 11 , but much of the light 11 is emitted in the direction in which the LED 44 is directed. Since the LED 44 is directed onto the first reflecting surface 34 , a large part of the light 11 reaches the first reflecting surface 34 , from where the light 11 is then directed downward onto the second reflecting surface 36 . From the second reflecting surface 36 , the light 11 is directed through the opening 25 of the lower housing 20 in order to light the surface 13 . Light 12 is reflected by and modulated by surface 13 and is collected and concentrated by lens 32 to be focused on light sensor 42 . The light sensor 42 uses the light 12 to take repeated images from the surface 13 and analyzes consecutive pairs of these images to determine the direction and magnitude of the movement of the optical mouse.

The optical system 10 works well, but is relatively complicated. In particular, the optical component 30 with its first reflector 34 and its second reflector 36 is relatively expensive. This expensive component increases the overall cost of the optical mouse 5 , making it less competitive on the market than the mechanical mouse.

Referring to Fig. 4, reference. Fig. 4 is a Perspecti vische bottom view of an optical mouse 50 according to the invention. The optical mouse 50 was designed to rest on a surface (not shown) such as an B. a desk, slides and detects this sliding movement. The optical mouse 50 has a lower housing 60 with an opening 62 . Through the opening 62 , the optical mouse 50 can detect the surface over which it slides. Information about the change of location is sent to a computer (not shown) via a cable 35 . Cable 53 may end in one of many different adapters, such as. B. a PS / 2 adapter, a universal serial bus (USB) adapter, etc.

Referring to FIG. 5 and FIG. 6 in conjunction with FIG. 4, reference. Fig. 5 is a partial exploded diagram of an optical system 110's optical mouse for the 50th Fig. 6 is a side view diagram of the optical system 110. The optical system 110 includes a lower housing 60 , a light source 70 , a lens component 80 , a circuit board 90 and a light sensor 100 . The light sensor 100 detects light 113 reflected from a surface 51 and takes a series of images of the surface 51 . The light sensor 100 includes an optical detection and control circuit (not shown) by which the light sensor 100 can analyze these successive images to determine a direction and an amount of movement of the optical mouse 50 . An example of such a device is the HDNS-2000 from Agilent Technologies. The output from the light sensor 100 is used to transmit motion information to the computer (not shown) via the cable 53 .

The light sensor 100 is attached to the circuit board 90 and electrically connected to it. The board 90 has an opening 92 . This opening 92 is necessary so that the light 113 can reach the light sensor 100 . The light sensor 100 therefore spans the opening 92 .

The lower housing 60 is molded in one piece from injection molded plastic. That is, the lower housing 60 is a single piece of plastic molded by a heat / pressure die with injected plastic. Materials other than plastic can also be used, but plastic is particularly inexpensive, easy to manufacture and sufficiently stable.

The lower housing 60 has an opening 62 , a light source bracket 66 , notches 67 and terminals 69th The opening 62 in the housing 60 allows the un direct light 112 from the light source 70 to reach the surface 51 and the light 113 that is reflected from the surface 51, the light sensor 110 to reach it. The light source holder 66 is designed in such a way that it can accommodate the light source 70 , and it has an underbody 64 that slopes away towards the opening 62 and two walls 63 . Located between the two walls 63 , the angle θ of the bottom surface 64 ensures that the angle of the light source 70 is determined such that the light source 70 suitably faces the opening 62 in a predetermined position. This predetermined location is determined by the developer and should be such as to ensure that the surface is illuminated in a manner that improves the contrast of the surface properties. The notches 67 help to position the lens component 80 . Corners 81 of the lens construction part 80 fit exactly into the corresponding notches 67 . The lens component 80 has a lens 84 which is fastened within a lens carrier 82 , the corners 81 being part of this lens carrier. The connection of the corners 81 to the notches 67 is designed in such a way that it is ensured that the lens 84 is positioned above the opening 62 . The lens component 80 also includes a flap 86 . When the lens member 80 is positioned above the opening 62 through the notches 67 , the flap 86 covers one side of the light source bracket 66 to form a roof. The flap 86 forms together with the light source holder 66 a closed, hollow structure 101 , in which the light source 70 is positioned. The lens component 80 is also a one-piece construction, made of transparent plastic of high quality.

The light source 70 is an LED and is fixed on the board 90 by guides 72 . The guides 72 are long enough to ensure that the LED 70 can protrude through the opening 92 of the board 90 . The LED 70 projects through the circuit board 90 into the hollow structure 101 , which is formed by the flap 86 and the light source holder 66 . The LED 70 is thereby positioned and held firmly within the light source holder 66 . The circuit board 90 in turn is held in position with the clamps 69 above the lens component 80 within the lower housing 60 . If the circuit board 90 is held in position by the clamps 60 , the lens component 80 is prevented from slipping out of the notches 67 . That is, the lens member 80 is clamped between the board 90 and the lower case 60 . Thus, the notches 67 and the board 90 work together to fix the lens component within the lower case 60 .

During operation of the optical mouse 50 , light 112 is output from the LED 70 . The direction in which the main part of the light 112 shines is determined by the orientation of the LED 70 . This orientation is in turn determined by the light source holder 66 . Furthermore, the hollow construction 101 , in which the LED 70 is located, also acts as a protective shield and prevents unwanted light from reaching the light sensor 100 directly. The light 112 shines on the surface 51 and is reflected. During this reflection, it is changed by surface 51 and becomes light 113 . The light 113 shines on the lens 84 . The lens 84 bundles the light 113 and the bundled light 113 passes through the opening 92 in the circuit board 90 to the light sensor 100 .

Reference is made to Figure 7.. Fig. 7 is a partial Exploring sion view of an optical system 200 for the optical mouse 50th In almost every respect, the optical system 200 is identical to the first optical system 100 . There are only a few slight differences between the two. For example, optical system 200 shows the use of screws 203 to secure board 210 . The screws 203 drill through openings 207 in the board 210 in supports 205 on the lower housing 220 . In addition, the lens member 230 has no flap to form a hollow structure with the light source bracket 225 . Instead, the light source holder 225 itself is already designed as a hollow construction, with walls 226 , a roof 228 and a sloping underbody 224 . However, the operation of the light source bracket 225 is just like that of the hollow structure 101 of the optical system 100 . That is, the light source bracket 225 serves both as a shield to protect the light sensor 215 from unwanted light from the light source 240 and to properly align the light source 240 within the lower housing 220 .

In contrast to the prior art, the present requires Invention no use of reflective surfaces in within the optical system of the optical mouse to get light from the light source on the surface on which the optical mouse slides to transfer. This will reduce the total cost of the optical system is reduced. The light source is stuck in the light source bracket, and both serve as a shield and ensure that the light source properly in the un tere housing of the optical mouse is aligned.

In summary, an optical mouse 50 comprises a one-piece lower housing 60 , 220 , a lens component 80 , 230 and a circuit board 90 , 210 for control and monitoring. The lower housing 60 , 220 has an opening 62 and a light source holder 66 , 225 . The lens component 80 , 230 lies above the opening 62 . The circuit board 90 , 210 has a light source 70 , 240 and a light sensor 100 , 215 which are fastened on the circuit board 90 , 210 . The circuit board 90 , 210 is fixed within the lower housing 60 , 220 over the lens component 80 , 230 , and secures the lens component 80 , 230 within the lower housing 60 , 220 . The light source 70 , 240 is located within the light source holder 66 , 225 . The light source holder 66 , 225 serves to define the angular orientation of the light source 70 , 240 within the lower housing 60 , 220 , so that light from the light source 70 , 240 through an opening 62 onto the surface 51 on which the optical mouse 50 slides , is directed. The light reflected from the surface 51 is directed by the lens component 80 , 230 onto the light sensor 100 , 215 .

Claims (12)

1. Optical mouse ( 50 ) for detecting the sliding movement of the optical mouse ( 50 ) on a surface ( 51 ), the optical mouse comprising:
a one-piece lower housing ( 60 , 220 ) with a first opening ( 62 ),
a lens component ( 80 , 230 ) above the first opening ( 62 ), and
a board ( 90 , 210 ) for control and monitoring, a light source ( 70 , 240 ) and a light sensor ( 100 , 215 ) which are mounted on the board ( 90 , 210 ), the board ( 90 , 210 ) inside the lower housing ( 60 , 220 ) is fastened over the lens component ( 80 , 230 ), and the circuit board ( 90 , 210 ) serves to secure the lens component ( 80 , 230 ) within the lower housing ( 60 , 220 ),
characterized in that
the lower housing ( 60 , 220 ) further comprises a light source holder ( 66 , 225 ),
that the light source ( 70 , 240 ) is in the light source holder ( 66 , 225 ), and
that the light source bracket ( 66 , 225 ) serves to set the angular orientation of the light source ( 70 , 240 ) within the lower housing ( 60 , 220 ) so that light from the light source ( 70 , 240 ) passes through the first opening ( 62 ) the surface ( 51 ) is directed, and light reflected from the surface ( 51 ) is directed through the lens component ( 80 , 230 ) to the light sensor ( 100 , 215 ). 2. Optical mouse ( 50 ) according to claim 1, characterized in that the one-piece lower housing ( 60 , 220 ) further comprises at least one notch ( 67 ) to accommodate the lens component ( 80 , 230 ), the notch ( 67 ) serves to position the lens component ( 80 , 230 ) within the lower housing ( 60 , 220 ). 3. Optical mouse ( 50 ) according to one of claims 1 or 2, characterized in that the lens component ( 80 , 230 ) comprises a lens ( 84 ) and a lens carrier ( 82 ), the lens ( 84 ) being fixed in the lens carrier ( 82 ) is seated, and the lens carrier ( 82 ) is clamped between the lower housing ( 60 , 220 ) and the circuit board ( 90 , 210 ). 4. Optical mouse ( 50 ) according to one of claims 1 to 3, characterized in that the lens component ( 80 ) further comprises a flap ( 86 ) which is designed so that it covers one side of the light source holder ( 66 ), wherein the The flap ( 86 ) and the light source holder ( 66 ) together produce a hollow structure ( 101 ) which receives the light source ( 66 ). 5. Optical mouse ( 50 ) according to claim 4, characterized in that the hollow structure ( 101 ) serves as a protective shield to block part of the light emitted by the light source ( 70 ). 6. Optical mouse ( 50 ) according to one of claims 1 to 5, characterized in that the light source holder ( 225 ) is a hollow construction. 7. Optical mouse ( 50 ) according to claim 6, characterized in that the hollow construction serves as a protective shield to prevent egg nen part of the light emitted by the light source ( 70 ). 8. Optical mouse ( 50 ) according to one of claims 1 to 7, characterized in that the circuit board ( 90 , 210 ) comprises a second opening ( 92 ), the light sensor ( 100 , 215 ) above the second opening ( 92 ) is attached , and that the light reflected from the surface ( 51 ) is guided through the lens component ( 80 , 230 ) and through the second opening ( 92 ) to the light sensor ( 100 , 215 ). 9. Optical mouse ( 50 ) according to claim 8, characterized in that the light source ( 70 , 240 ) projects through the second opening ( 92 ) into the light source holder ( 66 , 225 ). 10. Optical mouse ( 50 ) according to one of claims 1 to 9, characterized in that the light source ( 70 , 240 ) is a light emitting diode (LED). 11. Optical mouse ( 50 ) according to one of claims 1 to 10, characterized in that the one-piece lower housing ( 60 ) further comprises at least one clamp ( 69 ) which receives the circuit board ( 90 ), the clamp ( 69 ) Circuit board ( 90 ) clamped inside the lower housing ( 60 ). 12. Optical mouse ( 50 ) according to one of claims 1 to 11, characterized in that screws ( 203 ) are used to secure the circuit board ( 210 ) to the lower housing ( 220 ).