KR102137507B1 - Mouse having scanning function - Google Patents

Abstract

A mouse equipped with a scanning function according to an embodiment of the present invention includes: a case including a base having a scan window and a cover member coupled to an upper surface of the base; A scan button provided on one side of the case; And a scanner accommodated in the case and seated in the scan window, wherein the scanner includes: a housing defining an optical path therein; A glass module mounted on the lower side of the housing and coupled to the scan window; A mirror module mounted on one side of the upper portion of the housing and reflecting the scanned image transmitted from the glass module; A camera module mounted on a side surface of the housing corresponding to the opposite side of the mirror module to photograph an image reflected from the mirror module; A lighting module mounted on the inner upper side of the housing spaced apart from the camera module; And a barrier disposed above the inside of the housing corresponding to the front of the lighting module, and blocking light reflected from the inside of the housing and reflected on the camera module.

Description

Mouse having scanning function

The present invention relates to a mouse equipped with a scanning function.

In general, a mouse is a type of computer input device and performs functions such as program selection, loading, operation, stopping, and opening/closing a screen through a click operation. Recently, as a convergence concept, a fusion-type mouse with a scanning function in addition to the existing mouse function has appeared.

A mouse equipped with a scan function is also called a handheld scanner because it is moved by hand to perform a scan operation. Currently, as disclosed in Korean Patent Laid-Open No. 10-2006-0044271, a mouse with a scanning function capable of recognizing an image such as a barcode is provided.

However, the conventional scanner mouse such as the above patent has the following problems due to structural characteristics.

First, since the camera has a structure in which the scan area is photographed in a straight line from above, the height of the camera must be secured in order to clearly focus the focus. As a result, the height of the mouse increases, and there is a disadvantage that the overall size of the mouse increases.

Second, since the light source is located right next to the camera, there is a disadvantage that a ghost phenomenon occurs in which light emitted from the light source hits the scan area and then is reflected and projected to the camera to create a blurry light shadow on the camera lens.

Third, since the light source is positioned directly above the scan window, the light emitted from the light source cannot be diffused to the side and the light is concentrated in the center of the light source, and as a result, there is a disadvantage that a hotspot phenomenon occurs. That is, the light emitted from the light source does not spread evenly over the area, so that the edge of the scan window is darker than the central area, and there is a disadvantage in that the scanning performance is deteriorated due to the difference in brightness of the scan target surface.

Fourth, there is a disadvantage in that the outer portion of the image is perceived as dark because light cannot be transmitted relative to the center portion.

The present invention has been proposed to improve the above problems.

A mouse with a scan function according to an embodiment of the present invention for achieving the above object includes: a case including a base having a scan window and a cover member coupled to an upper surface of the base; A scan button provided on one side of the case; And a scanner accommodated in the case and seated in the scan window, wherein the scanner includes: a housing defining an optical path therein; A glass module mounted on the lower side of the housing and coupled to the scan window; A mirror module mounted on one side of the upper portion of the housing and reflecting the scanned image transmitted from the glass module; A camera module mounted on a side surface of the housing corresponding to the opposite side of the mirror module to photograph an image reflected from the mirror module; A lighting module mounted on the inner upper side of the housing spaced apart from the camera module; And a barrier disposed above the inside of the housing corresponding to the front of the lighting module, and blocking light reflected from the inside of the housing and reflected on the camera module.

In addition, the lighting module may include a pair of LED light sources, and the barriers are provided on one front side of the LED light source, respectively.

In addition, one portion of the lower portion of the barrier is stepped lower than the other portion.

In addition, the mirror module may include a mirror that reflects light, and the mirror is mounted at an angle to the housing, and is formed to reflect a scanned image transmitted from the glass module to the camera module.

In addition, the mirror is formed larger than the field of view of the camera module, so that the light transmitted to the edge of the mirror corresponding to the outside of the field of view of the camera module is reflected to the glass module. .

In addition, the sum of the first optical path from the glass module to the mirror module and the second optical path from the mirror module to the camera module is 43.2 mm.

In addition, the glass module includes a transparent glass and a glass frame on which the glass is mounted on a bottom surface, and a reflective layer is formed on an inner circumferential surface of the glass frame.

In addition, the mouse according to an embodiment of the present invention further includes an anti-reflection film coated on the glass.

In addition, the mouse according to an embodiment of the present invention further includes an antireflection film coated on the mirror.

According to the mouse having the scanning function according to the embodiment of the present invention constituting the above configuration has the following advantages and effects.

First, there is an advantage that a light source is installed at a point spaced apart from the photographing area of the camera, so that a phenomenon in which the light source is scanned together can be blocked.

Second, since the light source is installed at a point sufficiently separated from the scan window, and a reflective layer for light diffusion is coated on the inner side area of the scan window, light is evenly irradiated to the scan area, thereby maintaining uniform luminance.

Third, since the camera is installed in the inner side area of the mouse, the overall volume of the mouse is reduced, thereby improving the user's gripping sensitivity.

Fourth, since a reflective layer for light diffusion is formed, it not only diffuses the light emitted from the light source, but also increases the utilization rate of light, and thus, there is an advantage of generating effective light intensity with a small number of light sources.

In addition, since light is evenly diffused by the reflective layer, there is an effect of blocking a ghost phenomenon that occurs when light is reflected toward the camera while the light is concentrated in a specific area.

Fifth, since a diffusing lens for light diffusion is provided on the front surface of the light source, the diffusion area of light is widened, and the scan area can be evenly irradiated, so that effective light intensity can be produced with a small number of light sources.

Sixth, by installing a ghost barrier around the light source, there is an effect of preventing the occurrence of a ghost phenomenon in the camera by blocking the light irradiated from the light source from directly condensing on the glass.

Seventh, by making the area of the mirror wider than the field of view area that can be recognized by the camera, and reflecting back to the glass hitting the edge of the mirror, there is an advantage of minimizing the phenomenon that the image boundary is dark.

1 is an external perspective view of a mouse equipped with a scanning function according to an embodiment of the present invention.
2 is an exploded perspective view of the mouse.
3 is a perspective view of a scanner according to an embodiment of the present invention.
4 is an exploded perspective view of the scanner.
5 is a cross-sectional view taken along line II of FIG. 3.
6 is a cut-away perspective view taken along line II of FIG. 3.
7 is a view showing a mirror and glass of the scanner according to an embodiment of the present invention.

Hereinafter, a mouse equipped with a scan function according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is an external perspective view of a mouse equipped with a scanning function according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of the mouse.

1 and 2, a mouse 10 according to an embodiment of the present invention includes a case forming an exterior and a plurality of parts mounted inside the case.

In detail, the case includes a base 16 on which a viewing window 161 is formed, and a cover 11 coupled to an upper surface of the base 16, and the cover 11 includes an upper cover 111 and Includes a lower cover (13). In some cases, the cover 11 may be formed of an upper cover, a middle cover, and a lower cover.

In addition, the mouse 10 includes a main substrate 15 seated on the upper surface of the base 16, a scanner 20 seated in the viewing window 161 area, and a front upper surface of the main substrate 15 A scroller (14) placed on the cover, a scan button (12) provided on one side of the cover (11) to input a scan command, and a mouse sensor (17) mounted on the bottom front and rear ends of the base 16, respectively. ). The mouse sensor 17 may be mounted to face each other at the center of the front end and the center of the rear end of the base 16 or may be mounted to face each other diagonally.

In detail, the main substrate 15 is provided to cover a bottom area of the base 16 except for the viewing window 161. In addition, the scanner 20 is mounted on the viewing window 161. Further, the plurality of mouse sensors 17 are provided in order to accurately recognize an object to be scanned even if the mouse 10 moves irregularly. When only one mouse sensor 17 is mounted, there is a problem in that the mouse 10 does not move linearly in the left and right direction but moves in a curved direction, or when the mouse 10 moves in the left and right direction but moves obliquely up and down, it cannot be detected. However, when at least two of the mouse sensors 17 are mounted at positions facing each other, the two-dimensional coordinates can be accurately recognized and the movement trajectory of the mouse can be accurately recognized. That is, even if the mouse moves obliquely or in a curved line without moving in a horizontal direction (two-dimensional X-axis movement) on the object to be scanned, the captured scan screen is not overlapped or distorted, and it is possible to accurately scan.

Meanwhile, a battery 13 for supplying power to a wireless communication module may be built into the mouse 10.

Hereinafter, a scanner mounted on the mouse 10 will be described in detail with reference to the drawings.

3 is a perspective view of a scanner according to an embodiment of the present invention, and FIG. 4 is an exploded perspective view of the scanner.

3 and 4, the scanner 20 according to an embodiment of the present invention includes a housing 21, a glass module 23 mounted on the bottom of the housing 21, and the housing 21. ), a mirror module 24 mounted at an angle on the front surface of the housing 21, a lighting module 25 mounted at an angle on the upper surface of the housing 21, and a camera module 22 mounted on the rear surface of the housing 21.

In detail, the glass module 23 includes a glass frame 231 coupled to the lower side of the housing 21 and a transparent glass 232 mounted on the bottom of the glass frame 231 do. The bottom portion of the glass frame 231 is formed in the shape of a square frame whose inside is opened so that the glass 232 can be mounted. In addition, a reflective layer 233 is coated on the inner circumferential surface of the glass frame 22. The glass 232 may be mounted on the bottom of the glass frame 22 or on the viewing window 161 of the base 16. However, it is preferable to be mounted on the bottom of the glass frame 22 in order to prevent dust or foreign matter from flowing into the scanner 20.

In addition, the reflective layer 233 is provided to spread the light irradiated from the lighting module 25 evenly over the entire surface of the glass 232, it may be coated through a silk printing or optical printing method. Since the reflective layer 233 is formed, light is not evenly transmitted to the edge area of the glass 232, that is, the edge area of the scan area, or the light is relatively opposite to the side to which light is irradiated from the lighting module 25. This can prevent the phenomenon of not reaching much. To this end, the lighting module 25 is located at a position such that the light is diffused from the lighting module 25 and the field of light illumination irradiated to the glass 232 is larger than the area of the glass 232. It is better to be equipped. Then, the light leaving the glass 232 hits the reflective layer 233 and is reflected back into the glass 232. In addition, the light irradiated from the lighting module 25 and transmitted to the outer region of the glass 232 is reflected by the reflective layer 233 and irradiated to the opposite side. Accordingly, since light is sufficiently transmitted from the light source to an area opposite to the area irradiated with light, there is an advantage in that the luminance is uniform throughout the scan area.

Meanwhile, a front surface of the housing 21 is formed to be obliquely inclined, and a mirror hole 211 is formed in the inclined front surface. In addition, the mirror module 24 is mounted in the mirror hole 211. The reason that the mirror module 24 is mounted at an angle is to reflect the image transmitted from the glass 232 toward the camera module 22.

In detail, the mirror module 25 is seated on a step portion 212 surrounding the edge of the mirror hole 211, and the mirror module 25 has a sized mirror corresponding to the mirror hole 211 ( 242 and a supporter 241 supporting the mirror 242. The step portion 212 is formed so that the front edge of the mirror 242 is in close contact with each other with a predetermined width, so that a force is not applied only to a specific portion of the mirror 242. In addition, by pressing the entire rear surface of the mirror 242 by the supporter 241 with a uniform force, the mirror 242 is bent by the non-uniform pressing force and the scan screen imaged by the camera module 22 is displayed. The phenomenon of distortion does not occur.

In addition, the light irradiated from the illumination module 25 is reflected multiple times on the inner space of the scanner 20, that is, an optical path. In this process, when the light irradiated from the lighting module 25 is irradiated onto the mirror 242 or the glass 232 and then projected onto the camera module 22, the lighting module 25 is transferred to the camera module ( 22), a ghost phenomenon may occur. The ghost phenomenon refers to a phenomenon in which a light source is directly visible on the upper surface of the glass, and a light source formed on the upper surface of the glass is formed on the camera module 22, and strong light emitted from the light source is directly formed on the camera module 22 It is also called a hot spot phenomenon that becomes white.

The scanner 20 according to an embodiment of the present invention is characterized in that a means for removing the ghost phenomenon or hot spot phenomenon as described above is provided.

In detail, as shown in FIG. 4, a barrier 26 for preventing the ghost phenomenon protrudes from the inner upper surface of the housing 21 in a rib shape. The barrier 26 may be provided in the form of a rib protruding downward by a predetermined length from the upper surface of the housing 21. In addition, the barrier 26 is disposed in front of a point where the light source 251 (to be described later) of the lighting module 25 is installed. In addition, the barrier 26 is formed in an L shape in which one side of the rib is stepped in a rectangular shape, so as to block light directly reflected on the glass 232 and to minimize blocking of light that contributes to ensuring uniform luminance. do.

On the other hand, the lighting module 25 includes a pair of light sources 251, a substrate 252 on which the light source 251 is mounted, and a diffusion lens 253 covered on the front surface of the light source 251 can do.

In detail, the light source 251 includes an LED element, and may be mounted one by one on the left side and the right side. In addition, the diffusion lens 253 is mounted to increase a diffusion angle of light emitted from the light source 251. In addition, the substrate 252 is mounted slightly at an angle so that light sufficiently reaches the glass 232. Since the light source 251 is mounted at an angle at a point spaced laterally from the glass 232, the light movement distance is increased compared to the case where the light is located directly above the glass 232, and the mouse 10 There is an advantage that the volume can be minimized. In addition, since the light source 251 is disposed at a position away from the direct upper side of the glass 232, the light irradiated from the light source 251 is directly condensed on the glass 232 to cause a ghost phenomenon or a hot spot phenomenon. Can be prevented.

In addition, the camera module 22 includes a camera 221 for photographing an image to be scanned reflected by the mirror 242 and a substrate 222 to which the camera 222 is attached.

The camera 221 is mounted on a side of the housing 21 corresponding to the opposite side of the mirror 242 while being mounted on the front surface of the substrate 222. Accordingly, the object to be scanned under the glass 232 is reflected by the mirror 242 and an image is formed on the image sensor of the camera 221.

Hereinafter, a function of the barrier 26 for preventing light movement and ghosting occurring inside the scanner 20, that is, on an optical path, will be described in detail with reference to the drawings.

5 is a cross-sectional view taken along line II of FIG. 3, and FIG. 6 is a perspective view taken along line line II of FIG. 3.

5 and 6, light emitted from the light source 251 is diffused while passing through the diffusing lens 253 and is mostly irradiated toward the glass 232.

In detail, the light (e1, e2) irradiated from the light source 251 directly hits the glass 232 or is reflected from the mirror 242 and transmitted to the glass 232. In addition, by the diffusion lens 253, an area of light irradiated from the light source 251 to the upper surface of the glass 232 is larger than the area of the glass 232. That is, part of the light diffused by the diffusion lens 253 is also irradiated to the reflective layer 233. In addition, the light irradiated to the reflective layer 233 is reflected to the edge region of the glass 232 to minimize the darkened region inside the glass 232 so that the luminance is uniformly maintained.

In addition, since the inner circumferential surface of the housing 21 is textured, and an antireflection film is formed on the glass 232 and the mirror 242, light hitting the inner circumferential surface of the housing 21 or the glass 232 or the Light directly irradiated to the mirror 242 is reflected again to prevent a phenomenon that is formed on the camera 27. Therefore, it minimizes the occurrence of ghost phenomenon in which light is blurred.

Nevertheless, some of the light irradiated from the light source 251 may be reflected from the mirror 242 and the glass 232 and transmitted to the camera module 22, and as a result, there is a possibility that a ghost phenomenon may occur. have.

To block this possibility, the barrier 26 is used.

The optical paths e3 and e4 indicated by dotted lines in FIG. 5 are optical paths that cause ghosting in the camera 221. Such a ghost phenomenon-inducing beam is blocked by the barrier 26 to block condensation on the camera 221. In addition, the light passing through the stepped portion of the barrier 26 uniformizes the luminance of light inside the housing 21.

Meanwhile, in the case of a mouse scanner, an image stitching operation (or image merging operation) is performed in which the object to be scanned is photographed in several pieces while moving in the front and rear, left and right directions, and then merged to complete the same image as the original to be scanned.

In detail, the image stitching process is performed by an image stitching algorithm, and the minimum size of an image capable of image stitching is limited.

For this, image stitching, the coordinates of the mouse movement are recognized using two mouse sensors 17, and when the scan window, that is, the perspective window 161 is a rectangle rather than a square, the mouse There is a characteristic that normal scan is possible even for curve movement. In other words, when the scan window is square, there is a limitation in that the merging of images captured during the curve movement of the mouse cannot be performed normally. Accordingly, a rectangular scan window having a vertical width greater than a horizontal width is advantageous. In this case, the horizontal width of the scan window must be at least 15 mm and the horizontal width must be at least 40 mm to enable high-accuracy image merging. In the case of a scan window below the above value, the image merging rate may decrease.

Under this premise, the optical path of the scanned image set inside the scanner 20, that is, the minimum value of the mirror 242 (sum of path A and path B in FIG. 5) from the glass 232 is about 43.2 mm. It was obtained through an experiment that is optimal. If the optical path is shorter than this, the size of the captured image decreases, and if the size of the image is too small, image stitching may become difficult. In addition, when the size of the scanner 20 is made smaller and the optical path is shorter than 43.2 mm, the light emitted from the light source 251 is reflected to the camera 221, resulting in a problem that the ghost phenomenon is severe. . Therefore, the 43.2mm optical path can be defined as the minimum distance for image stitching.

7 is a view showing a mirror and glass of a scanner according to an embodiment of the present invention.

Referring to FIG. 7, a reflective layer 233 is formed inside the glass frame 231 constituting the glass module 23 of the scanner 20 according to an embodiment of the present invention, so that the edge of the scanned image is darkened. I tried to minimize the phenomenon.

In addition, the size of the mirror 242 of the present invention is formed to be larger than the area of the field of view 242a of the camera 221 to increase the luminance uniformity. In detail, conventionally, the size of the mirror was designed to be substantially the same as the field of view of the camera, and the mirror was used only for changing the optical path toward the camera. However, in the present invention, by making the area of the mirror 242 larger than the area of the field of view 242a of the camera 221, the edge area 242b of the mirror 242 corresponding to the outside of the field of view of the camera 221 ) So that the light hitting the glass is reflected to the glass 232. Then, the luminance of the edge portion of the glass 232 is secured, and there is an effect of preventing the edge of the scanned image from appearing dark.

Claims (9)

In a mouse equipped with a scan function,
A case including a base having a scan window and a cover member coupled to an upper surface of the base;
A scan button provided on one side of the case; And
A scanner accommodated in the case and seated in the scan window,
The scanner,
A housing forming an optical path therein;
A glass module mounted on the lower side of the housing and coupled to the scan window;
A mirror module mounted on one side of the upper portion of the housing and reflecting the scanned image transmitted from the glass module;
A camera module mounted on a side surface of the housing corresponding to the opposite side of the mirror module to photograph an image reflected from the mirror module;
A lighting module mounted on the inner upper side of the housing spaced apart from the camera module; And
A mouse including a barrier disposed in a form protruding downward from an upper surface of the housing corresponding to the front of the lighting module, and blocking light reflected from the inside of the housing and reflected on the camera module. The method of claim 1,
The lighting module includes a pair of LED light sources,
The barrier is a mouse, characterized in that provided on each of the front side of the LED light source. The method of claim 2,
A mouse, characterized in that one part of the lower part of the barrier is stepped lower than the other part. The method of claim 1,
The mirror module includes a mirror that reflects light,
Wherein the mirror is mounted at an angle to the housing and is formed to reflect the scanned image transmitted from the glass module to the camera module. The method of claim 4,
The mouse, characterized in that the mirror is formed larger than the field of view of the camera module so that the light transmitted to the edge of the mirror corresponding to the outside of the field of view of the camera module is reflected to the glass module. The method of claim 1,
A mouse, characterized in that the sum of the first optical path from the glass module to the mirror module and the second optical path from the mirror module to the camera module is 43.2 mm. The method of claim 1,
The glass module,
With transparent glass,
It includes a glass frame on which the glass is mounted on the bottom surface,
A mouse, characterized in that a reflective layer is formed on the inner circumferential surface of the glass frame. The method of claim 7,
Mouse further comprising an anti-reflection film coated on the glass. The method of claim 4,
Mouse further comprising an anti-reflection film coated on the mirror.

Images