KR20150052987A - Mirror apparatus for taking side-by-side stereo images - Google Patents

Abstract

A mirror apparatus for taking side-by-side stereo images is provided. The mirror apparatus comprises a dual reflector structure body including two separated left side reflectors facing each other slant at similar angles, and two separated right side reflectors facing each other slant at similar angles; a combine unit which combines the dual reflector structure body as releasable from a smart phone, arranged with a camera lens of the smart phone. A first light from a front object, which is reflected two times while passing by the two left side reflectors and a second light from a front subject, reflected two times while passing by the two right side reflectors, pass through the camera lens and is imaged in side-by-side shape images by an image sensor.

Description

[0001] The present invention relates to a mirror apparatus for taking a side-by-side stereo image,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a reflector device for stereoscopic imaging, and more particularly, to a reflector device capable of capturing a side by side stereo image with a camera of a smartphone employing a monopole lens.

3D stereoscopic images are costly and time consuming. In order to produce a three-dimensional image, a three-dimensional camera and a program different from a general two-dimensional camera are required. Three-dimensional (2D) cameras are generally expensive because of the complexity of the equipment, such as two lenses, and the technology of shooting is more complicated than that of ordinary cameras. Therefore, it was not easy for ordinary users to make stereoscopic images.

Recently, with the spread of smartphones, photographing and video shooting using a camera mounted on a smartphone are becoming popular. Such a digital camera or a smart phone is a single lens camera in which almost all of a single lens is used, and a captured image is a two-dimensional image. In particular, in the case of small devices such as smart phones, what is required in the design is to reduce the size and number of parts employed therein as much as possible. The design that employs two lenses to construct a 3-Dimensional (3D) camera on a smartphone is against this purpose. In addition, the adoption of two lenses is a factor of increasing the price of smartphone.

If a stereoscopic image can be easily produced with a single-frame camera, the production of three-dimensional stereoscopic images may increase rapidly. A typical method of photographing a three-dimensional stereoscopic image with a single camera is to generate a side-by-side stereo image. The human brain recognizes the depth of the image (difference in depth) due to differences in the images received from both eyes. In order to feel the stereoscopic effect on the image of the same object, it is necessary to show an image with a difference in the eyes of the viewer, and also an image which varies according to the distance of the object. In other words, by creating a side-by-side stereo image in which two different images having the same difference as the binocular disparity of a person are arranged on both sides, the two images are separately displayed in the left and right eyes of a person , The image is perceived in three dimensions.

One existing method of generating a side-by-side stereo image is to use a single reflector. A reflector is arranged on the side of the camera lens so as to be imaged on half of the image sensor of the camera of the image reflected by the reflector and the other half of the image sensor is directly imaged without passing through the reflector, Side stereoscopic image is generated by performing left-to-right conversion processing on the image using a dedicated program.

However, this method requires a separate program for such processing because it requires a process of correctly transforming the left and right inverted image by the reflector. It is troublesome because additional work such as creation of the program and installation on the user's smartphone is necessary. In addition, the battery consumption of the smartphone increases due to the execution of the program for real-time processing of the image conversion. The CPU is also required to have the ability to handle real-time processing of such image transformations.

The present invention has been made to solve the above-mentioned problems and disadvantages, and it is an object of the present invention to provide a video camera which is mounted on a single-lens camera having only one lens, And it is an object of the present invention to provide a reflector device with a simple structure that allows a stereo image to be captured.

According to an aspect of the present invention, each of the mirror surfaces is inclined at a distance from the upper side to the lower side while facing each other on the opposite side with respect to a virtual vertical plane. And first and second planar outer mirrors arranged in a state in which each of the mirror surfaces faces the mirror surfaces of the first and second outer reflectors in opposite directions and each lower side meets in the virtual vertical plane, And a reflecting mirror support for supporting the first and second outside reflecting mirrors and the first and second inside reflecting mirrors in a state of being arranged in an inclined manner A double mirror structure; And a coupling unit detachably coupling the double-reflecting mirror structure to the digital camera apparatus in a state of being aligned with a camera lens of the digital camera apparatus, wherein the double reflection mirror structure includes a first reflection mirror and a second reflection mirror, And a second light beam emitted from the front object and reflected twice through the first light beam, the second light beam, the second inner mirror, and the second inner mirror passes through the camera lens, - a side stereo image is imaged.

The first inner reflector and the second inner reflector are preferably disposed at an angle of 45 +/- 3 degrees with respect to the virtual vertical plane. In particular, it is preferable that the first inner reflector and the second inner reflector are symmetrically arranged with respect to the virtual vertical plane.

The first outer reflector and the second outer reflector are preferably disposed at an angle of 35 to 45 degrees on both sides of the virtual vertical plane. In particular, it is preferable that the first outer reflector and the second outer reflector are symmetrically arranged with respect to the virtual vertical plane, respectively.

The double reflector structure may further include a transparent cover covering the open inlet between the first outside reflector and the second outside reflector so as to close the opening so as to prevent foreign matter from entering and to transmit light.

According to an exemplary embodiment, the coupling portion includes a base to which the double-reflecting mirror structure is coupled, and a grip portion for coupling the base to the body of the digital camera device. The base includes a first and a second inner reflector And a light transmission aperture having a size not smaller than that of the camera lens is provided in the lower right portion of the lower side of the camera lens.

Preferably, the coupling portion further includes a slide guide portion provided around both of the light transmission apertures to guide the double reflector structure so as to guide the double reflector structure in a slidable manner.

It is preferable that the first and second inner reflectors and the first and second outer reflectors are both rectangular. In this case, the height of the upper ends of the first and second inner reflectors is preferably not higher than the height of the upper ends of the first and second outer reflectors. This is because it is advantageous in capturing a subject in the front side as wide as possible and imaging it. The height of the lower ends of the first and second inner reflectors is preferably not lower than the height of the lower ends of the first and second outer reflectors. Otherwise, a gap may be generated between the left image and the right image captured by the image sensor of the camera module.

The virtual vertical plane is preferably a plane including the axis of the camera lens, and is a virtual plane bisecting the image sensor to the left and right.

The digital camera device may be provided as part of a smart phone or a tablet PC.

According to the present invention, 3D stereoscopic images can be taken even in a digital camera device having a monocular lens, typically a smartphone, so that the cost of shooting a 3D image can be significantly reduced. In particular, since it can be easily applied to a smartphone camera that most people have, it is expected that the generation of stereo image contents will be very active.

The reflector device of the present invention can easily generate a side-by-side stereo image. This is because it is not necessary to install a separate image conversion program and installs a reflector on a smart phone. Side-by-side stereo images can be taken only with the optical principle of double reflection using only four reflectors without the processing of artificial image conversion using software. Since the reflector device itself is a simple structure, it can be manufactured at a low cost, and the cost for generating the side-by-side stereo image can be reduced because no separate software is required.

When the reflector device of the present invention is used, no additional image conversion processing using a program is required, and therefore no additional burden is imposed on the CPU of the smartphone. In addition, it is not necessary to perform a CPU operation process for image conversion, thereby saving battery consumption.

The reflector device of the present invention is detachable and has the advantage of being able to take a side-by-side stereo image only when necessary.

1 is a perspective view showing a state in which a reflector device according to a preferred embodiment of the present invention is aligned with a smartphone camera in an aligned state,
FIG. 2 and FIG. 3 are perspective views showing a decomposed state of the reflector device according to a preferred embodiment of the present invention, as viewed in the lower diagonal direction and the upper diagonal direction,
4 (a) and 4 (b) are side views of a reflector device according to a preferred embodiment of the present invention in alignment with a smartphone camera,
5 is a view for explaining a principle of picking up a side-by-side stereo image by a reflector device according to a preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 illustratively show that the reflector device 100 according to a preferred embodiment of the present invention is mounted on a Samsung Galaxy S3 model of a smartphone.

The reflector device 100 includes a double reflecting mirror structure 130 and a coupling part for detachably coupling the dual mirror housing structure 130 and the camera lens 160 of the camera module 160 of the smartphone 140, 110).

The double reflector structure 130 includes two outer reflectors 131-1 and 131-2 and two inner reflectors 133-1 and 133-2 disposed therebetween.

The first and second outside mirrors 131-1 and 131-2 are planar mirrors, and the mirror planes are disposed facing each other with respect to the virtual vertical plane 150. Here, the virtual vertical plane 150 is a plane including the axis of the camera lens 162, and is a virtual plane bisecting the image sensor 164 of the camera module 160 to the left and right. The first and second outside mirrors 131-1 and 131-2 are preferably rectangular (square or square) mirrors. The first and second outside mirrors 131-1 and 131-2 are inclined so that the intervals between the upper and lower mirrors 131-1 and 131-2 become gradually narrower. That is, the first and second inner reflectors are inclined with respect to the imaginary vertical plane 150 while spreading from the lower side toward the upper side (closer to the subject). It is preferable that the first and second outer reflectors 131-1 and 131-2 are arranged symmetrically with respect to the virtual vertical plane 150. [ The angle between the virtual vertical plane 150 and the first outer reflector 131-1 is preferably set within a range of approximately 35 degrees to 45 degrees. The angle between the virtual vertical plane 150 and the second outer reflector 131-2 is the same. Most preferably, the first outer reflector 131-1 and the second outer reflector 131-2 are symmetrically disposed at an angle of 40 degrees with respect to the virtual vertical plane 150, respectively.

The first and second inner reflectors 133-1 and 133-2 are planar mirrors and the mirror surfaces of the first and second inner reflectors 133-1 and 133-2 are the first and second outer reflectors 131-1 and 131-2 Respectively. The first and second inner reflectors 133-1 and 133-2 are also preferably rectangular (rectangular or square) in shape. The lower sides of the two reflectors 133-1 and 133-2 are virtual vertical planes 150), the angle between the two is gradually widened. In other words, the first and second inner reflectors 133-1 and 133-2 are arranged in a V-shape when viewed from the side. It is preferable that the first inner reflecting mirror 133-1 is arranged to be inclined so as to form approximately 45 占 degrees with the virtual vertical plane 150. [ If the image sensor 164 is tilted to such an extent that it deviates from the angle range, the left and right imbalance between the images formed on the image sensor 164 becomes so severe that the quality of the stereoscopic image becomes worse. The same is true for the second inside reflecting mirror 133-2. Most preferably, the first inner reflector 133-1 and the second inner reflector 133-2 form an angle of 90 degrees. It is most preferable that the first inner reflecting mirror 133-1 and the second inner reflecting mirror 133-2 are symmetrically disposed at an angle of 45 degrees with respect to the virtual vertical plane 150. [

According to this arrangement, the two mirror surfaces of the first outside mirror 131-1 and the first inside mirror 133-1 are inclined in approximately the same direction (upper left room) while facing each other, and the second outside mirror 133- 1) and the second inner reflecting mirror 133-2 are also inclined in a similar direction (upper right room) and facing each other.

The double reflector structure 130 also includes a reflector support. This reflector support supports the arrangement of the first and second outside reflectors 131-1 and 131-2 and the first and second inside reflectors 133-1 and 133-2. Specifically, the reflector support includes two side walls 137-1 and 137-2 for supporting the first and second outer reflectors 131-1 and 131-2. The first side wall 137-1 connects the left edges of the first and second outer reflectors 131-1 and 131-2 with each other. The second side wall 137-2 connects the right edges of the first and second outer reflectors 131-1 and 131-2 with each other. These two side walls 137-1 and 137-2 face each other.

In addition, the reflector support also includes a support structure 135 for supporting the first and second inner reflectors 133-1, 133-2. This support structure 135 has two surfaces joined to the inner walls of the first and second side walls 137-2 and 137-2 and two surfaces joined to the inner surfaces of the first and second inner reflectors 133-1 and 133-2 And may be a polygonal structure including at least two joined surfaces.

The first and second inner reflectors 133-1 and 133-2 are not so high in height as compared to the upper ends of the first and second outer reflectors 131-1 and 131-2 desirable. Otherwise, the front subject is covered by the upper ends of the first and second inner reflectors 133-1 and 133-2, narrowing the range of the subject imaged by the image sensor 164 of the camera. It is preferable that the lower end height of the inner reflectors 133-1 and 133-2 is not lower than the lower end heights of the outer reflectors 131-1 and 131-2. Otherwise, there may be a gap between the two images on the left and right sides of the image sensor 164. The height mentioned here means the height in the axial direction of the camera lens 162. [

 The entrance between the first inner reflector 131-1 and the first outer reflector 133-1 and the entrance between the second inner reflector 131-2 and the second outer reflector 133-2 are maximally wide, It is preferable that the upper portion of the upper portion 135 is chamfered.

According to this arrangement, between the first outer reflector 131-1 and the first inner reflector 133-1, between the second outer reflector 131-2 and the second inner reflector 133-2, Passages 138-1 and 138-2 are provided. The two light propagation paths 138-1 and 138-2 are symmetrical with respect to the virtual vertical plane 150 and are inclined in opposite directions to each other.

The double reflector structure 130 covers the open upper end opening between the first outside reflector 131-1 and the second outside reflector 131-2 so as to prevent foreign substances from entering the transparent cover 139 ).

The coupling unit 110 includes a base 121 to which the dual reflector structure 130 is coupled and a gripper 127 for coupling the base 121 to the body of the smartphone 140. The base 121 is provided with a light transmission aperture 125 having a size not smaller than that of the camera lens 162 in the lower right portion of the lower side of the first and second inner reflectors 133-1 and 133-2. On both sides of the opening 125, a slide guide 123 is provided, for example, in the form of a groove or a projection. Correspondingly, protrusions or grooves are provided at the lower end portions of the two side walls 137-1 and 137-2 so as to be engaged with the slide guide portion 123 to be slidably guided. By the slide guide part 123, the engaging part 110 guides the double reflecting mirror structure 130 while slidably guiding it.

The base 121 has a length corresponding to the width of the portion where the camera module 142 of the smartphone 140 is located. The grip portion 127 is provided in the form of being vertically bent downward at both side ends of the base portion 121. [ It is preferable that a protrusion for increasing the gripping force of the smartphone 140 with respect to the body is formed at the end of the grip portion 127 or a rubber or urethane pad having a good gripping force is applied.

The coupling part 110 is preferably made of an elastic material. And can be elastically applied to slightly different sizes of the smartphone 140 due to the elastic force of the coupling portion 110 itself. Although only one gripping portion 127 is shown in the drawing, a plurality of gripping portions may be provided to obtain a stable gripping force.

The engaging portion 110 having such a structure captures the body of the smartphone 140, whereby the double reflector structure 130 is combined with the smartphone 140. The engaging portion 110 may be engaged or disengaged from the body of the smartphone 140 when the user needs it. Whereby the reflector device 100 can be detachably coupled to the smartphone 140. [

Next, the principle of causing the reflector device 100 of the present invention to image the side-by-side stereo image to the image sensor 164 will be described with reference to FIG.

The user inserts the engaging portion 110 into the smartphone 140 so that the aperture 125 is aligned directly above the camera lens 162 of the smartphone 140 while the double reflecting mirror structure 130 is slidably engaged with the engaging portion 110. [ Lt; / RTI > In this arrangement, fine adjustment for accurate alignment between the double reflector structure 130 and the camera lens 162 can be performed while viewing the image displayed on the display screen 141 of the smartphone 140. That is, the image of the light beam incident through the first light propagation path 138-1 and the light beam incident through the second light propagation path 138-2 is displayed on the left half of the display screen 141 The position of the coupling part 110 and the coupling position of the double reflecting mirror structure 130 with respect to the coupling part 110 may be finely adjusted so as to respectively occupy the right and left sides 141-1 and 141-2. A virtual screen dividing line 162 for dividing the display screen 141 left and right may be displayed by using an application program, for example, in order to accurately align the double mirror system 130 and the camera lens 162. [

The left half 141-1 and the right half 141-2 of the display screen 141 have two images having deviations corresponding to the binocular parallaxes in a state in which alignment between the double reflector structure 130 and the camera lens 162 is performed, Respectively. The images displayed on the left half 141-1 and the right half 141-2 of the display screen 141 are images picked up in the left half and the right half of the image sensor 164, respectively. The image formed on the left half of the image sensor 164 is reflected by the light ray passing through the first light propagation path 138-1 between the first outside reflector 131-1 and the first inside reflector 133-1 And an image formed on the right half of the image sensor 164 is transmitted to the light ray passing through the second light propagation path 138-2 between the second outside reflector 131-2 and the second inside reflector 133-2 .

A light ray incident on the first light propagation path 138-1 out of the light rays coming from the object is first incident on the first outer reflector 131-1 as shown in FIG. The image of the reflected ray is reversed right and left. The reflected light is incident on the first inner reflecting mirror 133-1 and then reflected again. At this time, the image due to the reflected light is reversed left and right so that it coincides with the original left and right of the subject. The light beams reflected twice by the two reflectors 131-1 and 133-1 are refracted while passing through the camera lens 162 disposed at the lower side to form an image on the left half of the image sensor 164.

The light rays of the object incident on the second light propagation path 138-2 are also subjected to the same process. That is, the light rays of the subject are successively reflected by the second outside reflecting mirror 131-2 and the second inside reflecting mirror 133-2 (the left and right images of the reflected light at this time coincide with the left and right sides of the subject) Refracted while passing through the camera lens 162, and forms an image on the right half of the image sensor 164.

The two light beams, which pass through the first light path 138-1 and the second light path 138-2 and are incident on the camera lens 162, respectively undergo two reflections, . Therefore, there is no need to artificially perform the left-right conversion through the program of the image formed on the image sensor 164. At the same time, the two light beams, which pass through the first light propagation path 138-1 and the second light propagation path 138-2 and are respectively incident on the right and left halves of the image sensor 164 through the camera lens 162, And has a deviation corresponding to the time difference. Therefore, the images of the two light beams incident on the right and left halves of the image sensor 164 become a side-by-side stereo image. In the case of playing back the image thus picked up, it is displayed in the left half 141-1 and the right half 141-2 of the display screen 141, respectively. In other words, a side-by-side stereo image having a deviation corresponding to the binocular parallax appears on the display screen 141.

When the user views the side-by-side stereo image through the stereoscope, the image displayed on the left half 141-1 of the display screen 141 is displayed on the left eye and the image displayed on the right half 9141-2 is displayed on the right eye I will see. The two images entered by the two eyes are perceived as a stereoscopic image that can be sure of the depth of the space by being made into a stereoscopic image in the brain of the person.

Although the reflector device 100 of the present invention is applied to the smartphone 140 as described above, the present invention is not limited to a smart phone, but can be applied to any digital camera device employing a simple lens . However, the structure of the coupling portion 110 also needs to be adaptively designed to be adapted to the structure of the application target.

The shape of the reflecting mirrors 131-1, 131-2, 133-1, and 133-2 is most preferably a rectangle, but is not limited to that shape and may be any other shape. The sizes and shapes of the reflectors 131-1, 131-2, 133-1 and 133-2 are such that the first and second inner and outer reflectors 131-1 and 133-1 are located on the right half of the image sensor 164, The first and second inner and outer mirrors 131-2 and 133-2 can also take various images if they satisfy the condition that images are formed only on the right half of the image sensor 164 will be.

The present invention described above is merely a preferred embodiment of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the following claims. It is therefore intended that all changes which come within the meaning and range of equivalency of the claims are intended to be embraced therein.

The present invention can be widely used for photographing a 3D stereoscopic image by applying to a smartphone camera, a digital camera, or the like.

100: reflector device 110:
130: double reflector structure 131-1, 131-2: first and second outside reflectors
133-1 and 133-2: first and second inner reflectors
140: Smartphone 150: virtual vertical plane
160: Camera module

Claims (13)

First and second planar first and second outer reflectors disposed obliquely with their respective mirror planes facing each other with their imaginary vertical planes facing each other while being spaced apart from each other by a distance from the upper side to the lower side, A planar shape in which the mirror faces face toward the opposite side and the mirror faces of the first and second outside reflectors are facing each other and the lower side thereof is in the virtual vertical plane, 1 and a second inside reflector, and a reflecting mirror support for supporting the first and second outside reflecting mirrors and the first and second inside reflecting mirrors; And
And a coupling unit detachably coupling the double-reflecting mirror structure to the digital camera device in an aligned state with a camera lens of the digital camera device,
A first light beam from the front subject reflected twice through the first outer reflector and the first inner reflector and a second light beam from the front subject reflected twice through the second outer reflector and the second inner reflector, Side stereoscopic image to the image sensor of the digital camera apparatus through the camera lens so as to capture a side-by-side stereo image. 2. The reflector device according to claim 1, wherein the first inner reflector and the second inner reflector are disposed at an angle of 45 +/- 3 degrees with respect to the virtual vertical plane, respectively. 3. The reflector device according to claim 2, wherein the first inner reflector and the second inner reflector are symmetrically arranged with respect to the virtual vertical plane. 2. The reflector device according to claim 1, wherein the first outside reflector and the second outside reflector are inclined at 35-45 degrees with respect to the virtual vertical plane, respectively. 5. The reflector apparatus according to claim 4, wherein the first outer reflector and the second outer reflector are symmetrically arranged with respect to the virtual vertical plane, respectively. The double-reflecting mirror structure according to claim 1, further comprising a transparent cover covering the open inlet between the first outside reflector and the second outside reflector so as to close the opening so as to prevent foreign matter from entering, . 2. The digital camera apparatus according to claim 1, wherein the coupling portion includes a base to which the double-reflecting mirror structure is coupled and a holding portion to couple the base to the body of the digital camera device, Wherein a light transmitting opening having a size not smaller than that of the camera lens is provided in a lower right portion of the lower side of the reflector. 8. The reflector device according to claim 7, wherein the coupling portion further includes a slide guide portion provided on both sides of the light transmission opening to guide the double reflector structure so as to guide the double reflector structure in a slidable manner. 2. The reflector device according to claim 1, wherein the first and second inner reflectors and the first and second outer reflectors are both rectangular. 10. The reflector apparatus according to claim 9, wherein the height of the upper ends of the first and second inner reflectors is not higher than the height of the upper ends of the first and second outer reflectors. 10. The reflector device according to claim 9, wherein the height of the lower ends of the first and second inner reflectors is not lower than the height of the lower ends of the first and second outer reflectors. 2. The reflector apparatus according to claim 1, wherein the virtual vertical plane is a plane including an axis of a camera lens, and is a virtual plane bisecting the image sensor to the left and right. The reflector device of claim 1, wherein the digital camera device is provided as part of a smartphone or a tablet PC.

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