Technical Field This invention relates to stereopsis motion-picture photography and, in particular, it is capable of photographing stereopsis images on a Digital Image Sensor which may be processed and projected to give the viewer a three-dimensional perception of the original scene and this ground-breaking technology will propel the future of cinema viewing experience into a new dimension

Background Art In traditional 3D methods, simultaneously, one or more 2D Cameras basically serve to record and preserve the scenes that are viewed through their lenses. Lenses are designed to collect light reflecting off the subject and transmit it to CCD or a similar type of image sensor. 2D photographs are recorded with the definitions of focus are: 1) the position at which rays of light from a lens converges to form a clear and sharply defined image on a focal plane. 2) The action of adjusting the distance between the lens and subject to make light rays converge to form a clear and sharply defined image of the subject. Image intensifier or image intensifier tube facilitates the acceptable image quality under low-light conditions. Recorded images are processed for exhibiting to feel 3D illusion by means of either stereoscope 3D or Anaglyph 3D or Polarized 3D or alternate-frame sequencing 3D method or Active-shutter 3D. With respect to the adopted 3D methodology from traditional 3D methods, stereopsis as depth perception is achieved over presenting the two offset images separately to the left and right eye of the viewer. When a visually normal human being looks at these images, each eye sees it from a slightly different angle and sends these images to the brain. The differences between the two images are integrated into a single one, and the differences are used to get the 3D illusion. Stereoscope 3D, Anaglyph 3D, Polarized 3D, Alternate-frame sequencing 3D method, and Active-shutter 3D methods result in visual discomfort to observers. This has been a longstanding problem in stereoscopic research. According to the medical definition, it is necessary to view images with both eyes synchronously in order to create a single visual image and feel the depth perception. Wiggle 3D is one of the traditional 3D methods, Wiggle 3D is defined that the two images, left and right, are animated or alternately displayed on the screen in a particular frequency. This flickering of the two images, one after the other, creates a 3D image in the brain of the viewer. Hence the images look realistic and almost 3D, even on a regular display screen. No need for any special software or 3D glasses to view these images. Furthermore, it offers stereo-like depth also to people with limited or no vision in one eye. The sense of depth from wiggle 3-D images is due to parallax and to changes to the occlusion of background objects.

SUBSTITUTE SHEETS (RULE 26) Parallax is an apparent displacement or difference in the apparent position of an object viewed along two different lines of sight and is measured by the angle or semi-angle of inclination between those two lines. Nearby objects have a larger parallax than more distant objects when observed from different positions, so parallax can be used to determine distances. The Image if the lens is partly covered with a black sheet, while covering any part of a simple convex lens or complex camera lens forms the fainter image. Effectively the covered part is cutting out the light rays proportionally, but lenses still produce an entire image with limited intensity.

Summary of Invention The present invention provides the stereopsis camera and stereopsis camera accessories, which are capable to record Left and right side Images with common midground but time-based different foreground and background, these recorded common midground images are free from parallax errors. The present invention provides as one aspect thereof a stereopsis camera accessory as "stereoscope image filter" detachably attachable to the stereopsis camera. The stereoscope image filter includes an accessory mount to be detachably coupled with a camera mount provided in the stereopsis camera. The present invention provides as another aspect thereof a stereopsis camera accessory as "Anaglyph stereoscope image filter" detachably attachable to stereopsis camera. The Anaglyph stereoscope image filter includes an accessory mount to be detachably coupled with a camera mount provided in the stereopsis camera. The present invention provides as another aspect thereof a stereopsis camera accessory as "Liquid crystal stereoscope image filter" detachably attachable to the stereopsis camera. The Liquid crystal stereoscope image filter includes an accessory mount to be detachably coupled with a camera mount provided in the stereopsis camera. The present invention provides as still another aspect thereof a stereopsis camera accessory as "Anaglyph stereoscope image filter for Print Media" detachably attachable to a stereopsis camera. The Anaglyph stereoscope image filter for Print Media includes an accessory mount to be detachably coupled with a camera mount provided in the stereopsis camera. Other aspects of the present invention will become apparent from the following description and the attached drawings.

Brief Description of Drawings Figure 1 illustrates a front view of the stereopsis camera of an architectural model for motion picture according to one embodiment of the present invention Figure 2 illustrates a plan view of the stereopsis camera of an architectural model for motion picture according to one embodiment of the present invention

SUBSTITUTE SHEETS (RULE 26) Figure 3 illustrates a right side view of the stereopsis camera of an architectural model for motion picture according to one embodiment of the present invention

Figure 4 illustrates a left side view of the stereopsis camera of an architectural model for motion picture according to one embodiment of the present invention

Figure 5 illustrates a front view of the stereopsis camera accessory as "stereoscope image filter" according to one embodiment of the present invention

Figure 6 illustrates a plan view of the stereopsis camera accessory as "stereoscope image filter" according to one embodiment of the present invention

Figure 7 illustrates a right side view of stereopsis camera accessory as "stereoscope image filter" according to one embodiment of the present invention

Figure 8 illustrates a left side view of stereopsis camera accessory as "stereoscope image filter" according to one embodiment of the present invention

Figure 9 illustrates a front view of the stereopsis camera accessory as "Anaglyph stereoscope image filter" according to one embodiment of the present invention

Figure 10 illustrates a plan view of the stereopsis camera accessory as "Anaglyph stereoscope image filter" according to one embodiment of the present invention

Figure 11 illustrates a right side view of stereopsis camera accessory as "Anaglyph stereoscope image filter" according to one embodiment of the present invention

Figure 12 illustrates a left side view of stereopsis camera accessory as "Anaglyph stereoscope image filter" according to one embodiment of the present invention

Figure 13 illustrates a front view of the stereopsis camera accessory as "Liquid crystal stereoscope image filter" according to one embodiment of the present invention

Figure 14 illustrates a plan view of the stereopsis camera accessory as "Liquid crystal stereoscope image filter" according to one embodiment of the present invention

Figure 15 illustrates a right side view of stereopsis camera accessory as "Liquid crystal stereoscope image filter" according to one embodiment of the present invention

Figure 16 illustrates a left side view of stereopsis camera accessory as "Liquid crystal stereoscope image filter" according to one embodiment of the present invention

Figure 17 illustrates a front view of the stereopsis camera accessory as "Anaglyph stereoscope image filter for Print Media" according to one embodiment of the present invention

Figure 18 illustrates a plan view of the stereopsis camera accessory as "Anaglyph stereoscope image filter for Print Media" according to one embodiment of the present invention

Figure 19 illustrates a right side view of stereopsis camera accessory as "Anaglyph stereoscope image filter for Print Media" according to one embodiment of the present invention

SUBSTITUTE SHEETS (RULE 26) Figure 20 illustrates a left side view of stereopsis camera accessory as "Anaglyph stereoscope image filter for Print Media" according to one embodiment of the present invention

Figure 21 illustrates a plan view of the stereopsis camera in a coupling completion state with a stereoscope image filter with an example scene layout including the plane of focus according to one embodiment of the present invention

Figure 22 illustrates a right side view of the stereopsis camera in coordinating with Figure 21

Figure 23 illustrates a plan view of the stereopsis camera in a coupling completion state with stereoscope image filter indicates the shutter at an alternate location with an example scene layout including the plane of focus according to one embodiment of the present invention

Figure 24 illustrates a right side view of the stereopsis camera in coordinating with Figure 23

Figure 25 illustrates a plan view of the stereopsis camera in a coupling completion state with Anaglyph stereoscope image filter with an example scene layout including the plane of focus according to one embodiment of the present invention

Figure 26 illustrates a right side view of the stereopsis camera in coordinating with Figure 25

Figure 27 illustrates a plan view of the stereopsis camera in a coupling completion state with Anaglyph stereoscope image filter indicates the shutter at an alternate location with an example scene layout including the plane of focus according to one embodiment of the present invention

Figure 28 illustrates a right side view of the stereopsis camera in coordinating with Figure 27

Figure 29 illustrates a plan view of the stereopsis camera in a coupling completion state with Liquid crystal stereoscope image filter with an example scene layout including the plane of focus according to one embodiment of the present invention

Figure 30 illustrates a right side view of the stereopsis camera in coordinating with Figure 29

Figure 31 illustrates a plan view of the stereopsis camera in a coupling completion state with Liquid crystal stereoscope image filter indicates the shutter is in an open position at an alternate location with an example scene layout including the plane of focus according to one embodiment of the present invention

Figure 32 illustrates a right side view of the stereopsis camera in coordinating with Figure 31

Figure 33 illustrates a plan view of the stereopsis camera in a coupling completion state with Anaglyph stereoscope image filter for Print Media with an example scene layout including the plane of focus according to one embodiment of the present invention

Figure 34 illustrates a right side view of the stereopsis camera in coordinating with Figure 33

Figure 35 illustrates a plan view of the stereopsis camera for Print Media with an example scene layout including the plane of focus according to one embodiment of the present invention

SUBSTITUTE SHEETS (RULE 26) Figure 36 illustrates a right side view of the stereopsis camera in coordinating with Figure 35 Figure 37 illustrates a right side view rotated right 90 of stereopsis camera in coordinating with

Figure 21 Figure 38 illustrates stereopsis at "coordinate axis system" of an object depth in coordinating with Figure 21 Figure 39 illustrates a right side view rotated right 90 of stereopsis camera in coordinating with Figure 23 Figure 40 illustrates stereopsis at "coordinate axis system" of an object depth in coordinating with Figure 23 Figure 41 illustrates a right side view rotated right 90 of stereopsis camera in coordinating with Figure 25 Figure 42 illustrates stereopsis at "coordinate axis system" of an object depth in coordinating with Figure 25 Figure 43 illustrates a right side view rotated right 90 of stereopsis camera in coordinating with Figure 27 Figure 44 illustrates stereopsis at "coordinate axis system" of an object depth in coordinating with Figure 27 Figure 45 illustrates a right side view rotated right 90 of stereopsis camera in coordinating with Figure 29 Figure 46 illustrates stereopsis at "coordinate axis system" of an object depth in coordinating with Figure 29 Figure 47 illustrates a right side view rotated right 90 of stereopsis camera in coordinating with Figure 31 Figure 48 illustrates stereopsis at "coordinate axis system" of an object depth in coordinating with Figure 31 Figure 49 illustrates a right side view rotated right 90 of stereopsis camera in coordinating with Figure 33 Figure 50 illustrates stereopsis at "coordinate axis system" of an object depth in coordinating with Figure 33 Figure 51 illustrates a right side view rotated right 90 of stereopsis camera in coordinating with Figure 35 Figure 52 illustrates stereopsis at "coordinate axis system" of an object depth in coordinating with Figure 35

Description of Embodiments

SUBSTITUTE SHEETS (RULE 26) 0066 These embodiments are mentioned not to limit or define the invention, but to provide examples of embodiments of the invention to aid understanding thereof. Embodiments are discussed in the detailed description, and further description of the invention is provided there. The advantages offered by the various embodiments of the present invention may be further understood by examining this specification.

0067 Hereinafter, embodiments of the present invention will be described with reference to the drawings and the like. Further, in all the drawings for explaining the present invention, those having the same part may be designated by the same reference numerals, and the repeated description thereof may be omitted.

0068 These and other features, aspects, and advantages of the present invention are better understood when the following Detailed Description is read with reference to the accompanying drawings.

0069 Figure 1 to 4 shows the stereopsis camera comprises Stereopsis Image Sensor, rear lens group, aperture, front lens group, stereoscopic image splitter, and Stereopsis Accessory female mount. Stereopsis Accessory female mount to which the accessories are as a stereoscope image filter, Anaglyph stereoscope image filter, Liquid crystal stereoscope image filter, Anaglyph stereoscope image filter for Print Media is detachably (that is, interchangeably) attachable over Stereopsis Accessory male mount. Which are embodiments of one of the present invention and other stereopsis camera accessories that are also included in other embodiments of the present invention.

0070 Figure 5 to 8 shows the accessory for stereopsis camera as a stereoscope image filter. Figure 21 to 24 shows stereopsis camera in a coupling completion state with stereoscope image filter and the midground object located at the plane of focus is focused by stereopsis camera and the stereopsis image is forming at Stereopsis Image Sensor. Simultaneously, In addition to common midground images, the time-based different background and foreground images of the left side and right of the optical axis also captured by the Stereopsis Image Sensor. These background and foreground images provide the Parallax. Time for background and foreground images is controlled by the shutter's position and the shutter is horizontally reciprocating in front of the Stereoscopic image Splitter. The shutter is reciprocating due to Crank and it is connected by a connecting rod. Crank is driven by Shutter variable speed drive, thus the way the shutter is reciprocating in front of Stereoscopic image Splitter.

0071 Stereoscopic image Splitter is a rectangle and thin opaque structure and permanently fixed in front of the front lens group as shown in subsequent figures. The shutter is a rectangle and thin opaque structure. It reciprocates at the Shutter frame. Shutter frame is the accessory for stereopsis camera as stereoscope image filter is detachably attachable over Stereopsis Accessory male mount. The role of the shutter is to stop the passage of light. The centre of the shutter frame coincides with the optical axis of the lens system. Physical dimensions for Stereoscopic image Splitter and Shutter are the measurement of thickness is very thin, the length is not less than the physical measurement of the diameter of the front lens and the measurement of breadth is between 25% and 50% of the physical measurement of the diameter of the front lens.

SUBSTITUTE SHEETS (RULE 26) 0072 The quality of stereopsis is increasing while reciprocation of shutter increases; however, the minimum frequency is not less than double the frame speed per second.

0073 Figure 37 to 40, illustrates stereopsis at the "coordinate axis system" of an object depth upon the position of the shutter. Accordingly, stereopsis is achieved and recorded to give the viewer a three-dimensional perception of the original scene even to people with limited or no vision in one eye.

0074 Figure 9 to 12 shows the accessory for stereopsis camera as Anaglyph stereoscope image filter. Figure 25 to 28 shows the stereopsis camera in a coupling completion state with an Anaglyph stereoscope image filter. It is placed the chromatically opposite colour filters in between the Stereoscopic image Splitter and Shutter to achieve Anaglyph 3D. Chromatically opposite colour filters in which the density of selected colour for filtering is increased gradually towards the optical axis as corrective measures to meet the uniform filtering at stereopsis images.

0075 Figure 41 to 44, illustrates stereopsis at the "coordinate axis system" of an object depth upon the position of the shutter. Accordingly, stereopsis is achieved and recorded to give the viewer a three-dimensional perception of the original scene while viewing as per Anaglyph 3D

0076 Figure 13 to 16 shows the accessory for stereopsis camera as Liquid crystal stereoscope image filter. Figure 29 to 32 shows the stereopsis camera in a coupling completion state with a Liquid crystal stereoscope image filter. Liquid crystal stereoscope image filter is the Liquid crystal shutter contains a liquid crystal layer which has the property of becoming opaque when the electrical signal is applied, being otherwise transparent and light allowed passing through. The liquid crystal stereoscope image filter is electronically controlled and achieved the reciprocation sequences.

0077 Figure 45 to 48, illustrates stereopsis at the "coordinate axis system" of an object depth upon the open position of Liquid crystal shutter. Accordingly, stereopsis is achieved and recorded to give the viewer a three-dimensional perception of the original scene even to people with limited or no vision in one eye.

0078 Figure 17 to 20 shows the accessory for stereopsis camera as Anaglyph stereoscope image filter for Print Media. Figure 33 to 34 shows the stereopsis camera in a coupling completion state with an Anaglyph stereoscope image filter for Print Media. It is placed the chromatically opposite colour filters in front of the Stereoscopic image Splitter to achieve Anaglyph 3D

0079 Figure 49 and 50, illustrates stereopsis at the "coordinate axis system" of an object depth at printing media and still photographs. Accordingly, stereopsis is achieved and printed to give the viewer a three-dimensional perception of the original scene while viewing as per Anaglyph 3D.

0080 Figure 51 and 52, illustrates stereopsis at the "coordinate axis system" of an object depth at printing media and still photographs. Accordingly, stereopsis is achieved and printed to give the viewer a three-dimensional perception of the original scene even to people with limited or no vision in one eye.

SUBSTITUTE SHEETS (RULE 26) 0081 Figure 41 to 44, illustrates stereopsis at the "coordinate axis system" of an object depth upon the position of the shutter. Accordingly, stereopsis is achieved and recorded to give the viewer a three-dimensional perception of the original scene while viewing as per Anaglyph 3D.

0082 Description of numbers referred to in figures:

0083 1. Stereopsis Camera Body

0084 2. Stereopsis Image Sensor

0085 3. View Finder

0086 4. Stereopsis Lens Mount

0087 5. Stereopsis Lens Body

0088 6. Stereoscopic image Splitter

0089 7. Stereopsis Accessory female mount

0090 8. Rear Lens Group

0091 9. Diaphragm

0092 10. Aperture

0093 11. Front Lens Group

0094 12. Stereopsis Accessory male mount

0095 13. Shutter Guide

0096 14. Shutter

0097 15. Blank Shutter

0098 16. Crank and Connecting Rod

0099 17. Shutter Variable Speed Drive

0100 18. Accessory Body

0101 19. Desired Colour Filters for Anaglyph 3D

0102 20. Liquid crystal shutter glasses

0103 21. LC Shutter electronic control unit

0104 22. Liquid crystal shutter Open Position

0105 23. Liquid crystal shutter Close Position

0106 24. Optical Axis

SUBSTITUTE SHEETS (RULE 26) 0107 25. Plane of Focus

0108 The foregoing description of embodiments of the invention has been presented only for the purpose of illustration and description and is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to explain the principles of the invention and their practical application so as to enable others skilled in the art to utilize the invention and various embodiments with various modifications as are suited to the particular use contemplated. For example, the principles of this invention can be applied to any camera lens element and the camera for 2D to stereopsis conversion or any other conversion that contributes to stereopsis image enhancement or conversion which facilitates artificially vision to produce the enhanced stereopsis images.

SUBSTITUTE SHEETS (RULE 26)