TWI411299B - Method of generating multiple different orientation images according to single image and apparatus thereof - Google Patents

Abstract

The present invention discloses a method of generating multiple different orientation images according to single image and an apparatus thereof. The apparatus comprises a frame, a display module, an image generating module and a control module. The display module is disposed in one side of the frame, and displays a plurality of reset images. The image generating module is disposed on the site that the frame facing the display module, and generates a plurality of images by optical half-reflecting each reset image. The control module is disposed in the frame, and overlays a plurality of assistant lines on each reset image to generate a plurality of assistant images. By adjusting the display site of each reset image on the display module, each adjacent assistant image could be moved according to the reset images until the adjacent assistant lines are aligned.

Description

Processing device and method for generating multiple images of different orientations in a single image

The present invention relates to an image processing apparatus and method, and more particularly to a processing apparatus and method for generating a plurality of different orientation images in a single image.

At present, image output devices familiar to the public, such as cathode ray tube (CRT) televisions, liquid crystal televisions, plasma televisions, three-gun projectors or single-head projectors, all display images on the same plane. If the movement exceeds a certain angle of view, the image presented by the image output device cannot be seen.

Moreover, in the Magic Theater, the Magic Theater is a large indoor theme entertainment product, and the Magic Theater is also called the "Phantom Performance Theater." It uses the unreal imaging technology, computer synthesis technology and optical reflection principle to make the stage real image and the image reflection object together to complete the performance of the theater form. In the theater system with real people performance and real stage, it can realize very strange, Unique, incredible performance effects, suitable for a variety of surreal style theme content. For example, the performer can suddenly appear and disappear on the stage without leaving traces; the flames and smog can be transformed into various miraculous objects, sometimes become well-behaved birds, and sometimes become dance crowds; A bird and so on.

However, the Magic Theater can only display the real scene and the reflection of the image on the plane at different depths of the stage. The audience cannot see the same real scene and the reflection of the image reflection from different angles. This has led to considerable restrictions on its use.

In summary, whether it is a traditional image output device, or a magical theater combining unreal imaging technology, computer synthesis technology and optical reflection principle, images can only be output on the same plane or planes of different depths, making the audience It is impossible to see the image from various angles, so it is necessary to solve this technical problem.

In view of the above-mentioned problems of the prior art, the object of the present invention is to provide a processing device and method for generating a plurality of images of different orientations in a single image, to solve the conventional image output device, or to combine the unreal imaging technology and the computer synthesis technology. The magical theater of the principle of optical reflection is that the image can only be output on the same plane or a plane of different depths, so that the viewer cannot see the technical problem of the image from various angles.

According to the purpose of the present invention, a processing device for generating a plurality of different orientation images by a single image includes a frame, a display module, an imaging module, and a control module. The frame is composed of an upper top portion, a lower bottom portion and a support body. One end of the support body is coupled to the upper top surface, and the other end of the support body is coupled to the lower bottom surface, and the upper top surface corresponds to the lower bottom surface. The display module is placed on one side of the frame and displays a plurality of reset images. The imaging module is composed of a plurality of imaging units, and adjacent sides of each imaging unit are connected to each other, and a ㄧ imaging space is formed between the two sides of the frame, and the two sides of each imaging unit connected to the frame have an angle in the imaging space. Each reset image is optically semi-reflected to form a plurality of imaged images. The control module is disposed in the frame, and the control module respectively stacks at least one auxiliary line on each reset image, so that the same auxiliary line is displayed on each of the imaged images, and further forms a plurality of auxiliary images, and adjusts adjacent ones. The display parameters of the image are reset to change the display position of each reset image in the display module, so that adjacent auxiliary images are moved along the imaging position of the imaging module.

The control module further includes a memory unit, a playback unit, a copy image unit, an image placement unit, and an image adjustment unit. The memory unit stores at least one original image data, and provides preset location data and edit location data corresponding to each reset image. The playback unit is connected to the memory unit and plays the original image data in background playback to generate a background playback image. The copy image unit is connected to the playback unit, and the background playback image is copied to form a plurality of duplicate images. The image placement unit is connected to the copy image unit and the display module, and one of the preset position data and the edit position data is inverted, and each of the duplicate images is formed in the display module to form each reset image. The image adjusting unit is connected to the memory unit and the image placing unit, and receives at least one adjustment command, and at least one auxiliary line is respectively stacked on each of the reset images, so that the same auxiliary line is displayed on each of the imaged images, and the auxiliary lines are further formed separately. Image, and adjusting the display parameters of the adjacent reset images by using the adjustment command to change the display position of each reset image in the display module, so that adjacent auxiliary images move along the imaging position of the imaging module, and The edit position data is generated according to the preset position data and the display parameters, and the edit position data can also be saved to the memory unit.

According to the purpose of the present invention, a processing method for generating a plurality of different orientation images by a single image is further provided, the steps comprising: providing a display module to display a plurality of reset images, and using the imaging module to optically reflect each reset image A plurality of imaging images are formed, and at least one auxiliary line is respectively stacked on each of the reset images by using the control module, so that the same auxiliary line is displayed on each of the imaged images, and a plurality of auxiliary images are further formed. And adjusting the position of the adjacent auxiliary images on the imaging module until the adjacent auxiliary lines are aligned with each other.

The step of resetting the image generation further includes using the memory unit to store at least one original image data, and providing preset location data and editing location data corresponding to each reset image. The playing unit is connected to the memory unit, and the original image data is played in the background playing mode to generate a background playing image. The copy unit is connected to the playback unit, and the background playback image is copied to form a plurality of duplicate images. And copying the image unit and the display module by using the image placement unit, and flipping and configuring each of the duplicate images according to one of the preset position data and the edit position data to form each reset image in the display module.

The step of generating an image is further included by using a display module to display each reset image. The imaging module is composed of a plurality of imaging units, and each imaging unit corresponds to each display portion and forms an angle with each other. And using each imaging unit to form a plurality of imaging images by optical semi-reflection of each reset image.

The step of assisting the image generation further includes using the display module to display each reset image. Each of the reset images is optically semi-reflected to form each of the imaged images by each of the imaging units. And using the image adjusting unit to connect the memory unit and the image placing unit to receive at least one adjustment command, and respectively superimposing the auxiliary lines on the reset images, so that the same auxiliary lines are displayed on each of the imaged images, and further forming each Auxiliary image.

The step of adjusting adjacent auxiliary images and auxiliary lines further includes using a display module to display each reset image. Each of the reset images is optically semi-reflected to form a plurality of imaged images by using each of the imaging units. The adjustment command is used to superimpose the auxiliary lines on the reset images, so that the same auxiliary lines are displayed on the respective image images, and the auxiliary images are further formed. Adjusting adjacent reset images by using the adjustment command to change the display position of each reset image in the display module, so that adjacent auxiliary images are moved along the imaging position of the imaging module, and adjusted until adjacent auxiliary lines are mutually Align. And using the adjustment command to align the adjacent auxiliary lines with each other, according to at least one display parameter of each reset image in the display position of the display module, and generating the edit position data according to the preset position data and the display parameter, and editing the position data via The image adjustment unit is stored to the memory unit.

According to the present invention, there is provided a processing apparatus and method for generating a plurality of different orientation images in a single image, which may have one or more of the following advantages:

(1) A processing apparatus and method for generating a plurality of different azimuth images by a single image of the present invention, which is a technique for allowing a viewer to view an imaged image from various angles.

(2) A processing device and method for generating a plurality of different orientation images by a single image of the present invention, which provides an image that can adjust the position of each adjacent reset image displayed on the display module, so that the viewer can see each image from various angles. The image is in the same position for each of the displayed imaging units.

Embodiments of a processing apparatus and method for generating a plurality of different orientation images according to a single image of the present invention will be described below with reference to the related drawings. For ease of understanding, the same components in the following embodiments are denoted by the same reference numerals. .

Please refer to FIG. 1 and FIG. 2 , which are schematic diagrams showing the structure of a processing device for generating a plurality of different orientation images for a single image of the present invention. The device comprises a frame 1, a display module 2, an imaging module 3 and a control module 4. The frame 1 is composed of an upper top portion 11, a lower bottom portion 12 and a support body 13. One end of the support body 13 is coupled to the upper top surface 11, and the other end of the support body 13 is coupled to the lower bottom surface 12, and the upper top surface 11 is connected. Corresponding to the lower bottom surface 12. The display module 2 is disposed on one side of the frame 1 and displays a plurality of reset images 21. The imaging module 3 is composed of a plurality of imaging units 31. The adjacent sides of each imaging unit 31 are connected to each other, and an imaging space 33 is formed between the two sides of the frame 1. The two sides of the imaging unit 31 connected to the frame 1 are imaged. The space 33 has an angle θ, which is greater than 0° and less than 90°, and each of the reset images 21 is optically semi-reflected to form a plurality of imaged images 32. The control module 4 is disposed in the frame 1. The control module 4 respectively superimposes at least one auxiliary line on each of the reset images 21 (as shown in FIG. 2), so that the same auxiliary line is displayed on each of the imaged images 32. Further, a plurality of auxiliary images 23 are further formed, and display parameters of the adjacent reset images 21 are adjusted to change the display position of each reset image 21 in the display module 2, so that adjacent auxiliary images 23 are in the imaging mode. The imaging position of group 3 moves accordingly.

Please refer to FIG. 3, which is a block diagram of a processing device for generating a plurality of different orientation images for a single image of the present invention. The control module 4 further includes a memory unit 41, a playback unit 42, a copy image unit 43, an image placement unit 44, and an image adjustment unit 45. The memory unit 41 stores at least one original image data, and provides preset location data and edit position data corresponding to each reset image 21. The playing unit 42 is connected to the memory unit 41 and plays the original image data in a background playing manner to generate a background playing image. The copy image unit 43 is connected to the playback unit 42 and copies the background play image to form each copy image. The image placement unit 44 is connected to the copy image unit 43 and the display module 2, and flips and arranges each of the duplicate images according to one of the preset position data and the edit position data to form each reset image 21 in the display module. The image adjusting unit 45 is connected to the memory unit 41 and the image placing unit 44, and receives at least one adjustment command 451, and at least one auxiliary line is respectively stacked on each reset image, so that the same auxiliary line is displayed on each of the imaged images 32. Further, the auxiliary image 23 is further formed, and the display parameters of the adjacent reset images 21 are adjusted by the adjustment command 451 to change the display position of each reset image 21 in the display module 2, so that the adjacent auxiliary images 23 are The imaging position of the imaging module 3 is moved accordingly, and the editing position data is generated according to the preset position data and the display parameters, and the editing position data can also be stored to the memory unit 41.

Please refer to FIG. 4, which is a flow chart of a method for processing a plurality of different orientation images for a single image of the present invention. The steps are: S31: displaying a plurality of reset images by using the display module; S32: forming, by the imaging module, each of the reset images by optical semi-reflection to form a plurality of imaged images; S33: stacking at least one auxiliary line with the control module On each of the reset images, the same auxiliary line is displayed on each of the imaged images to form a plurality of auxiliary images; and S34: adjusting the position of the adjacent auxiliary images on the imaging module until the adjacent auxiliary lines are aligned with each other.

Please refer to FIG. 5, which is a flow chart of generating a reset image according to the present invention. The steps are as follows: S41: storing at least one original image data in the memory unit, and providing preset location data and editing location data corresponding to each reset image; S42: connecting the memory unit with the playing unit, and playing the original in the background playing mode. Image data to generate a background playing image; S43: connecting the playing unit with the copying image unit, and copying the background playing image to form a plurality of copied images; and S44: connecting the copying image unit and the display module by the image placing unit, according to the preset One of the location data and the edit location data, flipping and configuring each of the duplicate images to form each reset image in the display module.

Please refer to FIG. 6, which is a third flow chart for generating an image of the present invention. The steps are: S51: displaying a plurality of reset images by the display module; S52: dividing the imaging module into a plurality of imaging units, and each imaging unit corresponding to each display portion and forming an angle with each other; and S53: Each of the reset images is optically semi-reflected to form a plurality of imaged images by each imaging unit.

Please refer to FIG. 7 , which is a flow chart of generating an auxiliary image according to the present invention. The steps are: S61: displaying a plurality of reset images by using the display module; S62: forming a plurality of image images by optical semi-reflection with each imaging unit; and S63: connecting the memory unit and the image by the image adjusting unit The unit is arranged, and at least one adjustment command is received, and auxiliary lines are respectively superposed on each reset image, so that the same auxiliary lines are presented on each of the imaged images, thereby forming auxiliary images.

Please refer to FIG. 8 , which is a flow chart of adjusting auxiliary images and auxiliary lines according to the present invention. The step is: S71: displaying a plurality of reset images by using the display module; S72: forming, by each of the imaging units, each of the reset images by optical semi-reflection to form a plurality of imaged images; S73: receiving at least one adjustment command by the image adjusting unit Each auxiliary image is superimposed on each reset image so that the same auxiliary line is displayed on each of the imaged images to form each auxiliary image; S74: adjusting the display parameters of the adjacent reset images by using an adjustment command to change each reset image In the display position of the display module, the adjacent auxiliary images are moved along the imaging position of the imaging module, and adjusted until the adjacent auxiliary lines are aligned with each other; and S75: after the adjacent auxiliary lines are aligned with each other by the adjustment command, The editing position data is generated according to the display parameter of each reset image in the display position of the display module, and the edit position data is generated according to the preset position data and the display parameter, and the edit position data is stored to the memory unit via the image adjusting unit.

Referring to FIG. 9, a flow chart of a first embodiment of the present invention, wherein a plurality of circular auxiliary images are generated on a plurality of imaging units by using a circular original image file. The steps include: S81: providing a memory unit (such as a hard disk or a dynamic random access memory (DRAM)) with a memory device (such as a flash drive or an MP3) to store a circular original image file and providing a circular shape. The preset position data corresponding to the original image file; S82: connecting the memory unit by using the playing unit, and playing the circular original image data in the background playing mode to generate a circular background image; S83: connecting the playing unit by using the copy image unit, and Copying the circular background image to form a circular copy image; S84: using the image placement unit to connect the copy image unit and the display module (such as a projector, a liquid crystal display or a television), and according to the preset position data and the edit position data One of them, flipping and arranging the circular copy image to form a plurality of circular reset images in the display module respectively; S85: using each imaging unit (such as a semi-lens or reflective glass) to reset each circular reset image to an optical half Reflecting to form a plurality of circular imaging images; and S86: connecting the memory unit and the image placing unit with the image adjusting unit, and receiving the adjustment command, resetting the shadows in each circle Are provided stacked on the auxiliary line (such as: grid lines, arcs, or diagonal), that exhibit the same auxiliary line, thereby forming a secondary image on each of the respective circular image forming a circular image.

Please refer to FIG. 10 and FIG. 11 , which are schematic diagrams of two adjacent imaging units according to a first embodiment of the present invention, wherein adjacent first circular auxiliary images 23 and second circular auxiliary images 24 are The preset position data has an error, causing the positions of the first circular auxiliary image 23 and the second circular auxiliary image 24 and the auxiliary line 34 on the displayed imaging unit 31 from adjacent to the adjacent imaging units 31. When the position is viewed, the position of the second circular auxiliary image 24 is relatively upward. At this time, the adjustment command 451 (eg, G) is moved downward to adjust the display display parameter of the reset image 21 corresponding to the second circular auxiliary image 24, and the image adjustment unit 45 receives the adjustment command 451. The message of the adjustment command 451 is transmitted to the image placement unit 44, so that the reset image 21 corresponding to the second circular auxiliary image 24 is moved at the display position of the display module 2, so that the second circular auxiliary image is displayed. The imaging position of the imaging unit 31 is also moved and adjusted until the adjacent auxiliary lines 34 are aligned with each other. And according to the reset image 21 corresponding to the second circular auxiliary image 24, the display parameter at the display position of the display module 2 is according to the weight corresponding to the first circular auxiliary image 23 and the second circular auxiliary image 24. The preset position data and the display parameter of the image 21 are generated, and the edit position data of the reset image 21 corresponding to the first circular auxiliary image 23 and the second circular auxiliary image 24 is generated, and the generated edit position data is used by the image adjustment unit. 45 is stored to the memory unit 41.

Referring to FIG. 9, a flow chart of a second embodiment of the present invention, wherein a plurality of circular auxiliary images are generated on a plurality of imaging units by using a circular original image file. The steps include: S81: providing a memory unit to store a circular original image file by using a memory device, and providing a preset position data corresponding to a circular original image file; S82: connecting the memory unit by using a playing unit, and playing in a background manner Playing a circular original image data to generate a circular background image; S83: connecting the playback unit by using the copy image unit, and copying the circular background image to form a circular copy image; S84: using the image placement unit to connect the copy image unit and display The module, and according to one of the preset position data and the edit position data, flipping and arranging the circular copy image to form a plurality of circular reset images in the display module respectively; S85: using each imaging unit to round each circle The image is formed by optical semi-reflection to form a plurality of circular imaging images; and S86: connecting the memory unit and the image placing unit with the image adjusting unit, and receiving the adjustment command, respectively stacking at least one auxiliary on each circular reset image The lines are such that the same auxiliary line is presented on each circular image, thereby forming each circular auxiliary image.

12 and FIG. 13 are schematic views of two adjacent imaging units according to a second embodiment of the present invention, wherein adjacent first circular auxiliary images 23 and second circular auxiliary images 24 are The preset position data has an error, causing the positions of the first circular auxiliary image 23 and the second circular auxiliary image 24 and the auxiliary line 34 on the displayed imaging unit 31 from adjacent to the adjacent imaging units 31. When viewed in position, the position of the first circular auxiliary image 23 is relatively right. At this time, the adjustment command 451 (eg, F) is moved to the left to adjust the display parameter of the reset image 21 corresponding to the first circular auxiliary image 23, and when the image adjustment unit 45 receives the adjustment command 451, The message of the adjustment command 451 is transmitted to the image placement unit 44, so that the reset image 21 corresponding to the first circular auxiliary image 23 is moved at the display position of the display module 2, so that the first circular auxiliary image 23 is The imaging position of the imaging unit 31 is also moved and adjusted until the adjacent auxiliary lines 34 are aligned with each other. And according to the reset image 21 corresponding to the first circular auxiliary image 23, the display parameter at the display position of the display module 2 is according to the weight corresponding to the first circular auxiliary image 23 and the second circular auxiliary image 24. The preset position data and the display parameter of the image 21 are generated, and the edit position data of the reset image 21 corresponding to the first circular auxiliary image 23 and the second circular auxiliary image 24 is generated, and the generated edit position data is used by the image adjustment unit. 45 is stored to the memory unit 41.

Please refer to FIG. 10, FIG. 11, FIG. 12 and FIG. 13 for a schematic view of two adjacent imaging units according to the first embodiment and the second embodiment of the present invention. In the figure, the function of the adjustment command 451 includes zooming in and out (for example, < and >) of each reset image 21 displayed by the display module 2, and repeatedly playing the reset image 21 (eg, O), pause or again. The reset image 21 (eg, Space) is played, and the reset image 21 is reconfigured at the display position of the display module 2 (eg, U), and the reset image 21 can be displayed on the display position of the display module 2, Movement in the left and right directions (eg, ↑, ↓, ←, and →), saves the edit position data of the reset image 21 (eg, Alt), and leaves the adjustment command (eg, F4).

Moreover, the single image of the present invention generates a plurality of different orientation image processing methods, wherein the playback unit 42 plays the original image data in a background playback manner to generate a background playback image; the duplicate image unit 43 copies the background playback image to form a plurality of images. Copying the image; the image placing unit 44 flips and configures each of the copied images to form each of the reset images 21 in each of the display portions according to the preset position data and the edit position data; and the function of the adjustment command 451 . The above-mentioned actions can be completed and adjusted by using Flash, but are not limited thereto, and can also be achieved by other programming languages or software.

According to the above description, the processing device and method for generating a plurality of different orientation images by using the single image of the present invention solves the problem that the conventional image output device or the magic theater can output images only on the same plane or planes with different depths. The problem is that the viewer can see the imaged image 32 from a variety of angles.

The above is intended to be illustrative only and not limiting. Any equivalent modifications or alterations to the spirit and scope of this creation shall be included in the scope of the appended patent application.

1‧‧‧Frame

11‧‧‧ top surface

12‧‧‧ underside

13‧‧‧Support

2‧‧‧Display module

21‧‧‧Reset image

22‧‧‧Auxiliary imagery

23‧‧‧First circular auxiliary image

24‧‧‧Second circular auxiliary image

3‧‧‧ imaging module

31‧‧‧ imaging unit

32‧‧‧ imaging images

33‧‧‧ imaging space

34‧‧‧Auxiliary line

4‧‧‧Control Module

41‧‧‧ memory unit

42‧‧‧Play unit

43‧‧‧Copy image unit

44‧‧‧Image placement unit

45‧‧‧Image Adjustment Unit

451‧‧‧Adjustment order

Θ‧‧‧ angle

as well as

S31~S34, S41~S44, S51~S53, S61~S63, S71~S75, S81~S86‧‧

1 is a schematic structural diagram of a processing device for generating a plurality of different orientation images for a single image of the present invention;
2 is a schematic structural diagram of a processing device for generating a plurality of different orientation images for a single image of the present invention;
Figure 3 is a block diagram of a processing device for generating a plurality of different orientation images for a single image of the present invention;
Figure 4 is a flow chart of a method for processing a plurality of images of different orientations for a single image of the present invention;
Figure 5 is a flow chart of generating a reset image of the present invention;
Figure 6 is a flow chart of generating an image of the invention;
Figure 7 is a flow chart of generating an auxiliary image of the present invention;
Figure 8 is a flow chart of adjusting the adjacent auxiliary lines to each other according to the present invention;
Figure 9 is a flow chart of the first embodiment and the second embodiment of the present invention;
Figure 10 is a schematic view of two adjacent imaging units of the first embodiment of the present invention;
Figure 11 is a schematic view of two adjacent imaging units of the first embodiment of the present invention;
Figure 12 is a schematic view of two adjacent imaging units according to a second embodiment of the present invention; and Figure 13 is a schematic view of two adjacent imaging units of the second embodiment of the present invention.

1‧‧‧Frame

2‧‧‧Display module

21‧‧‧Reset image

22‧‧‧ Display section

3‧‧‧ imaging module

31‧‧‧ imaging unit

32‧‧‧ imaging images

33‧‧‧ imaging space

4‧‧‧Control Module

Claims (9)

A processing device for generating a plurality of images of different orientations in a single image, comprising:
ㄧ framework;
a display module is disposed on one side of the frame and displays a plurality of reset images;
An imaging module is disposed at a position of the frame facing the display module, and optically semi-reflecting each of the reset images to form a plurality of imaged images; and a control module disposed in the frame, the The control module respectively superimposes at least the auxiliary line on each of the reset images, so that the same auxiliary line is formed on each of the imaged images, and further forms a plurality of auxiliary images, and adjusts the adjacent ones of the reset images. The display parameter is used to change the display position of each of the reset images in the display module, so that adjacent auxiliary images are moved along the imaging position of the imaging module. A processing device for generating a plurality of images of different orientations according to the single image of claim 1 wherein the frame is composed of an upper top surface, a lower bottom surface and a support body, and one end of the support body and the top surface The surface is joined, and the other end of the support is coupled to the lower bottom surface, and the upper top surface corresponds to the lower bottom surface. The processing device for generating a plurality of different orientation images according to the single image described in claim 1 wherein the imaging module is composed of a plurality of imaging units, and adjacent sides of the imaging unit are connected to each other and to the frame An imaging space is formed between the two sides, and the two sides of the imaging unit connected to the frame have an angle in the imaging space. A processing device for generating a plurality of different orientation images according to the single image described in claim 1 wherein the control module comprises:
a memory unit storing at least one original image data and providing a preset location data and an edit location data corresponding to each of the reset images;
a playback unit is connected to the memory unit and plays the original image data in a background playing manner to generate a background playing image;
Copying the image unit, connecting the playing unit, and copying the background playing image to form a plurality of copied images;
An image placement unit is configured to connect the copy image unit and the display module, and flip and configure each of the duplicate images in the display module according to the preset position data and the edit position data. And resetting the image; and an image adjusting unit connecting the memory unit and the image placing unit to receive at least one adjustment command, and respectively stacking the auxiliary lines on each of the reset images, so that each of the image images is The auxiliary auxiliary line is further formed, and the auxiliary image is further formed separately, and the display parameter of the adjacent reset image is adjusted by using the adjustment command to change the display position of each of the reset images in the display module. The auxiliary image is moved along the imaging position of each imaging unit, and the edit position data is generated according to the preset position data and the display parameter, and the edit position data may be stored in the memory unit. A method for processing a plurality of images of different orientations by a single image, comprising:
Providing a display module to display a plurality of reset images;
Forming, by an imaging module, each of the reset images by optical semi-reflection to form a plurality of imaged images;
A control module is used to superimpose at least the auxiliary auxiliary lines on each of the reset images, so that the auxiliary image lines are displayed on each of the imaged images to further form a plurality of auxiliary images; and the adjacent reset images are adjusted. In the display position of the display module, the adjacent auxiliary images are moved along the position displayed by the imaging module until the adjacent auxiliary lines are aligned with each other. The processing method for generating a plurality of different orientation images according to the single image described in claim 5, wherein the reset image generation step:
Using a memory unit to store at least one original image data, and providing a preset location data and an edit location data corresponding to each of the reset images;
The memory unit is connected by a playing unit, and the original image data is played in a background playing manner to generate a background playing image;
Connecting the playback unit with a copy image unit, and copying the background playback image to form a plurality of duplicate images; and connecting the duplicate image unit and the display module by using an image placement unit, and Editing one of the location data, flipping and configuring each of the duplicate images to form each of the reset images in the display module. The processing method for generating a plurality of different orientation images according to the single image described in claim 5, wherein the imaging image generation step:
Using the display module to display each of the reset images;
The imaging module is composed of a plurality of imaging units, and each of the imaging units has an angle corresponding to each of the display portions and forms an angle with each other; and each of the reset images is represented by each of the imaging units Optical semi-reflection forms each of the imaged images. The processing method for generating a plurality of different orientation images according to the single image described in claim 5, wherein the auxiliary image generation step:
Using the display module to display each of the reset images;
Each of the reset images is optically semi-reflected to form each of the imaged images by using each of the image forming units; and an image adjusting unit is coupled to the memory unit and the image placing unit to receive at least one adjustment command. The auxiliary lines are respectively superimposed on the reset image, so that the auxiliary lines are also present on each of the imaged images, and each of the auxiliary images is further formed. The processing method for generating a plurality of different orientation images according to the single image described in claim 5, wherein the steps of aligning the adjacent auxiliary lines with each other are adjusted:
Using the display module to display each of the reset images;
Using the imaging unit, each of the reset images is optically semi-reflective to form each of the imaged images;
Using the adjustment command, the auxiliary lines are respectively stacked on each of the reset images, so that the auxiliary lines are also displayed on each of the imaged images, and each of the auxiliary images is further formed;
Adjusting the display parameters of the adjacent reset images by using the adjustment command to change the display position of each of the reset images in the display module, so that the adjacent auxiliary images are displayed at the position displayed by the imaging module. Moving until the adjacent auxiliary lines are aligned with each other; and using the adjustment command to display the display parameters of the reset image at the display position of the display module according to the adjacent adjacent auxiliary lines, and according to the preset position data And the display parameter generates the edit position data, and the edit position data is stored in the memory unit.