JP4415450B2 - Stereo image data generation apparatus and stereo image data generation method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
In the present invention, image data for displaying a right-eye image and a left-eye image with parallax is recorded on the display means. Stereo image data generation apparatus and stereo image data generation method About.
[0002]
[Prior art]
Conventionally, a stereoscopic image display system that displays a two-dimensional image stereoscopically has two cameras for the right eye and the left eye that are fixed to a tripod or the like, separated by a human eye width (about 65 mm). Image data captured by each of the two cameras, an image display device that alternately displays images of these image data so as to have parallax, and an image displayed on the image display device In addition, it is composed of shutter glasses that make one eye invisible.
[0003]
In such a stereoscopic image display system, the two cameras constituting the imaging device are driven in synchronization. The image display device alternately displays the two image data captured by the two cameras. At this time, the image data for the right eye and the image data for the left eye are alternately displayed on the image display device so as to have parallax. In addition, shutter glasses are connected to the image display device. When the right eye image is displayed on the image display device, the shutter glasses put the right eye lens in a see-through state and the left eye lens in a light shielding state. In addition, when the left eye image is displayed on the image display device, the shutter glasses put the left eye lens in a see-through state and the right eye lens in a light shielding state. As described above, in the image display system, the user can view stereoscopically by synchronizing the image displayed on the image display device and the on / off of the pair of left and right lenses of the shutter glasses.
[0004]
[Problems to be solved by the invention]
By the way, in this stereoscopic image display system, as a method for storing the image data for the right eye and the image data for the left eye photographed by two cameras, the horizontal scanning line data of the image data for the right eye and the image for the left eye are used. There is a method of storing the data so that the data of the horizontal scanning lines alternate.
[0005]
However, in such a method, since the image data for the right eye and the image data for the left eye have already been synthesized, editing such as enlarging or reducing the image cannot be performed.
[0006]
Therefore, the present invention records data so that an image for stereoscopic display can be re-edited. Stereo image data generation apparatus and stereo image data generation method The purpose is to provide.
[0007]
[Means for Solving the Problems]
In order to solve the above-described problem, the stereoscopic image data generation device according to the present invention generates a right-eye image captured in substantially the right half of one image sensor and a left-eye image captured in approximately the left half. In addition, an input unit for inputting one image data file in which the right-eye image and the left-eye image are arranged across the boundary, and the right-eye for the boundary input from the input unit A display unit that displays a single image data file in which an image and a left-eye image are arranged, and a single image in which a right-eye image and a left-eye image are arranged across a boundary input from the input unit Split lines at the boundary of the data file Instructions In addition, a predetermined region of one of the right-eye image and the left-eye image displayed on the display unit is formed by one cut line that forms a substantially rectangular shape. Instruction means for instructing, position input means for operating the indicated position of the instruction means, and instruction by the instruction means The other image area of the right-eye image or the left-eye image corresponding to the region that has been made is another cut line that forms a substantially rectangular shape. Control to display, Above right eye image above With tear line The right-eye image data file formed by cutting and the left-eye image With tear line Cross-point coordinate information for displaying the left-eye image data file formed by cutting, the right-eye image data, and the left-eye image data with parallax on the display unit. Record Saved information files in a folder on the recording medium Control device to control With. the above Control device Is The instruction means A predetermined area of one of the right-eye image and the left-eye image displayed on the display unit is defined by the one cut line. Instructions The distance between the dividing line and the line on the dividing line side of one cut line of the one image is such that the side edge on the side opposite to the dividing line of the other image and the line on the side edge side of the other cutting line The other cut line so that it is equal to the distance between display Do To control .
[0008]
Further, in the stereoscopic image data generation method according to the present invention, in order to solve the above-described problem, a right-eye image is captured in a substantially right half of a single image sensor, and a left-eye image is captured in a substantially left half. A step of inputting the generated image data file in which the right-eye image and the left-eye image are arranged across the boundary portion to the input portion; and the boundary portion input from the input portion The step of displaying one image data file in which the image for the right eye and the image for the left eye are arranged on the display unit, and the image for the right eye and the image for the left eye across the boundary input from the input unit Divide lines at the boundary of one image data file Instruction means indicate And steps to The instruction means A predetermined region of one of the right-eye image and the left-eye image displayed on the display unit is formed by one cut line that forms a substantially rectangular shape. Instructing step and the above instruction means The other image area of the right-eye image or the left-eye image corresponding to the region that has been made is another cut line that forms a substantially rectangular shape. Control to display Step and above of the image for the right eye With tear line The right-eye image data file formed by cutting and the left-eye image With tear line Cross-point coordinate information for displaying the left-eye image data file formed by cutting, the right-eye image data, and the left-eye image data with parallax on the display unit. Record Saved information files in a folder on the recording medium To control Steps. The instruction means A predetermined area of one of the right-eye image and the left-eye image displayed on the display unit is defined by the one cut line. Instructions The distance between the dividing line and the line on the dividing line side of one cut line of the one image is such that the side edge on the side opposite to the dividing line of the other image and the line on the side edge side of the other cutting line The other cut line so that it is equal to the distance between display Do To control .
[0009]
Furthermore, in order to solve the above-described problem, the stereoscopic image data generation device according to the present invention captures a right-eye image in approximately the right half of one image sensor, and captures a left-eye image in approximately the left half. An input unit to which one image data file in which the image for the right eye and the image for the left eye are arranged with the boundary portion interposed therebetween is input, and the boundary portion input from the input portion A display unit that displays one image data file in which an image for the right eye and an image for the left eye are arranged, and an image for the right eye and an image for the left eye are arranged across the boundary input from the input unit. Dividing lines at the boundary of one image data file Instructions In addition, a predetermined region of one of the right-eye image and the left-eye image displayed on the display unit is formed by one cut line that forms a substantially rectangular shape. Instruction means for instructing, position input means for operating the indicated position of the instruction means, and instruction by the instruction means The other image area of the right-eye image or the left-eye image corresponding to the region that has been made is another cut line that forms a substantially rectangular shape. Control to display, One image data file in which a right-eye image and a left-eye image are arranged across the boundary input from the input unit, and the one image data file Instruction means In Instructions For displaying the cut-out information indicating the positions of the one cut-out line and the other cut-out line, and the right-eye image and the left-eye image cut according to the cut-out information so as to have parallax on the display unit. Cross point coordinate information Record Saved information files in a folder on the recording medium Control device to control With. the above Control device Is The instruction means A predetermined area of one of the right-eye image and the left-eye image displayed on the display unit is defined by the one cut line. Instructions The distance between the dividing line and the line on the dividing line side of one cut line of the one image is such that the side edge on the side opposite to the dividing line of the other image and the line on the side edge side of the other cutting line. The other cut line so that it is equal to the distance between display Do To control .
[0010]
Furthermore, in order to solve the above-described problem, the stereoscopic image data generation method according to the present invention captures a right-eye image in approximately the right half of one image sensor and captures a left-eye image in approximately the left half. A step of inputting, to the input unit, one image data file in which the right-eye image and the left-eye image are arranged across the boundary, and the boundary input from the input unit And displaying one image data file in which the right-eye image and the left-eye image are arranged on the display unit, and the right-eye image and the left-eye image across the boundary input from the input unit. Divide lines at the boundary of one image data file Instruction means indicate And steps to The instruction means A predetermined region of one of the right-eye image and the left-eye image displayed on the display unit is formed by one cut line that forms a substantially rectangular shape. Instructing step and the above instruction means The other image area of the right-eye image or the left-eye image corresponding to the region that has been formed is another cut line that forms a substantially rectangular shape. Control to display A step, a single image data file in which a right eye image and a left eye image are arranged across the boundary input from the input unit, and the single image data file Instruction means In Instructions For displaying the cut-out information indicating the positions of the one cut-out line and the other cut-out line, and the right-eye image and the left-eye image cut according to the cut-out information so as to have parallax on the display unit. Cross point coordinate information Record Saved information files in a folder on the recording medium To control Steps. The instruction means A predetermined area of one of the right-eye image and the left-eye image displayed on the display unit is defined by the one cut line. Instructions The distance between the dividing line and the line on the dividing line side of one cut line of the one image is such that the side edge on the side opposite to the dividing line of the other image and the line on the side edge side of the other cutting line The other cut line so that it is equal to the distance between display Do To control .
[0011]
Furthermore, in order to solve the above-described problem, the stereoscopic image data generation device according to the present invention captures a right-eye image in approximately the right half of one imaging device and captures a left-eye image in approximately the left half. An input unit to which one image data file in which the image for the right eye and the image for the left eye are arranged is input with the boundary part interposed therebetween, and the boundary part input from the input part A display unit for displaying one image data file in which a right-eye image and a left-eye image are arranged, and a right-eye image and a left-eye image are arranged with a boundary input from the input unit interposed therebetween. Dividing lines at the boundary of one image data file Instructions In addition, a predetermined region of one of the right-eye image and the left-eye image displayed on the display unit is formed by a single cut line that forms a substantially rectangular shape. Instruction means for instructing, position input means for operating the indicated position of the instruction means, and instruction by the instruction means The other image area of the right-eye image or the left-eye image corresponding to the region that has been formed is another cut line that forms a substantially rectangular shape. Control to display, Above right eye image above With tear line The right-eye image data file formed by cutting and the left-eye image With tear line Cross-point coordinate information for displaying the left-eye image data file formed by cutting, the right-eye image data, and the left-eye image data with parallax on the display unit. Record And a composite image data file in which the horizontal scanning line data of the right-eye image data and the horizontal scanning line data of the left-eye image data are alternately stored in a folder of the recording medium. save Control device to control With. the above Control device Is The instruction means A predetermined area of one of the right-eye image and the left-eye image displayed on the display unit is defined by the one cut line. Instructions The distance between the dividing line and the line on the dividing line side of one cut line of the one image is such that the side edge on the side opposite to the dividing line of the other image and the line on the side edge side of the other cutting line The other cut line so that it is equal to the distance between display Do To control .
[0012]
Furthermore, in order to solve the above-described problem, the stereoscopic image data generation method according to the present invention captures a right-eye image in approximately the right half of one image sensor and captures a left-eye image in approximately the left half. A step of inputting, to the input unit, one image data file in which the right-eye image and the left-eye image are arranged across the boundary, and the boundary input from the input unit And displaying one image data file in which the right-eye image and the left-eye image are arranged on the display unit, and the right-eye image and the left-eye image across the boundary input from the input unit. Divide lines at the boundary of one image data file Instruction means indicate And steps to The instruction means A predetermined region of one of the right-eye image and the left-eye image displayed on the display unit is formed by one cut line that forms a substantially rectangular shape. Instructing step and the above instruction means The other image area of the right-eye image or the left-eye image corresponding to the region that has been formed is another cut line that forms a substantially rectangular shape. Control to display Step and above of the image for the right eye With tear line The right-eye image data file formed by cutting and the left-eye image With tear line Cross-point coordinate information for displaying the left-eye image data file formed by cutting, the right-eye image data, and the left-eye image data with parallax on the display unit. Record And a composite image data file in which the horizontal scanning line data of the right-eye image data and the horizontal scanning line data of the left-eye image data are alternately stored in a folder of the recording medium. save To control Steps. The instruction means A predetermined area of one of the right-eye image and the left-eye image displayed on the display unit is defined by the one cut line. Instructions The distance between the dividing line and the line on the dividing line side of one cut line of the one image is such that the side edge on the side opposite to the dividing line of the other image and the line on the side edge side of the other cutting line The other cut line so that it is equal to the distance between display Do To control .
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a stereoscopic image display system to which the present invention is applied will be described with reference to the drawings.
[0014]
As shown in FIG. 1, a stereoscopic image display system 1 to which the present invention is applied takes a digital camera 2 for capturing a video and image data generated by the digital camera 2 and performs data processing of the image data. And the control device 3 that displays an image with parallax on the display 55 and the shutter glasses 4 that make each eye invisible according to the image displayed on the display 55. In addition, the digital camera 2 is provided with an adapter 5 for capturing a right-eye image and a left-eye image in a lens barrel having a built-in lens such as an imaging lens and a focus lens. As a result, the right eye image and the left eye image are captured in one CCD element used in the digital camera 2. The control device 3 is supplied with image data including a right-eye image and a left-eye image generated by the digital camera 2. The control device 3 is, for example, for the right eye based on an input signal from the input device 7 including a keyboard 7a as a character input unit, a mouse 7b as a position input unit for operating an indication position of an instruction unit such as a pointer. Cut out the image and the image for the left eye. The control device 3 alternately displays the cut-out image for the right eye and the cut-out image for the left eye on the display 55 such as a CRT (Cathode-Ray Tube) or a liquid crystal display panel. Further, between the control device 3 and the display 55, a glasses control device 6 that controls on / off of the shutter glasses 4 is provided. The shutter glasses 4 include a right-eye lens unit 4a and a left-eye lens unit 4a, and the right-eye lens unit 4a and the left-eye lens unit 4b are configured by a liquid crystal shutter. Such shutter glasses 4 are connected to the glasses control device 6. The shutter glasses 4 open and close the liquid crystal shutters constituting the lens units 4 a and 4 b in synchronization with the right-eye images and the left-eye images displayed alternately on the display 55 under the control of the glasses control device 6. Thereby, the user opens and closes the lens portions 4a and 4b of the shutter glasses 4 according to the cut-out images for the right eye and the cut-out images for the left eye that are alternately displayed on the display 55, so that the display is displayed on the display 55. Images can be viewed stereoscopically.
[0015]
Hereinafter, the digital camera 2, the control device 3, the adapter 5, and the eyeglass control device 6 constituting the stereoscopic image display system 1 as described above will be described with reference to the drawings.
[0016]
The digital camera 2 has a configuration similar to that of a normal digital camera. As shown in FIG. 2, a CCD (Charge Coupled Device) that photoelectrically converts light incident from the imaging lens 11 and generates an imaging signal. An element 12, a CDS / AGC (Correlated Double Sampling / Automatic Gain Control) 13 that removes noise of the imaging signal from the CCD element 12, and an A / D converter 14 that converts the imaging signal from the CDS / AGC 13 into a digital signal And a signal processing unit 15 that performs signal processing corresponding to color coding.
[0017]
The CCD element 12 serving as an image sensor is a two-dimensional color image sensor provided with millions of pixels, and a color coding filter for imaging light of primary colors (R, G, B) or complementary colors (Ye, Cy, Mg). Are converted into color-coded imaging signals and output to the CDS / AGC 13.
[0018]
The CDS / AGC 13 performs correlated double sample hold of the image pickup signal supplied from the CCD element 12, removes reset noise and controls gain, and outputs the result to the A / D converter 14.
[0019]
The A / D converter 14 converts the imaging signal from the CDS / AGC 13 into digital image data. Then, the A / D converter 14 outputs the digitally converted image data to the signal processing unit 15.
[0020]
The signal processing unit 15 performs a decoding process corresponding to the color coding by the color coding filter of the CCD element 12 on the image data from the A / D converter 14, and generates luminance information, color difference information, and the like from the image data.
[0021]
As shown in FIG. 2, the digital camera 2 includes a compression unit 16 that compresses the image data processed by the signal processing unit 15, a memory 17 that stores the image data compressed by the compression unit 16, and A USB (Universal Sirial Bus) interface 18 for transmitting the image data compressed by the compression unit 16 to the control device 3 and an IC card for transmitting the image data to the IC card 8 using a flash memory or the like as a storage medium. Interface 19 and a control unit 20 for controlling the whole.
[0022]
The compression unit 16 compresses the image data signal-processed by the signal processing unit 15 in, for example, JPEG (Joint Photographic Experts Group) format. The compression unit 16 outputs the image data compressed in the JPEG format to the memory 17, and the memory 17 stores the image data compressed in the JPEG format.
[0023]
Further, the USB interface 18 transfers image data compressed in, for example, the JPEG format stored in the memory 17 to the control device 3. The IC card interface 19 transfers image data compressed in, for example, the JPEG format stored in the memory 17 to the card-type IC card 8 serving as an external storage device, to the control device 3.
[0024]
The control unit 20 controls the entire digital camera 2. Specifically, the control unit 20 controls driving of a focus lens, a zoom lens, and the like based on an operation signal from an operation unit (not shown). In addition, the control unit 20 stores the image data compressed in the JPEG format in the memory 17. Further, the control unit 20 directly transfers the compressed image data to the control device 3 via the USB interface 18 without storing the compressed image data in the memory 17, and also the IC card 8 via the IC card interface 19. Remember me.
[0025]
When an image is photographed by the digital camera 2 as described above and this data is recorded in the memory 17, the digital camera 2 photoelectrically converts the light incident from the imaging lens 11 by the CCD element 12, and generates an imaging signal. Is digitally converted by the A / D converter 14 via the CDS / AGC 13 to generate image data, the signal processing unit 15 performs signal processing, the compression unit 16 compresses the image data to the JPEG format, and the memory 17 compresses the image data. Stored image data is stored. In addition, when the JPEG format image data stored in the memory 17 is recorded on the IC card 8, the control unit 20 is connected to the digital camera 2 via the IC card interface 19 in accordance with an operation signal from the operation unit. When recording on the mounted IC card 8 and transferring image data to the control device 3 by USB, the control unit 20 responds to an operation signal from the operation unit via the USB interface 18. Forward to.
[0026]
Incidentally, as shown in FIG. 1, an adapter 5 for capturing an image for the right eye and an image for the left eye is attached to the lens barrel 2 a of the digital camera 2. This adapter 5 is for taking in an image for the right eye and an image for the left eye at the approximate center of one CCD element 12 used in the digital camera 2. As shown in FIGS. 3 and 4, the adapter 5 is provided with first flat mirrors 33 a and 33 b on the inner surfaces of the left and right inclined walls 32 a and 32 b which are the side walls of the outer casing 31. A substantially triangular partition wall 34 is provided in the approximate center of the outer casing 31. One side surface 34 c of the partition wall 34 faces the front surface of the outer casing 31, and forms a right-eye opening 35 a and a left-eye opening 35 b for capturing external light with the outer casing 31. The two side surfaces 34a and 34b adjacent to the one side surface 34c are provided so as to be substantially parallel to the inclined walls 32a and 32b of the outer casing 31, and the two side surfaces 34a and 34b include a first flat plate. Second flat mirrors 36a and 36b are provided so as to substantially face the mirrors 33a and 33b. Further, the back wall 37 of the outer casing 31 has an opening for taking outside light reflected by the first flat mirrors 33 a and 33 b and the second flat mirrors 36 a and 36 b into the lens barrel 2 a of the digital camera 2. A portion 38 is formed.
[0027]
The adapter 5 configured as described above is attached to the distal end side of the lens barrel 2 a so that the opening 38 faces the imaging lens 11 of the digital camera 2. The external light R captured from the right-eye opening 35a and the external light L captured from the left-eye opening 35b are reflected by the first flat mirrors 33a and 33b, and then the second flat mirrors 36a and 36b. And is taken into the CCD element 12 of the digital camera 2 through the imaging lens 11 facing the opening 38. Here, as shown in FIG. 4, the CCD element 12 captures an image having an angle of view of 2θ, where θ is the angle of view at the points 39a and 39b, as shown in FIG. Further, since the distance D between the points 39a and 39b determines the parallax, the distance D is set to 65 mm to 70 mm in accordance with the human eye width. The interval D may be adjusted according to individual differences. Therefore, the CCD element 12 captures the right-eye image and the left-eye image separated from each other in the left-right direction.
[0028]
Here, FIG. 5 is an image captured by the CCD element 12 when the adapter 5 is attached to the digital camera 2. This image 41 is a picture of a woman with a flowerpot placed in front and a background as a mountain. Is. As shown in FIG. 5, the image 41 is provided with a right-eye image 41 a in a substantially right half and a left-eye image 41 b in a substantially left half with a boundary portion 42 as a boundary. Comparing the right-eye image 41a and the left-eye image 41b, for example, the flower 43a and the mountain 44a for the right-eye image 41a are shifted slightly to the left in the figure from the flower 43b and the mountain 44b for the left-eye image 41b. . Thus, the right-eye image 41a and the left-eye image 41b are shifted by the amount of left and right parallax, that is, the interval D. Note that the boundary portion 42 is actually formed as a blurred white line.
[0029]
Therefore, when shooting is performed with the adapter 5 attached to the digital camera 2, the image 41 composed of the right-eye image 41 a and the left-eye image 41 b is taken into one CCD element 12, and this is regarded as one unit. The processed image data is stored in the memory 17 or the IC card 8 and transferred to the control device 3 via the USB interface 18. By using such an adapter 5, in the digital camera 2, the stereoscopic image 41 can be configured by one file, and management can be facilitated. Further, unlike the case where two conventional cameras are used, it is not necessary to provide a timing generator or the like for synchronizing each camera, and the configuration can be simplified. Furthermore, in the digital camera 2 to which the adapter 5 is attached, the left and right images can be simultaneously photographed without using two cameras even when still images are continuously photographed to make a moving image. Furthermore, in the digital camera 2 to which the adapter 5 is attached, it is not necessary to match the optical axes of the two camera lenses, so that a zoom function using a zoom lens can be used.
[0030]
Next, regarding the control device 3 that edits and displays the image data generated by the digital camera 2 to which the adapter 5 as described above is attached, that is, the image 41 composed of the right-eye image 41a and the left-eye image 41b, This will be described with reference to FIG.
[0031]
The control device 3 has substantially the same configuration as that of a normal personal computer. The image data of the image 41 described above, an application program for editing the image data, an application program for displaying the image three-dimensionally, and the like. , A hard disk (hereinafter also referred to as HDD) 51, a random access memory (hereinafter also referred to as RAM) 52 for temporarily reading an application program or the like recorded in the HDD 51, and the above-mentioned. USB interface 53 for data transmission with digital camera 2, IC card interface 54 for reading data recorded on IC card 8, display 55 for displaying images, and image data for display 55 To display An input device 57 including a video random access memory (hereinafter also referred to as VRAM) 56, a keyboard 57a and a mouse 57b for inputting a command for executing an application program, and a JPEG format A compression / decompression unit 58 that decompresses data and compresses the data into a JPEG format, and a microprocessor (Micro Processor Unit, hereinafter also referred to as MPU) 58 that serves as a control unit for controlling the whole are provided.
[0032]
The HDD 51 is edited by an operating system (Operating Systen, hereinafter also referred to as OS), an editing program for editing the image 41 composed of the right-eye image 41a and the left-eye image 41b, and the editing program. A browser for viewing an image, image data including a right-eye image 41a and a left-eye image 41b, and the like are recorded.
[0033]
The RAM 52 reads application programs to be executed and image data to be processed from the HDD 51 or the like. For example, image data composed of a right-eye image 41 a and a left-eye image read from the HDD 51 is a right-eye image and a left-eye image to be displayed on the display 55 from a single image data in the RAM 52. A cutting process is performed to cut out.
[0034]
When the USB interface 53 is connected to the USB interface 18 of the digital camera 2 by USB, the USB interface 53 receives image data compressed by the digital camera 2 by the JPEG method. The image data received by the USB interface 53 is stored in the HDD 51 by the MPU 59.
[0035]
The IC card interface 54 reads out image data of an image photographed by, for example, the digital camera 2 stored in the IC card 8 when the IC card 8 is attached to a drive of the IC card 8 provided in the apparatus main body. The image data read by the USB interface 53 is stored in the HDD 51 by the MPU 59.
[0036]
The display 55 is composed of a CRT or a liquid crystal display panel, and before editing processing, an image 41 in which a right-eye image 41a and a left-eye image 41b as shown in FIG. 5 are arranged in the horizontal direction is displayed. indicate. Further, the right-eye cut image data and the left-eye cut image data that have undergone the cut-out processing of the right-eye image 41a and the left-eye image 41b are alternately displayed so as to have parallax. The display 55 may be a progressive method or an interlace method.
[0037]
The VRAM 56 for displaying an image on the display 55 includes memory units 56a and 56b having a capacity necessary for storing cut image data for one frame. For example, the memory unit 56a stores the right-eye cut image data for one frame, and the memory 56b stores the left-eye cut image data for one frame. Then, the VRAM 56 alternately outputs the cut-out image data for the right eye stored in the memory unit 56a and the cut-out image data for the left eye stored in the memory unit 56b to the display 55.
[0038]
The compression / decompression unit 58 decompresses the compressed image data, for example, when reading the image data compressed in the JPEG format recorded on the IC card 8 into the RAM 52. Further, when storing the edited image data, the compression / decompression unit 58 compresses the image data in the RAM 56 into the JPEG format and stores it in the HDD 51 or the IC card 8.
[0039]
The MPU 59 controls the entire apparatus. For example, the MPU 59 stores the image data read by the USB interface 53 or the IC card interface 54 in the HDD 51. Further, the MPU 59 is processed by the editing program for editing the image 41 composed of the right-eye image 41a and the left-eye image 41b from the HDD 51, the browser for viewing the image edited by this editing program, and these programs. The image data to be read is read into the RAM 52. Then, the MPU 59 performs a cutting process for cutting out the right eye image and the left eye image to be displayed on the display 55 from the read single image data, and the right eye cut image data processed by the RAM 52 is stored in the VRAM 56. Are output to the memory unit 56a, and the cut-out image data for the left eye are output to the memory unit 56b.
[0040]
The control device 3 as described above operates as follows when displaying the image data including the cut-out image for the right eye and the cut-out image for the left eye on the display 55. That is, the MPU 59 decompresses the image data composed of the right-eye image and the left-eye image compressed in the JPEG format from the HDD 51 or the like, and then reads the image data into the RAM 52, from the input device 7 operated by the user. 5 is cut out from the predetermined area of the right eye image 41a and the left eye image 41b shown in FIG. 5, and the cut out right eye cut image data is output to the memory unit 56a of the VRAM 56, and the left eye cut image is output. The data is output to the memory unit 56b. Next, the VRAM 56 alternately outputs cut-out image data for the right eye from the memory unit 56a and cut-out image data for the left eye from the memory unit 56b. Here, each cut-out image data is output to a display 55 of a progressive method in which all of the scanning lines are drawn in order. On the display 55, a cut-out image for the right eye and a cut-out image for the left eye are alternately displayed, and the user wearing the shutter glasses 4 can see the image displayed on the display 55 in a three-dimensional manner.
[0041]
By the way, when the right-eye image and the left-eye image are displayed on the progressive display 55, as shown in FIGS. 1 and 6, the right-eye cut image and the left-eye cut image are displayed for one frame. Is read out from the memory units 56a and 56b of the VRAM 56 and displayed alternately. In the shutter glasses 4, it is necessary to switch the shutters of the right-eye lens unit 4a and the left-eye lens unit 4a in synchronization with this switching. For this reason, a glasses control device 6 for controlling the shutter glasses 4 is attached between the display 55 and the VRAM 56.
[0042]
As shown in FIG. 7, the eyeglass control device 6 outputs the right-eye cut image data and the left-eye cut image data for one frame stored in the memory units 56 a and 56 b of the VRAM 56 to the display 55. A detection unit 61 that detects a vertical synchronization signal of each image data, one is connected to the detection unit 61, and the other is a terminal 62 of the right-eye lens unit 4a of the shutter glasses 4 and a terminal 63 of the left-eye lens unit 4b. And a switch 64 selectively connected to the switch.
[0043]
As shown in FIG. 8A, when the right-eye cut image data and the left-eye cut image data are alternately output from the VRAM 56 to the display 55, the detection unit 61 detects the vertical synchronization signal of each cut image data. Is detected. For example, when the cut-out image data for the right eye is output from the memory unit 56a of the VRAM 56, the detection unit 61 detects a vertical synchronization signal of the cut-out image data. When detecting the vertical synchronization signal of the cut-out image data for the right eye, the detection unit 61 allows the user to view the cut-out image data for the left eye to be displayed next with the left eye, as shown in FIG. 8B. In order to do so, the switch 64 is switched so that the left-eye lens unit 4b of the shutter glasses 4 is turned off and the right-eye lens unit 4a is turned on as shown in FIG. 8C. Thereby, when the cut-out image for the left eye is displayed on the display 55, the left-eye lens unit 4b is in a see-through state, and the right-eye lens unit 4a is in a see-through state.
[0044]
Next, when the detection unit 61 detects the vertical synchronization signal of the currently displayed left-eye cut-out image data, as shown in FIG. 8C, the right-eye cut-out image data to be displayed next is displayed on the user. Is switched off so that the right-eye lens portion 4a of the shutter glasses 4 is turned off and the left-eye lens portion 4b is turned on as shown in FIG. 8B. 64 is switched. Thereby, when the cut-out image for the right eye is displayed on the display 55, the right-eye lens unit 4a is in a see-through state, and the left-eye lens unit 4b is in a see-through state. Thereafter, by switching the shutters of the right-eye lens unit 4a and the left-eye lens unit 4b of the shutter glasses 4 in accordance with the switching timing of the right-eye cut image and the left-eye cut image, as described above, The user can see the image displayed on the display 55 in three dimensions.
[0045]
The case where the interlaced display 55 is used will be described. The memory 56a of the VRAM 56 described above stores the right-eye cut-out image data in the horizontal scanning line data for each line, for example, the right eye in which even-numbered lines are thinned out. Cut-out image data is recorded, and left-eye cut-out image data in which the horizontal scanning line data of the left-eye cut-out image data is thinned out for each line, for example, odd-numbered lines, is recorded in the memory 56b. . Then, from the memory 56a, the cut-out image data for the right eye is output as image data for one field to the display 55, and the cut-out image data for the left eye is output from the memory 56b to the image for the next one field. Output as data. Therefore, as shown in FIG. 9A, the display 55 first displays an image with even-numbered lines thinned out, and then displays an image with odd-numbered lines thinned out.
[0046]
At this time, the glasses control device 6 controls the shutter glasses 4 as follows. That is, as shown in FIG. 9B, when the cut-out image data for the right eye for the first field is output from the memory 56a, the detection unit 61 detects the vertical synchronization signal provided at the end of this field. To do. When detecting the vertical synchronization signal of the cut-out image data for the right eye, the detection unit 61 allows the user to view the cut-out image data for the left eye to be displayed next with the left eye, as shown in FIG. 9C. In order to do so, the switch 64 is switched so that the left-eye lens unit 4b of the shutter glasses 4 is turned off and the right-eye lens unit 4a is turned on as shown in FIG. 9D. Thereby, when the cut-out image for the left eye is displayed on the display 55, the left-eye lens unit 4b is in a see-through state, and the right-eye lens unit 4a is in a light-shielding state.
[0047]
Next, when detecting the vertical synchronization signal of the currently displayed left-eye cut-out image data as shown in FIG. 9B, the detection unit 61 displays the next as shown in FIG. 9D. In order to allow the user to view the cut-out image data for the right eye with the right eye, the right-eye lens unit 4a of the shutter glasses 4 is turned off, and as shown in FIG. The switch 64 is switched so as to turn on the lens unit 4b. Thereby, when the cut-out image for the right eye is displayed on the display 55, the right-eye lens unit 4a is in a see-through state, and the left-eye lens unit 4b is in a see-through state. Thereafter, by switching the shutters of the right-eye lens unit 4a and the left-eye lens unit 4b of the shutter glasses 4 in accordance with the switching timing of the right-eye cut image and the left-eye cut image, as described above, The user can see the image displayed on the display 55 in three dimensions.
[0048]
Even in the case of the progressive method, as described above, for example, right-eye cut-out image data in which even-numbered lines are thinned out is recorded in the memory unit 56a, and odd-numbered lines are thinned out to the left. Cut-out image data for the eye may be recorded. In this case, like the interlace method, the cut-out image for the right eye in which the even-numbered lines are thinned out and the cut-out image for the left eye in which the odd-numbered lines are thinned are alternately displayed on the display 55. Even when the right-eye cut-out image data and the left-eye cut-out image data are output to the VRAM 56 by thinning out the horizontal lines, the CCD element 12 of the digital camera 2 has several million pixels as described above. Since things are used, the user is not made to feel the deterioration of the image quality.
[0049]
Next, processing using the control device 3 for image data captured by attaching the adapter 5 to the digital camera 2 described above, that is, image data editing processing will be described with reference to FIG.
[0050]
First, in step S1, for example, when an icon for starting an editing program displayed on the display 55 is clicked with the mouse 57b, the MPU 59 reads the editing program from the HDD 51 into the RAM 52 and starts it, and the process proceeds to step S2.
[0051]
In step S2, the MPU 59 selects an image data file to be edited based on a command from the input device 57 including the keyboard 57a and the mouse 57b, and opens the selected file. Here, the image data is a file compressed in the JPEG format. Specifically, when the digital camera 2 and the control device 3 are connected by USB, the MPU 59 decompresses the corresponding file from the memory 17 of the digital camera 2 by the compression / decompression unit 58 and then reads the file to the RAM 52. When the IC card 8 is attached to the third drive, the corresponding file is decompressed from the IC card 8 by the compression / decompression unit 58 and read out to the RAM 52. When the corresponding file is recorded in the HDD 51, the file is compressed / compressed by the HDD 51. After decompression by the decompression unit 58, the data is read out to the RAM 52, and the process proceeds to step S3.
[0052]
In step S3, the MPU 59 outputs the read image data once recorded in the RAM 52 to the progressive or interlace display 55 via the VRAM 56, displays the image on the display 55, and proceeds to step S4. In step S3, the display 41 displays the image 41 shown in FIG. That is, on the display 55, the right-eye image 41a and the left-eye image 41b are displayed as one image side by side in the horizontal direction. The right-eye image 41a and the left-eye image 41b are shifted by the amount of left and right parallax. Note that the boundary portion 42 between the right-eye image 41a and the left-eye image 41b is displayed as a slightly blurred white line.
[0053]
In step S4, the MPU 59 displays a dividing line 71 for dividing the image 41 into the right eye image 41a and the left eye image 41 in the vertical direction of the display 55 as shown in FIG. The dividing line 71 is held by the pointer 72 when the mouse 57b is clicked, and is moved so as to overlap the boundary portion 42 of the image 41 with the user's eyes. Accordingly, the MPU 59 divides the image 41 into a right eye image 41a and a left eye image 41b. Thus, the user can easily distinguish the right-eye image 41a and the left-eye image 41b.
[0054]
In step S5, as shown in FIG. 11B, the MPU 59 makes it easy to see the vertical center of the right-eye image 41a and the left-eye image 41b divided by the division line 71 displayed on the display 55. The vertical center line 73a for the right eye image 41a and the vertical center line 73b for the left eye image 41b are displayed. Here, the MPU 59 displays the vertical center line 73a for the right eye image 41a and the vertical center line 73b for the left eye image 41b so that the distance from the division line 71 is equal. The vertical center line 73a for the right-eye image 41a is held by the pointer 72 when the mouse 57b is clicked, and is visually moved to the vertical center desired by the user. The In the same manner, the vertical center line 73b for the left eye image 41b is automatically moved in the same direction by the same amount as the movement amount of the vertical center line 73a for the right eye image 41a. Thus, the MPU 59 makes it easy for the user to see the vertical center of the right eye image 41a and the vertical center of the left eye image 41b, and the set vertical center lines 73a and 73b are used for the right eye in the next step. The image 41a and the left-eye image 41b are used as a guide for the cutting operation.
[0055]
In step S6, the MPU 59 makes it easy to see the horizontal center of the right-eye image 41a and the left-eye image 41b divided by the division line 71 displayed on the display 55, as shown in FIG. The horizontal center line 74 is displayed. Here, the MPU 59 displays the image for the right eye 41a and the image for the left eye 41b at the center in the vertical direction. The horizontal center line 74 is held by the pointer 72 when the mouse 57b is clicked, and is visually moved to the horizontal center desired by the user. Thus, the MPU 59 makes it easy for the user to see the horizontal center of the right-eye image 41a and the left-eye image 41b, and the right-eye image 41a and the left-eye image 41b with the vertical center lines 73a and 73b described above. The center points 75a and 75b are easily identified, and the next step is used as a guide for cutting out the right-eye image 41a and the left-eye image 41b.
[0056]
The center points 75a and 75b can be readjusted. That is, the vertical center lines 73a and 73b can be adjusted by moving the center line 73a for the right-eye image 41a in the horizontal direction again as shown in FIG. Adjustment of 74 can be performed by moving the horizontal center line 74 in the vertical direction, as shown in FIG.
[0057]
In step S <b> 7, the MPU 59 performs a process for cutting out an image desired by the user. Specifically, in the right-eye image 41a, the user determines the start point 76 with the pointer 72 of the mouse 57b with reference to the vertical center line 73a, the horizontal center line 74, and the center point 75a, and the pointer 72 moves in the diagonal direction. Then, as shown in FIG. 11D, a substantially rectangular cut line 77a is displayed in the right eye image 41a. In the same manner, the MPU 59 displays a cut line 77b having the same shape as the cut line 77a in the left-eye image 41b. At this time, the MPU 59 determines that the interval between the dividing line 71 and the line on the dividing line 71 side of the cutoff line 77a is the same as the dividing line 71 of the left-eye image 41b. Opposite side The cut line 77b is displayed so as to be equal to the distance between the side edge of the cut line 77b and the line on the side edge side of the cut line 77b.
[0058]
Thus, the MPU 59 generates image data of the right-eye cut image 78a and image data of the left-eye cut image 78b for stereoscopic display on the display 55. Incidentally, as described above, the user may want to see how the user stereoscopically displays on the display 55 before saving the image data actually cut out in the HDD 51. Therefore, in step S8, the MPU 59 outputs the image data of the right-eye cut image 78a and the image data of the left-eye cut image 78b to the VRAM 56, and activates the preview mode. Details of this preview mode will be described later. In step S <b> 10, the MPU 59 compresses the image data of the right-eye cut image 78 a and the image data of the left-eye cut image 78 b into the JPEG format by the compression / decompression unit 58 and then saves the data in the HDD 51. Details of this storage method will be described later.
[0059]
In the image data editing processing method as described above, a user-desired region is cut out from the image data of the image 41, so that a stereoscopic image that suits the user's preference can be displayed on the display 55. . Further, when editing the image data of the image 41, the vertical center lines 73a and 73b and the horizontal center line 74 are displayed on the display 55, so that the user can easily cut out the image 41. it can.
[0060]
Since the editing operation of the image 41 as described above is performed using the right-eye image 41a, the display unit 55 is used for the editing operation by causing the MPU 59 to automatically recognize the boundary portion 42. Only the right eye image 41a may be displayed.
[0061]
Next, the preview mode in step S8 will be described with reference to FIG. In step S <b> 11, the MPU 59 activates the preview mode based on a command from the input device 57.
[0062]
In step S <b> 12, the MPU 59 displays a display format selection screen on the display 55. Here, as a mode of displaying a stereoscopic image, as shown in FIG. 13A, a substantially rectangular frame 79a having an aspect ratio of 3: 4 and an aspect ratio of 9 as shown in FIG. 16 is a substantially rectangular frame 79b, and as shown in FIG. 13C, there is a substantially circular frame 79c. Then, based on the command from the input device 57 by the user, the MPU 59 selects any one frame 79 from the frames shown in FIGS. 13A to 13C and proceeds to step S13. .
[0063]
In step S13, the output order from the VRAM 56 of the image data of the right-eye cut image 78a and the image data of the left-eye cut image 78b is determined based on the input signal from the input device 57 by the user. Specifically, the output order is to display on the display 55 from the image data of the right-eye cut image 78a or to display on the display 55 from the image data of the left-eye cut image 78b.
[0064]
In step S14, the MPU 59 alternately displays the right-eye cut image 78a and the left-eye cut image 78b so that the display 55 has parallax. Specifically, the MPU 59 outputs the image data of the right-eye cut image 78 a to the memory unit 56 a of the VRAM 56, and outputs the image data of the left-eye cut image 78 b to the memory unit 56 b of the VRAM 56. The VRAM 56 alternately outputs the image data of the right-eye cut image 78a and the image data of the left-eye cut image 78b to the display 55 based on the output order of the image data determined in step S13. In addition, the right-eye cut image 78a and the left-eye cut image 78b are alternately displayed.
[0065]
As a result, as shown in FIG. 14A and FIG. 14B, the cut-out image 78a for the right eye and the cut-out image 78b for the left eye are displayed on the display 55 as being shifted. Specifically, the right-eye cut image 78a and the left-eye cut image 78b displayed on the display 55 are displayed such that the shift amount is 0 at the position of the user's viewpoint, and the shift amount is a position where the shift amount is 0. Are displayed so that the amount of deviation increases in the direction toward the front or the direction toward the back as viewed from the user. Hereinafter, the position where the deviation amount is 0 is referred to as a cross point 81. That is, in the image shown in FIG. 14A, when the position of the person is the cross point 81, the mountain is displayed in a direction that is behind the person and the flower is in front of the person. It is displayed with the direction shifted.
[0066]
Further, as described above, the glasses control device 6 switches the shutters of the right-eye lens unit 4a and the left-eye lens unit 4b in accordance with the output order of the image data in step S13. In this switching, the spectacles control device 6 detects the vertical synchronization signal of the image data of the right-eye cut image 78 a and the image data of the left-eye cut image 78 b by the detection unit 61, and the right-eye image displayed on the display 55 is displayed. The shutter of the right-eye lens unit 4a and the left-eye lens unit 4b of the shutter glasses 4 is switched in accordance with the switching timing of the cut-out image 78a and the left-eye cut-out image 78b. Thereby, the user can see the image displayed on the display 55 in three dimensions. In subsequent steps, the user performs preview mode processing with the shutter glasses 4 on.
[0067]
In step S15, the depth adjustment, that is, the adjustment of the cross point 81 is performed in order to make the stereoscopic image most visible to the user. That is, the MPU 59 displays adjustment buttons 83 and 84 for adjusting the cross point 81 on the screen 82 shown in FIG. Here, the adjustment button 83 is for moving the cross point 81 in front of the plane, that is, horizontally in one direction, and the adjustment button 84 is for moving the cross point 81 in the middle of the screen, that is, horizontally in the other direction. Is for. Since these adjustment buttons 83 and 84 move the cross point 81 in the horizontal direction, they are displayed side by side in the horizontal direction on the screen 82 for easy operation.
[0068]
When the user presses the adjustment button 83 with the input device 57, the MPU 59 moves the cross point 81 forward, that is, in the lower left direction in the screen 82 of FIG. For example, when the cross point 81 moves to the position of the flower, the cut-out image 78a for the right eye and the cut-out image 78b for the left eye at the human position are shifted in one direction on the display 55, and the image at the mountain position is further enlarged. It will be displayed as if it is shifted in one direction. Thereby, it seems to the user wearing the shutter glasses 4 that there is a person in the back and a mountain in the back, based on the flower. When the user presses the adjustment button 84 with the input device 57, the MPU 59 moves the cross point 81 to the back, that is, in the upper right direction in the screen 82 in FIG. For example, when the cross point 81 moves to the mountain position, the cut-out image 78a for the right eye and the cut-out image 78b for the left eye at the human position are shifted in the other direction on the display 55, and the image at the flower position is further enlarged. It will be displayed as if it is shifted in the other direction. As a result, it seems to the user that there is a person in front of the mountain and a mountain in front of it. As described above, the user can perform depth adjustment, that is, adjustment of the cross point 81, at a position where the stereoscopic image is most easily seen.
[0069]
In step S <b> 16, vertical adjustment is performed to make it easier for the user to see the stereoscopic image. That is, when the adapter 5 is attached to the digital camera 2 and photographing is performed, the adapter 5 may be attached to the digital camera 2 so that the image 41 shown in FIG. 5 is inclined. It is difficult to view such an inclined image 41 in a three-dimensional manner. Therefore, in this step S16, the MPU 59 displays on the screen 82 adjustment buttons 85 and 86 for adjusting the right-eye cut image 78a and the left-eye cut image 78b in the vertical direction. When the user presses the adjustment button 85 with the input device 57, the MPU 59 shifts the right-eye cut image 78a upward and the left-eye cut image 78b downward. When the user presses the adjustment button 86 with the input device 57, the MPU 59 shifts the right-eye cut image 78a downward and the left-eye cut image 78b upward. As described above, the user can adjust the vertical positions of the right-eye cut-out image 78a and the left-eye cut-out image 78b to the position where the stereoscopic image can be seen most easily. Since the adjustment buttons 85 and 86 move the image in the vertical direction, the adjustment buttons 85 and 86 are displayed side by side in the vertical direction in the screen 82 for easy operation.
[0070]
In the play view mode as described above, the depth and the cross point 81 are adjusted with the adjustment buttons 83 and 84 provided on the screen 82, and the right eye is cut out with the adjustment buttons 85 and 86 provided on the screen 82. Since the vertical adjustment of the image 78a and the left-eye cut-out image 78b can be performed, before the right-eye cut-out image 78a and the left-eye cut-out image 78b are stored in the HDD 51, the user is most stereoscopic. Images can be saved in an easy-to-view state.
[0071]
By the way, as shown in FIG. 15, for example, the input device 57 is configured on the stereoscopic image 78 in which the right-eye cut image 78a and the left-eye cut image 78b are alternately displayed in the above-described play view mode. The pointer 72 of the mouse 57b may be moved. At this time, if the pointer 72 is displayed two-dimensionally, that is, in a display state at the cross point 81, it is difficult for the user to see the pointer 72. Therefore, the MPU 59 shifts the pointer 72 in accordance with the parallax of the position of the pointer 72 on the stereoscopic image 78, that is, the shift amount of the right-eye cut image 78a and the left-eye cut image 78b. That is, as shown in FIG. 15, when the cross point 81 is at a person's position and the pointer 72 is near the back mountain in the stereoscopic image 78, the MPU 59 The pointer 72 is also displayed while being shifted in accordance with the shift amount of the left-eye cutout image 78b. When the pointer 72 is near the flower in the middle of the stereoscopic image 78, the MPU 59 cuts out the right-eye cutout at this position. The pointer 72 is also shifted and displayed in accordance with the shift amount between the image 78a and the left-eye cutout image 78b. Furthermore, when the pointer 72 is at the cross point 81, the MPU 59 displays the two-dimensional image without shifting the pointer 72 because there is no shift between the right-eye cut image 78a and the left-eye cut image 78b. Thus, when the pointer 72 moves on the stereoscopic image 78 for stereoscopic display, the user is always displayed according to the parallax of the image in the background, and the pointer 72 can be viewed stereoscopically. It is possible to prevent the user from seeing the pointer 72.
[0072]
Further, as shown in FIG. 15, when the image 41 is being edited, a character 87 can be input into the image 41. That is, when the position for inputting the character 87 in the stereoscopic image 78 is designated by the pointer 72 of the mouse 57b and the character (for example, “A”) is input by the keyboard 57a, the MPU 59 sets the character at the position in the stereoscopic image 78. 87 is displayed. At this time, the MPU 59 shifts the character 87 in accordance with the parallax on the coordinates where the character 87 on the stereoscopic image 78 is input, that is, the shift amount between the right-eye cut image 78a and the left-eye cut image 78b. indicate. That is, when the cross point 81 is at a person's position and the character 87 is displayed near a mountain in the back of the stereoscopic image 78, the MPU 59 causes the right-eye cut image 78a and the left-eye cut image 78b to be displayed at this position. The character 87 is also displayed so as to be shifted in accordance with the shift amount of the image, and when the character 87 is near the flower in the front of the three-dimensional image 78, the MPU 59 displays the right-eye cut image 78a and the left-eye cut-off at this position. Characters 87 are also shifted and displayed in accordance with the shift amount of the output image 78b. Furthermore, when the character 87 is displayed at the cross point 81, the MPU 59 displays the two-dimensional image without shifting the character 87 because there is no shift between the right-eye cut image 78a and the left-eye cut image 78b. To do. Thus, when the user displays the character 87 on the stereoscopic image 78 that performs stereoscopic display, the character 87 is always displayed in accordance with the parallax of the image in the background, and the character 87 can also be viewed stereoscopically. The character 87 can be prevented from being difficult to see. Further, when the shift amount of the character 87 is matched with the shift amount in the foreground in the image, the character 87 appears to the user as the forefront, and the character 87 can be emphasized.
[0073]
14A, when the right-eye cut image 78a and the left-eye cut image 78b are alternately displayed, the reference plane is the screen 82 of the display 55 or the screen shown in FIG. A frame 79 is formed. That is, the screen 82 and the frame 79 on the screen have a planar display form that does not consider parallax. For this reason, the user who is viewing the stereoscopic image 78 of FIG. 14A wearing the shutter glasses 4 displays the periphery of the stereoscopic image 78 displayed on the screen 82 in a planar manner. It becomes difficult to view the image 78 three-dimensionally. Therefore, a frame 88 having a predetermined width such as a frame is displayed around the stereoscopic image 78 as shown in FIG. When the amount of shift of the frame 88 is the most visible, for example, the same or more than the amount of shift of the flower, the stereoscopic image 78 seems to be displayed stereoscopically on the inside of the frame 88. Can show. In addition, when the amount of shift of the frame 88 is the deepest, for example, the amount of shift of the mountain is equal to or greater than the amount of shift of the mountain, the stereoscopic image 78 seems to have popped out of the frame 88 to the user. Can show. As described above, by providing the frame 88 having a predetermined width around the stereoscopic image 78, the stereoscopic image can be more easily seen by the user.
[0074]
Next, a method for managing the image data of the three-dimensional image 78 composed of the image data of the right-eye cut image 78a and the left-eye cut image 78b edited as described above, that is, in FIG. The method for managing cut image data in step S9 will be described with reference to FIG. When the image data of the right-eye cut image 79a and the image data of the left-eye cut image 79b shown in FIG. 14A are to be saved, first, the save button 89 displayed on the screen 82 with the mouse 57b of the input device 57 or the like. Is pressed. When the save button 89 is pressed by the pointer 72, the MPU 59 saves the image data of the right-eye cut image 79a and the image data of the left-eye cut image 79b on the RAM 52 to the HDD 51 or the IC card 8 via the bus. Specifically, as illustrated in FIG. 17, the MPU 59 includes information including a right-eye cut-out image data file 92, a left-eye cut-out image data file 93, and information relating these files 92 and 93 in the folder 91. Save the file 94.
[0075]
The right-eye cut image data file 92 is image data of the right-eye cut image 78a cut in step S7 in FIG. 10, and this image data is compressed by the compression / expansion unit 58 into the JPEG format. The left-eye cut image data file 93 is image data of the right-eye cut image 78b, and this image data is compressed by the compression / decompression unit 58 in the JPEG format.
[0076]
The information file 94 records the coordinates of the cross point 81 when the right-eye cut image 78a and the left-eye cut image 78b are alternately displayed. As described above, when the cut-out image data for the right eye with the even-numbered lines thinned out and the cut-out image data for the left eye with the odd-numbered lines thinned are displayed on the display 55, Line information indicating whether the data is the first line is recorded. That is, the information file 94 records data necessary for reproducing the stereoscopic image at the time of storage.
[0077]
In the data management method as described above, the right-eye cut-out image data file 92, the left-eye cut-out image data file 93, and the information file 94 are provided separately, so that these data are compressed and decompressed. You can re-edit. That is, since the folder 91 includes the right-eye cut image data file 92 and the left-eye cut image data file 93, the user again stores the right-eye cut image 78a and the left-eye cut image 78b. Re-editing such as enlargement or reduction can be performed.
[0078]
Further, the image data of the right-eye cut image 78a and the image data of the left-eye cut image 78b can be stored as shown in FIG. That is, the folder 96 includes an image data file 97 composed of image data composed of the right eye image 41a and the left eye image 41b shown in FIG. An information file 98 composed of information for generating the eye cut image 78b is recorded. That is, the image data file 97 is obtained by compressing the image data before the editing process shown in FIG. 10 into the JPEG format by the compression / decompression unit 58. Further, the information file 98 is recorded with position data of the dividing line 71, position data of the vertical center lines 73a and 73b, position data of the horizontal center line 74, and position data of the cut lines 77a and 77b shown in FIG. Yes. The information file 96 records the coordinates of the cross point 81 when the right-eye cut image 78a and the left-eye cut image 78b are alternately displayed. Further, when the cut-out image data for the right eye with the even-numbered lines thinned out and the cut-out image data for the left eye with the odd-numbered lines thinned are displayed on the display 55, which data is the first. Line information indicating whether the line is to be recorded is recorded. That is, the information file 98 records data necessary for reproducing the stereoscopic image at the time of storage.
[0079]
In the data management method as described above, the image data composed of the right-eye image 41a and the left-eye image 41b is stored. Therefore, even if this image data is compressed and expanded, the storage method shown in FIG. Further editing operations can be performed. Specifically, in this management method, an editing operation as shown in FIG. 10 is performed, such as reading out the image data file 97 and the information file 98 from the folder 96 and again cutting the image as shown in FIGS. Edit work can be done.
[0080]
Further, the image data of the right-eye cut image 78a and the image data of the left-eye cut image 78b can be stored as follows. That is, this storage method stores composite image data in which the horizontal scanning line data of the image data of the right-eye cut image 78a and the horizontal scanning line data of the image data of the left-eye cut image 78b are alternately stored. As shown in FIG. 19, the folder 101 contains right-eye cut-out image data in which even-numbered lines are thinned out and left-eye cut-out image data in which odd-numbered lines are thinned out. A composite image data file 102 in which the composite image data that has been combined is recorded is recorded.
[0081]
In such a management method, the information file is not provided in the image data management method shown in FIGS. 17 and 18 above, so that re-editing cannot be performed, but the data size can be reduced. it can. In this folder 101, in addition to the composite image data file 102, a cut-out image data file 92 for the right eye, a cut-out image data file 93 for the left eye shown in FIG. An information file 94 composed of information to be stored may be stored. Further, in this folder 101, in addition to the composite image data file 102, an image data file 97 composed of image data composed of the right eye image 41a and the left eye image 41b shown in FIG. You may make it preserve | save the information file 98 which consists of the information for producing | generating the image 78a for right eyes, and the image 78b for right eyes from the file 97. FIG.
[0082]
The different data management methods have been described above with reference to FIGS. 17 to 19, but the control device 3 stores image data in the HDD 51 by any one of the different data management methods illustrated in FIGS. 17 to 19. Alternatively, any one of these methods may be selected and stored in the HDD 51. For example, the saving method shown in FIG. 17 is convenient when the editing operation is interrupted and re-editing is performed. When the saving method shown in FIG. 18 is attached to an email and transmitted to the other party, the other party enlarges the image. It can be reduced and is convenient. Further, the saving method shown in FIG. 19 is convenient for saving a homepage or the like.
[0083]
Now, a browser that reads the data edited by the editing program as described above and saved in the recording means such as the HDD 51 in the format shown in FIGS. 17 to 19 and displays the data on the display 55 will be described.
[0084]
First, the activation of the browser will be described with reference to FIG. 20. In step S 21, for example, when the icon for starting the browser displayed on the display 55 is clicked with the mouse 57 b, the MPU 59 loads the browser program from the HDD 51. The data is read into the RAM 52, and the process proceeds to Step S22.
[0085]
In step S22, the MPU 59 displays the activation screen 111 shown in FIG. At this time, although details will be described later, the eyeglass control device 6 detects the signal on the activation screen 111 and controls on / off of the right-eye lens unit 4a and the left-eye lens unit 4b of the shutter glasses 4.
[0086]
In step S <b> 24, the MPU 59 displays the browser 112 on the screen 82 of the display 55. That is, the VRAM 56 outputs the image data for the right eye of the browser 112 from the memory unit 56 a to the display 55, and outputs the image for the left eye of the browser 112 to the display 55 from the memory unit 56 b. On the display 55, the right-eye image and the left-eye image of the browser 112 are alternately displayed so as to have a parallax. Thereby, the user wearing the shutter glasses 4 can view the screen of the browser 112 in three dimensions.
[0087]
In step S25, the MPU 59 opens the image data folder to be edited, that is, the folders 91, 96, and 101 shown in FIGS. 17 to 19, based on the command from the input device 57 including the keyboard 57a and the mouse 57b. Here, since the selected files 91, 96, 101 are compressed in the JPEG format, the MPU 59 decompresses the files 91, 96, 101 by the compression / decompression unit 58, reads them to the RAM 52, and displays the display 55. The right-eye cut image 78a and the left-eye cut image 78b are alternately displayed on the browser 112 displayed in FIG. That is, the VRAM 56 displays on the display 55 the right-eye cut image data in which the even-numbered lines recorded in the information files 94 and 98 are thinned and the left-eye cut-out image data in which the odd-numbered lines are thinned. In this case, based on the line information indicating which data is the first line, first, the image data of the right-eye cut image 78a is output from the memory unit 56a, and then the left-eye cut image 78b. The image data is output from the memory unit 56b, and thereafter, the three-dimensional image 78 is displayed on the display 55 by repeating this. Therefore, the right-eye cut image 78a and the left-eye cut image 78b are displayed further three-dimensionally in the three-dimensional frame 113 as viewed from the user wearing the shutter glasses 4. Become. In this way, by further displaying the stereoscopic image 78 in the stereoscopic frame 113, the browser 112 makes it easy for the user to see the stereoscopic image.
[0088]
Further, the termination operation of the browser 112 will be described with reference to FIG. 22. When the termination instruction unit 114 consisting of “X” in the corner portion of the browser 112 is clicked with the mouse 57b in step S31, the MPU 59 The termination operation of the browser 112 is started. Then, in step S32, the MPU 59 displays an end screen 115 that is substantially the same as the start screen 111 in the approximate center of the screen 82 of the display 55, as shown in FIG. At this time, although details will be described later, the spectacles control device 6 detects the signal on the end screen 115 and turns off both the right-eye lens unit 4a and the left-eye lens unit 4b of the shutter glasses 4. In step S33, the MPU 59 completes the end operation of the browser 112.
[0089]
By the way, when the browser 112 is activated, the shutter glasses 4 need to be driven. For this reason, when the activation screen 111 is displayed on the screen 82 of step S22 shown in FIG. 6 detects whether the browser 112 is activated. That is, when the browser 112 is activated, as shown in FIG. 24A, the VRAM 56 supplies a video signal of, for example, a white → black → white → black pattern for displaying the activation screen 111 on the display 55. Like to do.
[0090]
Here, the detection unit 61 of the spectacles control device 6 shown in FIG. 7 detects an image signal of a white → black → white → black pattern, and in step S25 in FIG. 20, the browser first output from the memory unit 56a. The right eye lens unit 4a of the shutter glasses 4 is turned off so that the user can see the right eye image with the right eye by matching the image data of the right eye image 112 with the output. The switch 64 is switched so that the ophthalmic lens unit 4b is turned on. Thereby, when the right-eye image is displayed on the display 55, the right-eye lens unit 4a is in a see-through state, and the left-eye lens unit 4b is in a light-shielding state.
[0091]
Next, as illustrated in FIG. 8 described above, when the detection unit 61 detects the vertical synchronization signal of the right-eye image data, the user views the left-eye image data of the browser 112 displayed next with the left eye. Therefore, the switch 64 is switched so that the left-eye lens portion 4b of the shutter glasses 4 is turned off and the right-eye lens portion 4a is turned on. Thereby, when the image for left eyes is displayed on the display 55, the lens part 4b for left eyes will be in a see-through state, and the lens part 4a for right eyes will be in a light-shielding state. Thereafter, by switching the shutters of the right-eye lens unit 4a and the left-eye lens unit 4b of the shutter glasses 4 in accordance with the switching timing of the right-eye image 78a and the left-eye image 78b as described above, The user can view the image of the browser 112 displayed on the display 55 in three dimensions.
[0092]
The MPU 59 detects an image signal of a white → black → white → black pattern, thereby converting an icon, a character, or the like of an area on the screen 82 where the browser 112 is not displayed into an image having parallax. What is displayed on the entire screen may be viewed three-dimensionally. As a result, the entire screen becomes a three-dimensional display image, and it is possible to prevent a region where the three-dimensional image 78 composed of the right-eye cut image 78a and the left-eye cut image 78b is not displayed from flickering. As described above, the video signal of the white → black → white → black pattern is used as a synchronizing signal for synchronizing the shutter glasses 4 and the image displayed on the display 55 and detects that the browser 112 is opened. It is used as a detection signal for
[0093]
Further, when the browser 112 is terminated, the driving of the shutter glasses 4 needs to be stopped. For this reason, when the end screen is displayed on step S32 shown in FIG. The apparatus 6 detects whether or not the browser 112 has been terminated. That is, when the browser 112 ends, as shown in FIG. 24B, the VRAM 56 supplies an image signal of, for example, a white → black → black → white pattern for displaying the end screen 115 on the display 55. I am doing so.
[0094]
Here, when the detection unit 61 of the glasses control device 6 shown in FIG. 7 detects a video signal of a white → black → black → white pattern, a stereoscopic image cannot be seen thereafter, so the right side of the shutter glasses 4 Both the ophthalmic lens unit 4a and the left-eye lens unit 4b are turned off, and both the right-eye lens unit 4a and the left-eye lens unit 4b are made transparent. That is, the shutter glasses 4 are turned off and the lens units 4a and 4b are made transparent so that the planar display can be easily seen when the user does not activate the browser 112.
[0095]
In addition, when the icons, characters, etc. of the area on the screen 82 where the browser 112 is not displayed are changed to an image having parallax so that the user can see what is displayed on the entire screen in three dimensions. In other words, by detecting the video signal of this white → black → black → white pattern, the MPU 59 stops the image having parallax for icons, characters, and the like, and switches to an image without deviation. That is, the video signal of the white → black → black → white pattern is used as a detection signal for turning off the shutter glasses 4 and as a detection signal for detecting that the browser 112 is closed. .
[0096]
As described above, when the browser 112 is activated, the video signal of the white → black → white → black pattern is output from the VRAM 56, and the eyeglass control device 6 detects this signal, whereby the display 55 is displayed. The switching of the liquid-crystal shutters of the right-eye lens unit 4a and the left-eye lens unit 4b of the shutter glasses 4 is controlled in synchronization with the right-eye image data and the left-eye image data of the browser 112 that are alternately output. Can do. Thereby, for example, when the right-eye image is displayed on the display 55, the right-eye lens unit 4a is in a see-through state, the left-eye lens unit 4b is in a see-through state, and the right-eye image is viewed with the left eye. The trouble can be eliminated. When the browser 112 ends, the video signal of the white → black → black → white pattern is output from the VRAM 56 and this signal is detected by the glasses detection device 6, so that the right eye of the shutter glasses 4 can be detected. By turning off both the lens unit 4a for the left eye and the lens unit 4b for the left eye, and making both the lens unit 4a for the right eye and the lens unit 4b for the left eye transparent, it is possible to make the planar display easy to see. Further, by using the image signals as described above for the start screen 111 and the end screen 115, it is possible to prevent the user from seeing.
[0097]
Note that the video signal at the start and end of the browser 112 is not limited to the white → black → white → black pattern or the white → black → black → white pattern at the start, and is not easily noticeable. Any color or combination may be used as long as it is a color pattern.
[0098]
Incidentally, there is a case where a second stereoscopic image is further superimposed on the stereoscopically displayed browser 112 that becomes the first stereoscopic image and displayed on the display 55. For example, as illustrated in FIG. 25, a stereoscopic image that has already been cut out is pasted on the browser 112 or the stereoscopic image 78 displayed on the browser 112 is moved. As shown in FIGS. 9 and 25, a right-eye cut-out image in which even-numbered lines of horizontal scanning line data are thinned out and a left-eye cut-out in which odd-numbered lines of horizontal scanning line data are thinned out. In the case of alternately displaying images, when the stereoscopic image 78 is pasted or moved on the browser 112, the left eye line of the stereoscopic image 78 is positioned on the right eye line of the browser 112. It may end up. That is, the stereoscopic image 78 displays the left-eye image when the browser 112 displays the right-eye image, or the stereoscopic image 78 displays the right-eye when the browser 112 displays the left-eye image. An image for use will be displayed. In this case, the user cannot see the stereoscopic image 78 stereoscopically. Therefore, as shown in FIG. 25, when the browser 112 moves the stereoscopic image 78 and the line of the browser 112 does not match the line of the stereoscopic image 78, the browser 112 converts the stereoscopic image 78 to one line in the vertical direction. The line of the browser 112 and the line of the stereoscopic image 78 are made to coincide with each other.
[0099]
Specifically, as shown in FIG. 26, in step S41, for example, the stereoscopic image 78 at the first position at the upper left in FIG. 25 is selected by the mouse 57b, and the stereoscopic image 78 at the second position at the lower right in FIG. In step S42, the MPU 59 moves the stereoscopic image 78 at the first position to the second position or pastes the stereoscopic image 78.
[0100]
In step S43, the MPU 59 determines that Y at the most upstream coordinate A (X, Y) in the scanning direction is for the right eye of the browser 112 at the second position where the stereoscopic image 78 is moved or pasted. It is detected whether it is on the horizontal scanning line or the horizontal scanning line for the left eye. Then, the MPU 59 ends the process when the first horizontal scanning line of the stereoscopic image 78 matches the horizontal scanning line of the browser 112, and proceeds to step S44 when they do not match. That is, when the first horizontal scanning line of the stereoscopic image 78 is for the right eye and Y is on the horizontal scanning line for the right eye of the browser 112, the horizontal scanning line of the browser 112 is displayed. The MPU 59 finishes the process assuming that the line of the first horizontal scanning line of the stereoscopic image 78 coincides with this line. Further, when the first horizontal scanning line of the stereoscopic image 78 is for the right eye and Y is on the horizontal scanning line for the left eye of the browser 112, the horizontal scanning line of the browser 112 is displayed. The MPU 59 proceeds to step S44 on the assumption that this line does not match the first horizontal scanning line of the stereoscopic image 78.
[0101]
In step S44, the MPU 59 moves the stereoscopic image 78 by one line up or down. As a result, the MPU 59 matches the first horizontal scanning line of the stereoscopic image 78 with the horizontal scanning line of the browser 112 so that the user can view the stereoscopic image 78 stereoscopically. Then, the MPU 59 ends the process.
[0102]
As described above, in the browser 112, even when the stereoscopic image 78 is moved and the stereoscopic image 78 is pasted, the stereoscopic image 78 is always converted into the line of the browser 112 and the stereoscopic image 78 as the image frame. Therefore, the user can always see a stereoscopic image.
[0103]
In addition, as illustrated in FIG. 27, a stereoscopic image 78 that is a second stereoscopic image displayed on the browser 112 that is a first stereoscopic image may be enlarged or reduced. As shown in FIGS. 9 and 27, the right-eye cut-out image in which even-numbered horizontal scanning lines are thinned out and the left-eye cut-out image in which odd-numbered horizontal scanning lines are thinned out alternately. When the stereoscopic image 78 is enlarged or reduced on the browser 112, the horizontal scanning line for the left eye of the stereoscopic image 78 is displayed on the horizontal scanning line for the right eye of the browser 112. May be located. That is, the stereoscopic image 78 displays the left-eye image when the browser 112 displays the right-eye image, or the stereoscopic image 78 displays the right-eye when the browser 112 displays the left-eye image. An image for use will be displayed. In this case, the user cannot see the stereoscopic image 78 stereoscopically. Therefore, as shown in FIG. 27, when the browser 112 enlarges or reduces the stereoscopic image 78, when the horizontal scanning line of the browser 112 does not match the horizontal scanning line of the stereoscopic image 78, The stereoscopic image 78 is shifted by one line in the vertical direction so that the browser 112 line and the stereoscopic image 78 line coincide.
[0104]
Specifically, as shown in FIG. 28, in step S51, a stereoscopic image 78 is selected by the input device 57, and the display magnification of the selected stereoscopic image 78 is designated. In step S52, the MPU 59 enlarges or reduces the stereoscopic image 78 based on the display magnification specified by the user.
[0105]
Then, in step S53, the MPU 59 determines the coordinate B on the most upstream side in the scanning direction of the image 121a obtained by enlarging the stereoscopic image 78 or the reduced image 121b. ₁ (X ₁ , Y ₁ ), B ₂ (X ₂ , Y ₂ Y) ₁ , Y ₂ Is on the horizontal scanning line for the right eye of the browser 112 or on the line for the left eye. Then, the MPU 59 ends the process when the first horizontal scanning line of the images 121a and 121b matches the horizontal scanning line of the browser 112, and proceeds to step S54 when they do not match. That is, if the first horizontal scanning line of the images 121a and 121b is for the right eye, Y ₁ , Y ₂ Is on the horizontal scanning line for the right eye of the browser 112, the MPU 59 assumes that the line of the browser 112 and the first horizontal scanning line of the stereoscopic image 78 coincide with each other. finish. In addition, when the line of the first horizontal scanning line of the stereoscopic image 78 is for the right eye, Y ₁ , Y ₂ Is located on the horizontal scanning line for the left eye of the browser 112, the MPU 59 determines that the line of the browser 112 and the first horizontal scanning line of the stereoscopic image 78 do not coincide with each other in step S44. Proceed to
[0106]
In step S54, the MPU 59 moves the images 121a and 121b by one line up or down, and matches the first horizontal scanning line of the images 121a and 121b with the horizontal scanning line of the browser 112. As another method, the MPU 59 is closest to the display magnification specified by the user so that the first horizontal scanning line of the images 121a and 121b matches the horizontal scanning line of the browser 112. The images 121a and 121b are enlarged or reduced again. By the above method, the MPU 59 matches the first line of the images 121a and 121b with the horizontal scanning line of the browser 112, and the user views the images 121a and 121b enlarged or reduced in three dimensions. To be able to. Then, the MPU 59 ends the process.
[0107]
As described above, in the browser 112, even when the images 121a and 121b are enlarged or reduced, the lines of the browser 112 and the lines of the stereoscopic image 78, which are the frames of the images 121a and 121b, are always matched. Therefore, the user can always see a stereoscopic image.
[0108]
By the way, an editing program for editing the image 41 composed of the right-eye image 41 a and the left-eye image 41 b as described above and a browser for viewing an image edited by the editing program are stored in the HDD 51. In addition, it can be stored and stored in a recording medium such as a magnetic disk, a magneto-optical disk, an optical disk, or a semiconductor memory. In this case, as shown in FIG. 6, these programs are loaded into the RAM 52 from the recording medium via the bus when the recording medium is loaded in the drive unit 131 and the program is activated by the input device 57. It is. And the process mentioned above is performed by the program read from the recording medium.
[0109]
These programs can also be installed in the HDD 51 from the drive unit 131 via a providing medium provided to the user such as a magnetic disk, a magneto-optical disk, an optical disk, or a semiconductor memory in which the program is recorded. In addition to installing these programs in the HDD 51 via such a providing medium, the programs can also be installed in the HDD 51 via a transmission / reception unit 132 from a download site wirelessly or by wire.
[0110]
Next, a network system 151 using the stereoscopic image system 1 configured as described above will be described with reference to FIG. The network system 151 includes a server device 152 that accumulates stereoscopic image data, and a personal terminal device 153 that accesses the server device 152 and downloads stereoscopic image data. The server device 152 and the plurality of personal terminal devices 153 are connected via a network.
[0111]
The server device 152 has substantially the same configuration as a normal computer, and a storage unit 161 that accumulates stereoscopic image data and the like, and a read that stores various programs such as a program that controls the overall operation. An only memory (Read-Only Memory, hereinafter also referred to as ROM) 162, a RAM 163 that once reads a program or the like recorded in the ROM 162, a transmission / reception unit 164 for transmitting / receiving data to / from the personal terminal device 153, and the whole And a control unit 165 composed of an MPU for controlling.
[0112]
In such a server device 152, a program for controlling the entire operation is once read from the ROM 162 to the RAM 163, and is executed by the control unit 165, whereby the operation of the entire device is controlled. In the server device 152, a home page composed of a stereoscopic image or the like is opened in the storage unit 161, and this home page can be accessed, that is, viewed from the personal terminal device 153.
[0113]
The personal terminal device 153 corresponds to the control device 3 described above and has a similar configuration. That is, as shown in FIG. 29, an HDD 51 in which browsing search software (browser 112) for displaying the image 41 in three dimensions, an e-mail program, and the like, and an application program and the like recorded in the HDD 51 are temporarily stored. RAM 52 to be read, display 55 for displaying image 41, VRAM 56, input device 57, compression / decompression unit 58 for decompressing data in JPEG format and compressing the data in JPEG format, and the whole. MPU59.
[0114]
The personal terminal device 153 is installed, for example, in an individual user's house, and is connected to the Internet 154 via a modulator / demodulator and a telephone line, a terminal adapter, an ISDN (Integrated Services Digital Network) line, a CATV (Cable Television) line, and the like. Connected to the provider in For example, when browsing a home page established on the server device 152, if the user operates the input device 57 to input a URL (Uniform Resource Locator) of a desired home page, the browser 112, TCP / IP protocol ( As a result, the personal terminal device 153 accesses the server device 152 via the Internet 154, downloads the accessed home page, and displays it on the display 55. Also, the user can use this personal terminal device 153 to send an e-mail to the personal terminal device 153 of another user via the Internet 154.
[0115]
Further, in this personal terminal device 153, as shown in FIG. 29, shutter glasses 4 for viewing an image displayed on the display 55 in three dimensions are provided between the VRAM 56 and the display 55. Connected through. Therefore, the user can see the image having parallax displayed on the homepage in three dimensions by putting on the shutter glasses 4.
[0116]
A case where a user browses a homepage established in the server device 152 by the personal terminal device 153 in the network system 151 as described above will be described. In the server device 152, stereoscopic image data is stored as an image having parallax, for example, by a method shown in FIG. As shown in FIG. 19, the stereoscopic image data is composed of right-eye cut-out image data with even-numbered lines thinned out and left-eye cut-out image data with odd-numbered lines thinned out. A composite image data file 102 in which the composite image data is recorded is stored. Since the composite image data file 102 has a small data size, the time for downloading the composite image data file 102 from the server device 152 can be shortened.
[0117]
On the other hand, in the personal terminal device 153, when browsing a home page as shown in FIG. 20 and FIG. 21 in step S61 shown in FIG. 30, first, an icon for starting a browser displayed on the display 55 is used as a mouse. When clicked at 57 b, the MPU 59 reads the browser program from the HDD 51 into the RAM 52, and displays the startup screen 111 shown in FIG. 21 on the screen 82 of the display 55. Here, as shown in FIG. 24A, the VRAM 56 supplies a video signal of a white → black → white → black pattern for displaying the activation screen 111 to the display 55. The detection unit 61 of the glasses control device 6 detects a video signal of a white → black → white → black pattern and detects that the browser 112 is activated. When the startup of the browser 112 is completed, the right-eye image data and the left-eye image data of the browser 112 are alternately output from the VRAM 56, and the right-eye image and the left-eye image are alternately displayed on the display 55. Displayed with parallax.
[0118]
Simultaneously with the start of the browser 112, when the right eye image of the browser 112 is displayed in step S <b> 62, the glasses control device 6 sets the right eye lens 4 a of the shutter glasses 4 in a see-through state, and the left eye When the left-eye image of the browser 112 is displayed, the left-eye lens 4b of the shutter glasses 4 is made transparent, and the right-eye lens unit 4a The shutter glasses 4 are controlled so as to be in a light shielding state and to repeat this. As described above, by switching the shutters of the right-eye lens unit 4a and the left-eye lens unit 4b of the shutter glasses 4 in accordance with the switching timing of the right-eye image and the left-eye image of the browser 112, the usage can be performed. The person can view the image of the browser 112 displayed on the display 55 in three dimensions.
[0119]
In step S63, when the user operates the input device 57 to input the URL of a desired home page, the personal terminal device 153 accesses the server device 152 via the Internet 154 to access the accessed home page. Is downloaded and displayed on the display 55. It is also possible to select and download a 3D image posted on the homepage. For the selected image, stereoscopic image data is accumulated in the storage unit 161 of the server device 152 by the method shown in FIG. The image data shown in FIG. 17 includes a right-eye image data file 92, a left-eye image data file 93, and an information file 94 including information related to the files 92 and 93. Since this image data includes a right-eye image data file 92 and a left-eye image data file 93, an editing program for enlarging or reducing the right-eye image and the left-eye image on the personal terminal device 153 Can be done by.
[0120]
In the network system 151 as described above, stereoscopic image data is stored in the server device 152 by the method shown in FIGS. 17 and 19, and the user wears the shutter glasses 4 on the personal terminal device 153 side and displays it on the display 55. By viewing the displayed home page, the image displayed on the display 55 can be viewed three-dimensionally. For example, when a user purchases a product via the Internet 154, the user can view the product in three dimensions and can easily determine whether or not to purchase the product.
[0121]
The network system 151 can also exchange electronic mail between the personal terminal devices 153. For example, the image data obtained by attaching the adapter 5 to the digital camera 2 and performing the editing process described above is attached to an e-mail and transmitted to another personal terminal device 153. Here, a case where image data is stored in the HDD 51 of the personal terminal device 153 on the transmission side by the method shown in FIG. 17 will be described. In this case, as described above, the cut-out image data file 92 for the right eye, the cut-out image data file 93 for the left eye, and the information file 94 including information related to the files 92 and 93 are stored in the folder 91. Has been.
[0122]
In the personal terminal device 153 on the transmission side, the user operates the input device 57 to transmit the folder 91 to the address of the server device 152 that is the transmission destination. As a result, the transmitted folder 91 is accumulated in the storage unit 161 of the server device 152. Thereafter, when the personal terminal device 153 of the user who is the recipient accesses the address of the server device 152, the personal terminal device 153 of the recipient downloads the folder 91 and stores it in the HDD 51.
[0123]
In the personal terminal device 153 on the receiver side, when viewing an image stored in the folder 91, the browser 112 is activated by the procedure shown in FIG. Then, the user who is the receiver opens the received file 91 and the VRAM 56 alternately displays the right-eye cut image data file 92 and the left-eye cut image data file 93 on the display 55 so as to have parallax. As a result, the image displayed on the browser 112 with the shutter glasses 4 on can be viewed three-dimensionally. By the way, since the right-eye cut image data file 92 and the left-eye cut image data file 93 are stored in the folder 91, the user again selects the right-eye cut image 78a and the left-eye cut image 78b. Re-editing such as enlargement or reduction can be performed.
[0124]
Next, a case where image data is stored in the HDD 51 by the method shown in FIG. 18 will be described. In this case, as described above, in the folder 96, the image data file 97 composed of the image data composed of the right eye image 41a and the left eye image 41b shown in FIG. An information file 98 composed of information for generating the image 78a for the right eye and the image 78b for the right eye is stored.
[0125]
The personal terminal device 153 on the transmission side is transmitted to the folder 96 via the server device 152 by the user operating the input device 57 to the personal terminal device 153 of the user serving as the receiver.
[0126]
In the personal terminal device 153 on the receiver side, when viewing an image stored in the folder 96, the browser 112 is activated according to the procedure shown in FIG. Then, the user who is the receiver opens the received file 96 and the VRAM 56 alternately displays the right-eye cut image data file 92 and the left-eye cut image data file 93 on the display 55 so as to have parallax. As a result, the image displayed on the browser 112 with the shutter glasses 4 on can be viewed three-dimensionally. By the way, since there is an image data file 97 in this folder 91, the user again performs an editing operation as shown in FIG. 10, that is, an editing operation such as cutting of the right eye image and the left eye image. be able to.
[0127]
In the network system 151 as described above, since each personal terminal device 153 has at least the browser 112, it is possible to attach a stereoscopic image to an e-mail and exchange stereoscopic image data.
[0128]
The example in which image data is compressed and stored in the JPEG format has been described above, but the present invention may be a compression method such as MPEG (motion picture expert group). In addition, although an example of a still image has been described above, a moving image may be used.
[0129]
【The invention's effect】
According to the stereoscopic image data generation device and the stereoscopic image data generation method according to the present invention, the right-eye image With tear line The right eye image data file formed by cutting and the left eye image file With tear line Cross-point coordinate information for displaying the left-eye image data file, the right-eye image data, and the left-eye image data that are cut and formed so as to have parallax on the display unit. Record Thus, the user can perform re-editing such as enlarging or reducing the right-eye image data and the left-eye image data again.
[0130]
In addition, according to the stereoscopic image data generation device and the stereoscopic image data generation method according to the present invention, one image data file in which the right-eye image and the left-eye image are arranged across the boundary input from the input unit. And from one image data file Instruction means In Instructions Cross point coordinate information for displaying the right eye image and the left eye image cut according to the cut information indicating the positions of the one cut line and the other cut lines and the image for the left eye with parallax on the display unit. Record Therefore, the user can perform editing operations such as image cutting.
[0131]
Furthermore, according to the stereoscopic image data generation device and the stereoscopic image data generation method according to the present invention, With tear line The right eye image data file formed by cutting and the left eye image file With tear line Cross-point coordinate information for displaying the left-eye image data file, the right-eye image data, and the left-eye image data that are cut and formed so as to have parallax on the display unit. Record The stereoscopic image can be read using the information file thus obtained, and the horizontal scanning line data of the right-eye image data and the horizontal scanning line data of the left-eye image data are alternately stored. The three-dimensional image can be read using the synthesized image data file. When reading is performed using the right-eye image data file, the left-eye image data file, the right-eye image data, and the information file, editing operations such as image cutting can be performed.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an overall configuration of a stereoscopic image display system.
FIG. 2 is a block diagram illustrating a configuration of a digital camera.
FIG. 3 is a perspective view of an adapter attached to a lens barrel of a digital camera.
FIG. 4 is a diagram illustrating the configuration of the adapter.
FIG. 5 is a diagram illustrating an image captured by a CCD element when an adapter is attached to a digital camera.
FIG. 6 is a block diagram of a control device that edits and displays image data composed of a right-eye image and a left-eye image captured by a digital camera.
FIG. 7 is a block diagram of an eyeglass control device that controls shutter eyeglasses.
FIG. 8 is a diagram for explaining the switching timing of the right eye lens unit and the left eye lens unit of the shutter glasses in the progressive method.
FIG. 9 is a diagram for explaining the switching timing of the right eye lens unit and the left eye lens unit of the shutter glasses in the interlace method.
FIG. 10 is a diagram illustrating image data editing processing.
FIG. 11 is a diagram illustrating an editing screen.
FIG. 12 is a diagram illustrating a preview mode.
FIG. 13 is a diagram illustrating an image display mode in a preview mode.
FIG. 14 is a diagram illustrating a display screen in a play view mode.
FIG. 15 is a diagram illustrating a method of displaying a pointer and characters on the display screen in the play view mode.
FIG. 16 is a diagram illustrating a method of displaying a three-dimensional frame around an image.
FIG. 17 is a diagram illustrating a storage format of image data.
FIG. 18 is a diagram illustrating another example of a storage format of image data.
FIG. 19 is a diagram illustrating still another example of the image data storage format.
FIG. 20 is a diagram illustrating a startup procedure of a browser.
FIG. 21 is a diagram illustrating a browser startup screen.
FIG. 22 is a diagram illustrating a state in which an image is displayed on the browser.
FIG. 23 is a diagram illustrating a procedure for closing a browser.
FIG. 24 is a diagram illustrating signals at the time of a browser start screen and an end screen.
FIG. 25 is a diagram illustrating a state in which an image displayed on a browser is moved.
FIG. 26 is a diagram illustrating a procedure for moving an image displayed on a browser.
FIG. 27 is a diagram illustrating a state in which an image displayed on a browser is enlarged or reduced.
FIG. 28 is a diagram illustrating a procedure for enlarging or reducing an image displayed on a browser.
FIG. 29 is a diagram illustrating a network system using a stereoscopic image system.
FIG. 30 is a diagram illustrating a procedure for viewing a home page.
[Explanation of symbols]
1 stereoscopic image system, 2 digital camera, 3 control device, 4 shutter glasses, 5 adapter, 6 eyeglass control device

Claims (12)

The right-eye image and the left-eye image generated by capturing the right-eye image in approximately the right half of one image sensor and generating the left-eye image in approximately the left half, with the boundary portion interposed therebetween. An input unit for inputting one image data file in which
A display unit that displays one image data file in which a right-eye image and a left-eye image are arranged across a boundary input from the input unit;
The dividing line is instructed to the boundary part of one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary part input from the input part, and the above-mentioned display displayed on the display part An instruction means for instructing a predetermined region of one of the right-eye image and the left-eye image with one cut line that forms a substantially rectangular shape ;
Position input means for operating the indicated position of the indicating means;
The right eye image or the left eye image corresponding to the area instructed by the instructing means is controlled so as to display the other image area with another cut line having a substantially rectangular shape. and file of the right-eye image data formed by cutting in the above cutting line of the image, and the file of the image data for the left eye formed by cutting in the above cutting line of the left-eye image, the image data and the for the right eye a left-eye image data and a control unit for controlling to store the folder information file and the recording medium in which the coordinate information of the cross point is recorded for displaying to have parallax on the display unit ,
The control device, when the instruction means that instructs the image for the right eye displayed on the display unit, a predetermined region of one of the images of the left eye image at tear line the one, and the division line The interval between the cut line of one of the one image and the line on the dividing line side is equal to the interval between the side edge opposite to the divided line of the other image and the line on the side edge of the other cut line. And a stereoscopic image data generation device that controls to display the other cut line. The instruction means is displayed on the display section, the right-eye image of the cutoff line in cut and formed right-eye image and the left eye image of the image for the left eye formed by cutting in the cutting line You can adjust the cross point by moving horizontally with
The stereoscopic image data generation device according to claim 1, wherein when the cross point is adjusted, the control device records the coordinate of the cross point after the adjustment in the information file. The right-eye image and the left-eye image generated by capturing the right-eye image in approximately the right half of one image sensor and generating the left-eye image in approximately the left half, with the boundary portion interposed therebetween. A step of inputting one image data file in which are arranged in the input unit;
Displaying one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary input from the input unit on the display unit;
An instruction means for instructing a dividing line to the boundary portion of one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary portion input from the input portion;
The instruction means instructing a predetermined region of one of the image for the right eye and the image for the left eye displayed on the display unit with one cut line having a substantially rectangular shape ;
Controlling to display the area of the other image of the right-eye image and the left-eye image corresponding to the area instructed by the instructing means with another cutting line having a substantially rectangular shape;
And file of the right-eye image data formed by cutting in the above cutting line of the right-eye image, and the file of the image data for the left eye formed by cutting in the above cutting line of the left-eye image, for the right eye controlling the image data and the left-eye image data to be stored in the folder information file and the recording medium in which the coordinate information of the cross point is recorded for displaying to have parallax on the display unit And
Said indicating means for image the right eye displayed on the display unit, when a predetermined region of one of the images of the left eye image are indicated on the cutting line of the one of the division line and said one of the images The other cut line is equal to the line on the side opposite to the divided line of the other image and the line on the side edge side of the other cut line is equal to the line on the side of the other cut line. A stereoscopic image data generation method for controlling to display a cut line. Displayed on the display unit, and an image for the left eye formed by cutting in the above cutting line of the right-eye image for the right eye are formed by cutting in the above cutting line of the image and the left eye image horizontally You can move and adjust the above crosspoint,
4. The method for generating stereoscopic image data according to claim 3, wherein when the cross point is adjusted, the coordinates of the adjusted cross point are recorded in the information file. The right-eye image and the left-eye image generated by capturing the right-eye image in approximately the right half of one image sensor and generating the left-eye image in approximately the left half, with the boundary portion interposed therebetween. An input unit for inputting one image data file in which
A display unit that displays one image data file in which a right-eye image and a left-eye image are arranged across a boundary input from the input unit;
The dividing line is instructed to the boundary part of one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary part input from the input part, and the above-mentioned display displayed on the display part An instruction means for instructing a predetermined region of one of the right-eye image and the left-eye image with one cut line that forms a substantially rectangular shape ;
Position input means for operating the indicated position of the indicating means;
Control is performed so that the area of the other image of the right-eye image or the left-eye image corresponding to the area instructed by the instructing means is displayed with another cut line having a substantially rectangular shape, from the input unit One image data file in which the image for the right eye and the image for the left eye are arranged across the input boundary, and the one cut line and the other cut line designated by the instruction means from the one image data file Information in which cross-point coordinate information for displaying the right-eye image and the left-eye image clipped according to the cut-out information so as to have parallax on the display unit is recorded. And a control device for controlling the file to be stored in a folder of the recording medium,
The control device, when the instruction means that instructs the image for the right eye displayed on the display unit, a predetermined region of one of the images of the left eye image at tear line the one, and the division line The interval between the cut line of one of the one image and the line on the dividing line side is equal to the interval between the side edge opposite to the divided line of the other image and the line on the side edge of the other cut line. And a stereoscopic image data generation device that controls to display the other cut line. The instruction means is displayed on the display section, the right-eye image of the cutoff line in cut and formed right-eye image and the left eye image of the image for the left eye formed by cutting in the cutting line You can adjust the cross point by moving horizontally with
6. The stereoscopic image data generation device according to claim 5, wherein when the cross point is adjusted, the control device records the coordinate of the cross point after the adjustment in the information file. The right-eye image and the left-eye image generated by capturing the right-eye image in approximately the right half of one image sensor and generating the left-eye image in approximately the left half, with the boundary portion interposed therebetween. A step of inputting one image data file in which are arranged in the input unit;
Displaying one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary input from the input unit on the display unit;
An instruction means for instructing a dividing line to the boundary portion of one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary portion input from the input portion;
The instruction means instructing a predetermined region of one of the image for the right eye and the image for the left eye displayed on the display unit with one cut line having a substantially rectangular shape ;
Controlling to display the area of the other image of the right-eye image and the left-eye image corresponding to the area instructed by the instructing means with another cutting line having a substantially rectangular shape;
One image data file in which the image for the right eye and the image for the left eye are arranged across the boundary input from the input unit , and the one cut line instructed by the instruction means from the one image data file, Cross-point coordinate information for displaying the cut-out information indicating the position of the other cut-out line and the right-eye image and the left-eye image cut in accordance with the cut-out information with parallax on the display unit. and a step of controlling so as to store the recorded information file in the folder of the recording medium,
Said indicating means for image the right eye displayed on the display unit, when a predetermined region of one of the images of the left eye image are indicated on the cutting line of the one of the division line and said one of the images The other cut line is equal to the line on the side opposite to the divided line of the other image and the line on the side edge side of the other cut line is equal to the line on the side of the other cut line. A stereoscopic image data generation method for controlling to display a cut line. Displayed on the display unit, and an image for the left eye formed by cutting in the above cutting line of the right-eye image for the right eye are formed by cutting in the above cutting line of the image and the left eye image horizontally You can move and adjust the above crosspoint,
The stereoscopic image data generation method according to claim 7, wherein when the cross point is adjusted, the coordinates of the adjusted cross point are recorded in the information file. The right-eye image and the left-eye image generated by capturing the right-eye image in approximately the right half of one image sensor and generating the left-eye image in approximately the left half, with the boundary portion interposed therebetween. An input unit for inputting one image data file in which
A display unit that displays one image data file in which a right-eye image and a left-eye image are arranged across a boundary input from the input unit;
The dividing line is instructed to the boundary part of one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary part input from the input part, and the above-mentioned display displayed on the display part An instruction means for instructing a predetermined region of one of the right-eye image and the left-eye image with one cut line that forms a substantially rectangular shape ;
Position input means for operating the indicated position of the indicating means;
The right eye image or the left eye image corresponding to the area instructed by the instructing means is controlled so as to display the other image area with another cut line having a substantially rectangular shape. and file of the right-eye image data formed by cutting in the above cutting line of the image, and the file of the image data for the left eye formed by cutting in the above cutting line of the left-eye image, the image data and the for the right eye and information file coordinate information of the cross point for displaying the left-eye image data so as to have a parallax on the display unit is recorded, data and the left eye of the horizontal scanning lines of the image data for the right eye A control device for controlling to store a composite image data file in which horizontal scanning line data of image data is alternately stored in a folder of a recording medium,
The control device, when the instruction means that instructs the image for the right eye displayed on the display unit, a predetermined region of one of the images of the left eye image at tear line the one, and the division line The interval between the cut line of one of the one image and the line on the dividing line side is equal to the interval between the side edge opposite to the divided line of the other image and the line on the side edge of the other cut line. And a stereoscopic image data generation device that controls to display the other cut line. The instruction means is displayed on the display section, the right-eye image of the cutoff line in cut and formed right-eye image and the left eye image of the image for the left eye formed by cutting in the cutting line You can adjust the cross point by moving horizontally with
The stereoscopic image data generation device according to claim 9, wherein when the cross point is adjusted, the control device records the coordinate of the adjusted cross point in the information file. The right-eye image and the left-eye image generated by capturing the right-eye image in approximately the right half of one image sensor and generating the left-eye image in approximately the left half, with the boundary portion interposed therebetween. A step of inputting one image data file in which are arranged in the input unit;
Displaying one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary input from the input unit on the display unit;
An instruction means for instructing a dividing line to the boundary portion of one image data file in which the image for the right eye and the image for the left eye are arranged across the boundary portion input from the input portion;
The instruction means instructing a predetermined region of one of the image for the right eye and the image for the left eye displayed on the display unit with one cut line having a substantially rectangular shape ;
Controlling to display the area of the other image of the right-eye image and the left-eye image corresponding to the area instructed by the instructing means with another cutting line having a substantially rectangular shape;
And file of the right-eye image data formed by cutting in the above cutting line of the right-eye image, and the file of the image data for the left eye formed by cutting in the above cutting line of the left-eye image, for the right eye An information file in which coordinate information of cross points for displaying the image data and the image data for the left eye on the display unit so as to have a parallax is recorded ; Controlling to store a composite image data file in which horizontal scanning line data of the left-eye image data is alternately stored in a folder of a recording medium,
Said indicating means for image the right eye displayed on the display unit, when a predetermined region of one of the images of the left eye image are indicated on the cutting line of the one of the division line and said one of the images The other cut line is equal to the line on the side opposite to the divided line of the other image and the line on the side edge side of the other cut line is equal to the line on the side of the other cut line. A stereoscopic image data generation method for controlling to display a cut line. Displayed on the display unit, and an image for the left eye formed by cutting in the above cutting line of the right-eye image for the right eye are formed by cutting in the above cutting line of the image and the left eye image horizontally You can move and adjust the above crosspoint,
12. The method for generating stereoscopic image data according to claim 11, wherein when the cross point is adjusted, the coordinates of the adjusted cross point are recorded in the information file.

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