JP2010147787A - Camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a camera with which a user attaches fringes according to tastes for individual photographs. <P>SOLUTION: The camera includes: a print size input means (21) for inputting arbitrary print size; a fringe width input means (22) for inputting fringe width to be formed around a photographed image at a print complete state; and an image size adjustment means (16) for adjusting the size of the photographed image so that the photographed image may be settled in a second area to be manually formed by cutting the fringe width input by the fringe width input means (22) from four sides in each direction from a first area to be specified by the print size input by the print size input means (21). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a camera.

When printing a photo, a white border may be added around the image. 2. Description of the Related Art Conventionally, there is a printing apparatus that allows the width of the white edge to be manually input and forms the white edge of that width for all photographs to be printed (for example, see Patent Document 1).
Japanese Patent Laid-Open No. 2004-29923

  However, the above-described prior art is to uniformly determine the edge of the same width for all prints in the printing apparatus, and does not necessarily have a white edge as desired by the user.

  An object of the present invention is to enable a user to add an edge according to his / her preference for individual photographs.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this.
According to the first aspect of the present invention, there is provided a print size input means (21) capable of inputting an arbitrary print size, and an edge width input means (22) capable of inputting an edge width formed around the photographed image in a print completed state. In a second area formed by cutting the edge width input by the edge width input means (22) from four sides in the vertical and horizontal directions from the first area defined by the input print size. The camera (10) further comprises image size adjusting means (16) for adjusting the size of the photographed image so that the photographed image can be accommodated.
The invention according to claim 2 is the camera (10) according to claim 1, wherein the captured image is different in aspect ratio from the second region, and is vertically or horizontally compared to the second region. When either one of the images has a long width, the other width of the second region in the captured image is made equal to the width of the other of the second region, and the one end of the captured image And the aspect ratio of the photographed image is made to match the aspect ratio of the second region, and an edge having a constant width is generated on the entire circumference, or the one width of the photographed image is made the second width A selection means that can match the width of one of the regions, form an edge larger than the edge width input by the print (21) on the other side, and maintain the aspect ratio of the photographed image; A camera (10) characterized by comprising.
According to a third aspect of the present invention, in the camera (10) according to the second aspect, in the case where an edge having a constant width is generated on the entire circumference, the end on the one side of the photographed image is evenly distributed from both sides. The camera (10) is characterized by being cut into two pieces.
The invention according to claim 4 is the camera (10) according to claim 2, wherein the print size input means (21) formed on the other side when the aspect ratio of the captured image is maintained. The camera (10) is characterized in that an edge larger than the edge width input by the step (1) is formed on one side of the other side.
A fifth aspect of the present invention is the camera (10) according to any one of the first to fourth aspects, wherein an edge is formed around the captured image adjusted by the image size adjusting means (16). A storage unit (17) that stores the formed adjustment image; and an image processing unit (15) that performs image processing on the adjustment image. The camera (10) is characterized in that image processing is performed on a portion excluding the edge portion.

  Note that the configuration described with reference numerals may be modified as appropriate, and at least a part of the configuration may be replaced with another component.

  ADVANTAGE OF THE INVENTION According to this invention, the camera which can form an edge as a user's liking can be provided.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an external perspective view of an electronic camera 10 to which an embodiment of the present invention is applied as viewed from the back. FIG. 2 is a block diagram of the electronic camera 10. As shown in FIGS. 1 and 2, the electronic camera 10 includes an imaging unit 11, an operation unit 12, a display unit 13, a control unit 14, an image processing unit 15, an edge image generation unit 16, and an image. And a recording unit 17.

  The imaging unit 11 includes an imaging optical system and an imaging element such as a lens and a diaphragm (not shown). The imaging unit 11 converts a subject image formed on the imaging element through the lens into an electrical signal (imaging data) and outputs the electrical signal to the image processing unit.

  The operation unit 12 includes a power button and a release button (not shown), a cross key 12A, and a plurality of operation buttons 12B. The operation unit 12 can be operated by the user and outputs the operation information to the control unit 14. Various functions can be set by operating the operation screen displayed on the liquid crystal panel 13A of the display unit 13 with the cross key 12A or the like. A plurality of operation screens are prepared corresponding to a plurality of functions, and the operation screen is switched from the menu screen for operation. Thereby, many function settings are possible by the limited number of operation buttons 12B.

  The display unit 13 includes a liquid crystal panel 13 </ b> A provided on the back surface of the electronic camera 10. The display unit 13 is controlled by the control unit 14 described later, and is measured by the setting information related to photographing input by the user via the operation unit, such as shutter speed, aperture, and exposure correction information, or by the imaging unit 11. Photometric information is displayed on the liquid crystal panel 13A. Further, the photographed image, its histogram, photographing information and the like are displayed on the liquid crystal panel 13A. Furthermore, an operation screen that defines the function of the operation unit 12 is displayed on the liquid crystal panel 13A.

  The control unit 14 is configured by a microcomputer or the like. Then, based on operation information such as pressing of a shutter button and setting information input from the operation unit 12, each unit of the electronic camera 10 is integratedly controlled. Further, the control unit 14 controls the display unit 13 to display various information, captured images, and the like on the liquid crystal panel 13A. The control unit 14 stores a program for executing these processes in advance.

  The image processing unit 15 generates image information by performing various types of digital signal processing such as color signal generation, matrix conversion processing, γ conversion processing, and correction processing on the imaging data input from the imaging unit 11.

  The border image generation unit 16 displays a white border automatic generation screen on the display unit 13 when generating a border image. As will be described later, the border image generation unit 16 can set the print size and the border width. And the image size adjustment means 26 which adjusts the size of a picked-up image based on the setting information, and the selection means 25 of the edge generation form mentioned later are included. The edge image generation unit 16 will be described in detail later.

  The image recording unit 17 is configured by a detachable removable memory or the like. Then, the photographed image (original image) processed by the image processing unit 15 and the framed image formed by the framed image generation unit 16 are recorded. In the following description, an original captured image generated by the image processing unit 15 is referred to as an “original image”, and an image in which an edge is generated from the original image by the edge image generation unit 16 is referred to as an “edge image”.

  The electronic camera 10 having the above configuration operates as follows. When the operation unit 12 (release button) is operated by the user (photographer) at the time of shooting, the imaging unit 11 captures a subject image. The subject image captured by the imaging unit 11 is converted into an electrical signal and output to the image processing unit 15. Image data (original image) is formed from the electric signal in the image processing unit 15 and recorded in the image recording unit 17. The display unit 13 causes the liquid crystal panel 13A to display an operation screen that defines various setting information, shooting information, captured images, and functions of the operation unit 12. The electronic camera 10 causes the display unit 13 to display a white edge automatic generation screen, which is one of the operation screens, when the edge image generation unit 16 described later generates the edge image. Setting input of processing information to the marginal image generation unit 16 is performed by operating the operation unit 12.

  Next, the bordered image generation unit 16 will be described in detail. The rimmed image generation unit 16 is a part that processes the original image generated by the image processing unit 15 and generates a rimmed image corresponding to the print size and having a rim around it. FIG. 3 is a diagram showing an operation screen (white border automatic generation screen 20) for setting a bordered image displayed on the liquid crystal panel 13A of the display unit 13. As shown in FIG. 4-7 is a figure explaining the concept of the border image generation by the border image generation part 16. FIG. FIG. 8 shows a processing flow of the framed image generation unit 16.

  Note that when an edge image is printed, the outermost peripheral portion (that is, the edge portion) is slightly cut at a cut rate described later in detail, and the edge width on the final print is slightly smaller than the edge width in the edge image. Becomes narrower. In the following description, the edge portion generated in the edge image is referred to as an “enlarged edge portion” and is distinguished from the “edge” on the final print. The present embodiment is an example in which a white so-called “white edge” is formed around an image. However, the border is not limited to white, and an edge of an arbitrary color or pattern may be formed.

  A print size (size of print paper), a border width, a cut rate, and a border generation form are input to the bordered image generation unit 16 as processing information. The edge generation form is selected from two types (detailed later).

  The processing information is input from the white edge automatic generation screen 20 shown in FIG. 3, which is one of the operation screens displayed on the liquid crystal panel 13 </ b> A of the display unit 13. This white edge automatic generation screen 20 selects and displays white edge automatic generation from the image editing menu screen displayed on the liquid crystal panel 13A of the display unit 13.

  As shown in FIG. 3, the white edge automatic generation screen 20 includes a print size setting dialog box 21, an edge width setting dialog box 22, a print size display box 23, and a cut rate input box 24. In addition, an edge generation form selection check box 25 (25A, 25B) is provided. Furthermore, an execution button 26 for instructing the start of processing and a cancel button 27 for cancellation are provided.

  In the print size setting dialog box 21 of the white edge automatic generation screen 20, a drop-down list of predetermined paper sizes (for example, L size, 2L size, postcard size, etc.) is prepared. It can be selected and set. In conjunction with the print size setting in the print size setting dialog box 21, numerical values (mm) of vertical and horizontal dimensions stored in advance are automatically input to the print size display box 23. . However, even if they are referred to as the same 2L print, these dimensions may differ slightly depending on the lab, so that the user can input a numerical value into the print size display box 23 by himself / herself. In this case, this new numerical value is set as the stored value, and when 2L is selected next time, the numerical value is automatically input. The edge width setting dialog box 22 has a drop-down list in units of 1 mm, for example, which can be selected and set from the list.

  In the cut rate input box 24, a numerical value of the cut rate (%) is manually input. Here, the cut rate represents the ratio of the length of the printed image to the original image (note: not the area ratio) in% when the photographed image (original image) is printed by a laboratory print service or the like. This is an index indicating how much area of the original image is actually printed.

  That is, in the laboratory print service, the entire original image is not printed as it is, but the periphery of the original image is slightly cut and printed. This is because even if a deviation occurs due to a mechanical error or the like of the output device, a margin is provided so that an image is surely formed on the entire surface of the print paper. For example, in the L size or 2L size, even when the aspect ratio of the original image is the same as that of the print paper, about 98% of the vertical and horizontal dimensions of the original image (photographed image) are printed in both the vertical and horizontal directions, and the outside is cut. (In other words, the cut rate is about 98%). Therefore, in order to form an edge having a desired constant width around the image, it is necessary to generate an edged image in which an enlarged edge portion is formed in consideration of the cut rate. Otherwise, the edge width on the final print will be narrower than desired.

The edge generation form selection check box 25 includes two types of check boxes 25A and 25B, and either one of them is alternatively selected. These two types of edge generation forms are the following forms.
A (check box 25A): Both the upper and lower sides or the left and right sides of the original image are equally cut so as to match the aspect ratio of the print paper, and an edge surrounding the periphery of the image is formed with a set constant width. A bordered image is generated. Hereinafter, this is referred to as “constant width edge generation”. In the white edge automatic generation screen shown in FIG. 3, “Adjust to printer aspect ratio” is displayed.
B (check box 25B): A bordered image for forming a border around the image while maintaining the aspect ratio is formed without cutting the original image. In this form, the edge width of at least one side of the print is wider than the set width. Hereinafter, this is referred to as “aspect ratio priority edge generation”. In the white edge automatic generation screen shown in FIG. 3, “Keep the aspect ratio of the original image” is displayed.

  In this way, the necessity to select one of the two types of edge generation forms is that the aspect ratio of the image captured by a general digital camera is usually 4: 3 or 3: 2, which is the aspect ratio of the print paper. This is due to the fact that these are not exactly the same. That is, because the aspect ratio of the original image and the printing paper is different, it is impossible to form a print having a fixed width on the four sides around the image without changing the original image.

  For this reason, as shown in FIG. 4, is a part of the original image 30 cut (cut area 31) to form a print 32 in which edges of a set width are generated on all four sides (constant width edge generation)? Or the print 33 in which the edge of the set width is generated only on the three sides of the original image without generating the edge of the set width on all four sides (the aspect ratio priority edge generation) is formed. Is to choose.

Next, the processing contents in the rimmed image generation unit 16 will be described by numerical examples with reference to FIG.
First, constant width edge generation will be described. Here, size: 2L print = 177 (mm) × 126 (mm), cut rate: 98%, white edge width: t = 3 (mm). The original image before processing is 2048 × 1536 (pixel) (aspect ratio 1.33). In addition, these numerical values are examples, and are not limited to these.

The rimmed image generation unit 16 first performs pre-calculation based on the input information. Refer to Fig. 5 for the dimensional relationships. In the figure, Wi × Hi is the size of the border image, Wp × Hp is the size of the printing paper, and Wo × Ho is the size of the image area excluding the border in printing.
The outline of the finished print (print paper)
Wp × Hp = 177 (mm) × 126 (mm)

On the other hand, in order to add 3 (mm) white border around the finished print,
Wo = Wp-2t = 177-2 × 3 = 171 (mm)
Ho = Hp-2t = 16-2−3 = 120 (mm)
Therefore, the image area obtained by subtracting the white margin from the printed outline is
Wo × Ho = 171 (mm) × 120 (mm).

The aspect ratio of the image area is
Wo ÷ Ho = 171 ÷ 120 = 1.425
It becomes.
Next, in order to obtain Wi and Hi, the cut rate is considered. Since the cut rate is 98%,
Wi = Wp ÷ 0.98 = 180.61 (mm)
Hi = Hp ÷ Hi = 128.57 (mm)

From the above, the following procedure is used to add a white edge of t = 3 (mm) in the completed print state.
First, the aspect ratio of the image is adjusted to 1.425.
Adding an enlarged edge
In the horizontal direction, the width of the image area width: Wo = 171 (mm) with the enlarged edge added is Wi = 180.61 (mm)
Therefore, it is only necessary to add the enlarged edges equally to the left and right so that Wi ÷ Wo = 1.056 times the image.

In the vertical direction, the width of the image area width: Ho = 120 (mm) with an enlarged edge is Hi = 128.57 (mm)
Therefore, it is only necessary to add an enlarged edge portion evenly in the vertical direction so that Hi ÷ Ho = 1.071 times the image.

Next, specific processing in units of (pixel) with respect to the original image in the generation of the constant width edge based on the numerical values calculated as described above will be described with reference to FIG.
As shown in FIG. 6, first, the aspect ratio is adjusted to generate an aspect ratio matching image (B).
That is, in order to match the original image (A) of 2048 × 1536 (pixel) (aspect ratio 1.33) with a horizontally long image region having an aspect ratio of 1.425 (the horizontal direction changes) The image is cut up and down to generate a 2048 × 1437 (pixel) aspect ratio matching image (B).

An enlarged edge Fi is added to the periphery of the aspect ratio matching image (B) to obtain a bordered image (C).
The addition of the enlarged edge Fi
The horizontal direction is
2048 × 1.056 = 2162 (pixel)
The enlarged edge portion Fi is added evenly on the left and right sides.
The vertical direction is
1437 × 1.071 = 1539 (pixel)
The enlarged edge portion Fi is added evenly so that

When a decimal fraction is found in this pixel number calculation, it is necessary to make it an integer. At that time, the calculation result is even if the number of pixels of the original image is even, and the calculation result is odd if the number of pixels of the original image is odd so that the top and bottom in the vertical direction and the left and right in the horizontal direction are equal. It is desirable to make fine adjustments.
In this way, the edge image (C) to which the enlarged edge portion Fi is added is printed in a 2L size in a laboratory, thereby obtaining a print in which a white edge having a desired width (3 mm) is formed around the periphery.

Next, the case of aspect ratio priority edge generation illustrated in FIG. 7 will be described. Each set value is the same as in the case of the constant width edge generation described above.
In the aspect ratio priority edge generation, the blank image Fb is added to the original image (A) to generate an intermediate image (B) having an aspect ratio equal to the previous Wo / Ho = 1.425, and the intermediate image (B) is generated. On the other hand, a white image for forming a white edge is further added to obtain an image with an aspect ratio priority edge (C).

That is, since the original image (A) is 2048 × 1536 (pixel) (aspect ratio 1.33),
1536 × 1.425 = 2189 (pixel)
A white margin image Fb is added to the right end of the screen to generate a 2189 × 1536 (pixel) intermediate image (B).

In addition to this intermediate image (B), the horizontal direction is 2189 × 1.056 = 2231 (pixels), and the vertical direction is 1536 × 1.071 = 1644 (pixels). An enlarged edge portion Fi is added evenly in the vertical direction, and the aspect ratio priority edged image (C) is generated.
As a result, an edge having a width obtained by adding the enlarged edge portion Fi to the blank image Fb is generated at the right end edge of the aspect ratio priority edged image (C).

  The rimmed image (C) to which the enlarged edge Fi is added in this way is printed in the lab by 2L, so that the entire original image (A) is entered without being cut, a margin is added to the right side, and the other 3 A print with a white edge having a desired width (3 (mm)) can be obtained. Here, a margin (margin image Fb) for absorbing the aspect ratio is generated at the right end. This is because the margin is cut off with a cutter to obtain a uniform white edge on all four sides, and it is easier to cut if the part to be cut off is on the right side. However, the present invention is not limited to this, and a margin may be generated on the left side, or a margin may be generated equally on the left and right.

FIG. 8 is a processing flow by the framed image generation unit 16 described above. According to this processing flow, the flow of processing at the time of the marginal image generation processing will be described.
First, when a user calls a menu on the operation screen on the liquid crystal panel 13A of the display unit 13 and selects automatic white edge generation from the image editing menu screen (S01), the automatic white edge generation screen 20 is displayed. .
The user inputs the print size from the dialog box 21 on the white edge automatic generation screen 20 and inputs the cut rate into the cut rate input box 24 (S02).

The rimmed image generation unit 16 determines whether or not the set numerical value is appropriate (S03), and urges correction if it is inappropriate. If it is inappropriate, a correction value is input by the user (S04).
Next, the edge width is input from the edge width setting dialog box 22 by the user (S05), and the edge generation form is selected from the edge generation form selection check box 25 (25A, 25B) (S06). The button 26 is clicked (S07).
In response to this, the edge image generation unit 16 determines whether the selection of the edge generation form is constant width edge generation or aspect ratio priority generation (S08).

If “Fit to printer aspect ratio”, which is constant-width edge generation, is selected in step (S08), the aspect ratio of the image area obtained by subtracting the white margin from the aspect ratio of the original image and the print outline. It is determined whether the ratios are equal (S09).
If the result of determination in step (S09) is equal, a white portion is added around the image (S13). If they are not equal, the original image is equally cut so that the top and bottom or the left and right are equal (S10), and an enlarged edge is generated around the image (S13).

On the other hand, when “match to printer aspect ratio” is not selected in the determination of step (S08) (that is, “maintain the aspect ratio of the original image” which is the aspect ratio priority edge generation is selected). In step S11, it is determined whether the aspect ratio of the original image is equal to the aspect ratio of the image area obtained by subtracting the white margin from the print outline.
If the result of determination in step (S11) is equal, an enlarged edge is added around the image (S13). If they are not equal, an intermediate image is generated by adding a margin above or to the right of the original image so as to be equal (S12), and an enlarged edge is additionally generated around the intermediate image (S13).

  Here, the marginal image generated by the marginal image generation unit 16 as described above is recorded in the image recording unit 17 with a name different from the original image under the control of the control unit 14. At that time, the control unit 14 sets a flag indicating that the white edge automatic generation processing has been performed on the border image, and further, (pixel) at four corners of the image (inner corner of the added enlarged edge portion). The coordinates are memorized at the same time. As a result, it is possible to prevent a problem that occurs at the enlarged edge portion by performing image processing after performing the white edge automatic generation processing.

  That is, when processing such as level correction, brightness / contrast adjustment, and color correction is performed on a bordered image that has been subjected to automatic white border generation processing, the enlarged edges generated in the surrounding area affect the processing. There is a possibility that the level correction is not appropriate, or conversely, the enlarged edge is affected to cause a color cast. For this reason, the image processing after the white edge automatic generation processing is limited to be performed only on the image portion. That is, when image processing is performed by the image processing unit 15, it is possible to identify that the image has been subjected to automatic white edge generation processing, and to perform image processing only on the image portion excluding the enlarged edge portion. It is something that can be done.

FIG. 9 shows a processing flow of level correction as an example of image processing in the image processing unit 15 for a bordered image that has been subjected to automatic white border generation processing. According to this processing flow, the user operation and the flow of processing during level correction will be described.
First, the user displays an image editing menu screen for performing image processing on the display unit 13, and selects level correction therefrom (S21).

The image processing unit 15 determines the white edge automatic generation history of the image based on the flag (S22). If it is determined that there is no white edge automatic generation history, the entire image is selected.
If there is a white edge automatic generation history in step (S22), only the image part inside the enlarged edge part set with coordinates is selected (S23).
Thereafter, the user performs each level correction setting (S24) and instructs execution (S25).
The image processing unit 15 performs level correction based on the setting (S26). After the level correction is completed, the selection of the image portion when there is a white edge automatic generation history is canceled (S27).

As described above, this embodiment has the following effects.
(1) It is possible to generate a bordered image that can create a print with an edge having a desired width by printing as it is without requiring troublesome calculations and operations.
(2) Since the automatic white edge generator is mounted on an electronic camera and performed as one of the in-camera image processing, the desired width can be obtained simply by requesting a laboratory without image processing by a personal computer or the like. A print with white edges can be obtained.
(3) Use the entire print size by appropriately cutting the top and bottom or left and right of the original image to match the aspect ratio of the image with the print, or add margins to the right or bottom without cutting the original image. Therefore, the original image can be printed in a desired form.
(4) Even if image processing such as level correction, brightness / contrast adjustment, and color correction is performed after automatic white edge generation, not only can this be performed properly, but the white edge remains white. The
(5) Ordinary lab borderless printing usually cuts the periphery of the original image slightly (the actual print is about 96-98%), but by adding a white border, the lab print In this case, the entire original image can be printed without being undesirably cut around the original image.

(Deformation)
The present invention is not limited to the above-described embodiment, and various modifications and changes as described below are possible, and these are also within the scope of the present invention.
(1) In this embodiment, in order to adjust the aspect ratio of the original image to the print aspect ratio, the upper and lower sides or a part of the left and right sides of the image are cut in the embodiment, but the center of the image including the main subject is included. The peripheral portion other than the portion may be enlarged or reduced while changing the magnification so that the aspect ratio of the original image matches the print aspect ratio.
(2) In the present embodiment, a white edge is formed around the image. However, the edge portion is not limited to white, but may have a desired color or pattern.
Note that the embodiment and the modification can be used in appropriate combination, but detailed description thereof is omitted. Further, the present invention is not limited to the embodiment described above.

1 is an external perspective view of an electronic camera to which an embodiment of the present invention is applied. It is a block block diagram of an electronic camera. It is a figure which shows the white edge automatic generation screen for a bordered image setting. It is a figure explaining the concept of two types of border image generation. It is a figure explaining the concept of bordered image generation. It is a conceptual explanatory drawing of the bordered image generation by equal width edge generation. It is a conceptual explanatory drawing of the bordered image generation by aspect ratio priority edge generation. It is a figure which shows the processing flow of a bordered image generation part. It is a figure which shows the processing flow of the level correction | amendment with respect to a border image.

Explanation of symbols

  10: Electronic camera, 12: Operation unit, 15: Image processing unit, 16: Bordered image generation unit, 17: Image recording unit, 21: Print size setting dialog box, 22: Border width setting dialog box, 23: Print size Display box, 25 (25A, 25B): Edge generation form selection check box

Claims (5)

A print size input means capable of inputting an arbitrary print size;
An edge width input means capable of inputting an edge width formed around the photographed image in a print completed state;
The photographed image is in a second area formed by cutting the edge width input by the edge width input means from four sides in the vertical and horizontal directions from the first area defined by the input print size. Image size adjusting means for adjusting the size of the photographed image so as to fit,
Comprising a camera. The camera according to claim 1,
When the captured image is different from the second region in aspect ratio, and the width of either the vertical or horizontal is longer than that of the second region,
In the photographed image, the other width, which is shorter in either length or width, is matched with the other width of the second region, the one end of the photographed image is cut, and the aspect ratio of the photographed image is Match the aspect ratio of the second region and generate a constant width edge around the circumference, or
The width of one of the photographed images is matched with the width of one of the second regions, and an edge larger than the edge width input by the print size input means is formed on the other side, and the aspect ratio of the photographed image Hold or
The camera further comprising a selection means capable of selecting the camera. The camera according to claim 2,
When generating an edge with a constant width on the entire circumference, the end of the one side of the captured image is cut evenly from both sides;
Camera characterized by. The camera according to claim 2,
When maintaining the aspect ratio of the photographed image, an edge larger than the edge width input by the print size input means formed on the other side is formed on one of the other side. camera. The camera according to any one of claims 1 to 4,
Storage means for storing an adjusted image in which an edge is formed around the captured image adjusted by the image size adjusting means;
Image processing means for performing image processing on the adjusted image,
A camera characterized in that when image processing is performed on the adjusted image, image processing is performed on a portion excluding the formed edge portion.

Images