JP2001524224A - Image transformation device for use in photographic technology - Google Patents

Abstract

(57) [Summary] Light deformation device for use in cameras. There are several embodiments of this device: a transparent plate (20) with a diffusion pattern, mounted on the film side, and a transparent plate mounted in a film cartridge, both in a conventional 35 mm film canister. A photographic film strip (16) of predetermined length to be wound and a patterned plastic film strip of similar length disposed adjacent thereto, between the main lens of the camera and the camera body (12). Transparent plate coupler to be placed.

Description

Description: Image transformation device for use in photographic technology Background of the Invention a) Field of the Invention The present invention relates generally to photographic image transformation devices, and more particularly to a photographic image transformation device for imparting a special effect, such as a pictorial effect, to a photographic negative during exposure. b) Description of Related Technology Techniques for providing special effects in the field of photographic technology have been very active in the past, and have continued to grow with increasing interest in photographic technology and the search for more interesting visual depictions. I have. In the past, for example, devices have been developed in which an image is changed before or during exposure to film. Such devices are typically mounted at the end of a camera lens where light directly interferes before reaching the film. The changes and effects to the incident light are different from the changes to overlay the "sub-image" by color filters on the same frame of the film that records the "true" image. For example, an opaque mat, pre-shaped, may be placed in front of a portion of the incident light to block the corresponding portion of the film, leaving an unexposed area on the film, which is subsequently separated. By "filling" with the image, one intended depiction or effect can be created. Still photography uses a similar diffusion mat to create a vignette-like contour by gradually reducing the exposure level of the film frame during exposure. Conventional devices have also been used to overlay a character image, such as a date or other alphabetic or numeric information, on a portion of an image on a film frame. Such a device is typically the device disclosed in U.S. Pat. No. 1,504,959 to Leschbrandt, such as a translucent plate having opaque characters placed on the film surface of a camera. Or a ribbon). The letter plate is aligned adjacent and in front of the film surface. The light on the selected plate is overlaid on a portion of the film using light from an external light source or light generated inside the camera. Ueda et al., U.S. Pat. No. 3,916,423, discloses an apparatus for transferring information (characters, lines, patterns) to a film surface while exposing the film to an image. A transparent plate with an opaque mask is attached to the film cartridge adjacent and in front of the film frame. During exposure, an opaque mask placed on the transparent plate blocks some of the light before the light from the image reaches the film and is exposed. As a result, an underexposed region corresponding to the specific shape of the opaque mask is generated on the film (negative). When a negative print is exposed to a positive print, certain opaque mask features are positively transferred to the final print as dark overexposed areas. One limitation of such conventional special effects devices is that they all rely on the technique of blocking some of the incident light before it reaches the film. Prior art methods using opaque masks can produce many effects, but there are many other effects that require more subtle diffusion methods. When taking a picture of a particular subject in a particular background, depending on the lighting conditions and light distribution of the background, as well as the reflective properties of the subject, the film negative may be overexposed or underexposed from the film's "normal" exposure range. Regions often occur. Conventional cameras typically include at least one light meter, which is used to measure the average intensity of the light before the light incident on the camera exposes the film. The light meter generates an electrical signal, which is processed by a computer and the size of the lens aperture or shutter speed, or its speed, so that the average intensity of light is corrected throughout the image recorded on the film. Control both. Some more advanced cameras, such as the Nikon (City, Japan) N-90, N90s, F5, use several independent light meters, each with a specific zone or area within the frame. (For example, the upper region is used to measure the intensity of light from the background sky). Using several light meters to measure the different light intensities for each region of the scene in the frame can provide a more accurate reading of the average intensity of the light, but the camera will not be able to read the specific area of the scene in the frame. Cannot reach the corresponding area on the film from the same without changing the amount of light reaching other areas on the film. In other words, the density of the entire negative can be corrected by adjusting the aperture or shutter speed of the lens, but since this exposure correction is equally effective over the entire recording area (ie, frame) of the film, is there. For example, if the aperture is stopped down to reduce the amount of light reaching the film and correct for "bright" points in the subject or background, the "neutral" or normal areas of the subject or background will be too dark. If the shutter speed is slowed and the darker areas of the image are "strongly burned", the normal areas will be overexposed beyond an acceptable level and "discolored". Unfortunately, since conventional cameras only measure the average of the total light of a particular image incident on the camera, some of the recorded images are overexposed (too dark) or underexposed (fading). There are many photos that will be. In order to prevent what would otherwise be a good photo without the negative effects of this relatively common exposure, photographers should, as a normal practice, take several photos of the same image. By changing the exposure of each shot (typically, about 1/3 EV) (that is, bracketing the image), the exposure of each image is slightly different. From among them, it is possible to select a recorded image in which the received light is most appropriately averaged. The Nikon N-90 mentioned above can have a bracketing function with the M-26 data back accessory, the camera automatically takes the selected number of photos, and exposes only a predetermined step for each shot. Can be changed. There are several problems with bracketing technology in photographic technology. In addition to exposing a large amount of film for images that change little, only relatively expensive cameras can make exposure adjustments, much less automatic bracketing of exposures. Also, while exposure bracketing allows you to choose from several photos, the camera's light meter must take into account all the light it receives, and it can also locally expose some of the image frames. Because of the correction, all bracketed photos are overexposed or underexposed at different stages. In other words, if an image has overexposed areas, bracketing does not compensate for the exposure in those areas, but simply hides them by changing the exposure of the entire image recorded on film. . Other attempts have been made to control the exposure in certain areas of the film frame without changing the exposure in other areas of the film frame. In a specially divided zone filter, regions having different opacity are provided, and the regions are corrected for a highlight region such as cloudy sky according to a specific scene. Such a filter rarely matches the details of the image, so it is only effective when the specific area defined by the filter matches the area of the scene. Once the negative has been developed, a "deep bake" or "strong bake" is performed by placing a density mask (made of opaque and translucent sheet material) in the exposure path (on photographic paper) when making a print from the negative. A technique commonly known as "burning" can correct for underexposed or overexposed areas while creating a photographic print. This mask is used to selectively protect the negative overexposed areas from some of the light projected on the photographic paper when the image is enlarged (ie, during the printing process). However, such techniques are used in expensive custom print processes and not in inexpensive automated print processes. Because the accuracy of placing the density mask in the proper position each time a print is made is inherently low and adjusting the position of the mask for each print is very time consuming, such techniques can be used repeatedly and evenly. Difficult to do. The result of such exposure correction is not known until the print is exposed and developed. If you do not get a satisfactory result, you have to try again by trial and error until you get a satisfactory print. It is therefore an object of the present invention to provide a special effects device for use in photographic technology which overcomes the limitations of the prior art. It is another object of the present invention to provide the above-described apparatus, which enables a photographer to convert a photographic image into an image having characteristics inherent to a painting. Another object of the present invention is to allow a photographer to overlay a translucent mask with a random crack pattern on the image to obtain the final print with cracks characteristic of old oil paintings. An object of the present invention is to provide the above device. Another object of the present invention is to provide such an apparatus wherein a photographer can overlay a translucent mask on the image and convert the image to an image having the essential characteristics of watercolor. is there. Another object of the invention is to allow a photographer to overlay a translucent mask on an image and convert that image into an image having the essential features of an oil painting drawn with a palette knife. It is to provide a device. It is another object of the present invention to provide a method and apparatus for producing photographic negatives that can correct for overexposed and underexposed areas before exposing the film. It is another object of the present invention to provide local exposure correction for selected areas of an image recorded on film that are along specific contours of a background, subject, or subject in the image. It is in. It is another object of the present invention to provide a preview image of an image that has been exposure corrected before the image is recorded on film. It is yet another object of the present invention to provide a stepwise different local exposure correction to an image. It is yet another object of the present invention to provide a method and apparatus for selectively deforming an image using a single deformation device adjacent to the film. Summary of the Invention In a first embodiment, the invention includes a transparent plate mounted on a film surface in a camera. The transparent plate has a translucent diffuse pattern that diffuses incident light reflected from the subject and effectively repositions it under control before exposing the film. With the proposed diffusion pattern, the light rays can be varied to create features found in various types of painting. In another embodiment of the present invention, a transparent plate having this translucent diffusion pattern is mounted on a film cartridge. In another embodiment of the invention, a length of plastic film (pattern strip) is placed adjacent to a similar length of photographic film (film strip). A suitable translucent diffusion pattern is provided on one surface of the pattern strip along its entire length. The two strips are wound on a conventional 35 mm canister and are pulled out simultaneously (within the camera) as needed, so that a mask is placed before each frame of film at the film gate of the camera. In another embodiment of the present invention, a transparent plate having a translucent diffusion pattern is disposed between the main lens of the camera and the camera body. In this arrangement, a correction lens is needed to sharply focus the pattern of the specific pattern on the image to be exposed on the film on the film surface. In another embodiment of the invention, an LCD is mounted in front of the camera film and used to correct specific areas of the image before the image light exposes the film. In another embodiment of the present invention, a number of transparent members, each having a different translucent diffusion pattern, are provided in a storage location remote from the camera film gate and one or more in the film gate between the film and the camera lens. It is slidably movable between a film gate position where the transparent member is arranged. In yet another embodiment of the present invention, a single-lens reflex type disposable camera has a pivoting mirror disposed between a camera lens and an eyepiece, wherein the mirror reflects incident light from the image into the eyepiece. It is rotatable between a first position directed to the lens and a second position where incident light is directed to the film. The rotatable reflector can also function as a light deforming device and is easily interchangeable with another deforming device. BRIEF DESCRIPTION OF THE FIGURES FIG. 1 is a cross-sectional side view of a single-lens reflex (SLR) camera according to a first embodiment of the present invention, showing a filmstrip, an optical deformation plate, a film surface, a lens assembly, and an incident light beam. . FIG. 2a is a plan view of an optical deformation device according to another embodiment of the present invention. FIG. 2b is a side view of the optical deformation device of FIG. 2a. FIG. 2c is a cross-sectional side view of the film gate of the camera, showing the optical deformation device of FIG. 2b being located within the film gate. FIG. 3 is a partial cross-sectional front view of a film cassette using an optically deformable plate according to another embodiment of the present invention. FIG. 4 is a partial cross-sectional top view of the film cassette shown in FIG. FIG. 5 is a partial front view of a filmstrip, an optical deformation strip, and a film bobbin according to another embodiment of the present invention. FIG. 6 is a cross-sectional side view of a camera in which the filmstrip, the optically deformable strip, and the film bobbin of FIG. FIG. 7 is a rear view of the camera of FIG. FIG. 8 is a partial cross-sectional side view taken along line 8-8 of FIG. 7, showing details of the filmstrip and the optically deformable strip on the film surface of the camera. FIG. 9 is a sectional rear view of a camera showing the optically deformable cartridge according to another embodiment of the present invention in a non-operation position. FIG. 10 is a cross-sectional rear view of the camera of FIG. 9, showing a state where the optically deformable cartridge is in an operation position in front of the film gate. FIG. 11 is a partial top cross-sectional view taken along line 11-11 of FIG. 10 showing details of the filmstrip and the optically deformable cartridge on the film side of the camera. FIG. 12 is a partial side cross-sectional view taken along line 12-12 of FIG. 11, showing details of the filmstrip guide and the optically deformable cartridge (after insertion). FIG. 13 is a cross-sectional side view of a deformer holder coupled between a camera body and a lens assembly (both shown in phantom) according to another embodiment of the present invention. FIG. 14 is a partial cross-sectional side view of the deformation device holder of FIG. FIG. 15 is a partial cross-sectional view of the deformation device holder of FIG. FIG. 16 is a top view of a disposable camera showing an optical deformation device assembly according to yet another embodiment of the present invention. FIG. 17 is a top view, partially in section, of the camera and optical deformer assembly of FIG. 16 taken along line 17-17 of FIG. FIG. 18 is a partial cross-sectional top view of the optical deformer assembly of FIG. 16, showing details of the optical deformer assembly along line 18-18 of FIG. FIG. 19 is a partial cross-sectional front view of an optical deformation device according to still another embodiment of the present invention. FIG. 20 is a partial cross-sectional view of the optical deformation device of FIG. 19, taken along line 20-20 of FIG. FIG. 21 is a cross-sectional view of an optical deformation device holder according to yet another embodiment of the present invention. FIG. 22 is a partial cross-sectional view of the optical deformation device holder of FIG. 21 taken along the line 22-22 of FIG. FIG. 23 is an explanatory drawing of a photograph of two flowers. FIG. 24 is an explanatory drawing of a photograph of two flowers in which light of an image is diffused by one of the optical deformation devices according to the present invention. FIG. 25 is an explanatory drawing of a photograph of two flowers with the light of the image diffused by another optical deformation device according to the present invention. FIG. 26 is a front view of an optical deformation device turret assembly according to another embodiment of the present invention. FIG. 27 is a cross-sectional side view of the deformation device of FIG. 26, taken along line 27-27. FIG. 28 is a partial cross-sectional front view of the deformation device disk taken along line 28-28 of FIG. FIG. 29a is a cross-sectional view of a camera according to another embodiment of the present invention, showing the film gate and the two pivoting devices in the stowed position. FIG. 29b is a cross-sectional view of the camera of FIG. 29a, showing a state where the first deforming device is in the storage position and the second deforming device is disposed in the film gate. FIG. 29c is a cross-sectional side view of the camera of FIG. 29, showing a state where the first deformation device according to the present invention is in the film gate and the second deformation device is located in the storage position. FIG. 30a is a partial cross-sectional rear view of a camera according to another embodiment of the present invention, showing the film gate, the film, the rails, and the first and second deformation devices located in a stowed position remote from the film gate. ing. FIG. 30b is a top view schematically illustrating the film gate area of the camera of FIG. 30a, showing the first and second deforming devices located in a storage position spaced from the film gate. FIG. 31a is a partial cross-sectional rear view of the camera of FIG. 30a, showing a state in which the first deformation device is disposed in the film gate. FIG. 31b is a top view schematically illustrating the film gate area of the camera of FIG. 31a, with the first deforming device positioned within the film gate and the second deforming device in the stowed position. FIG. 32a is a partial cross-sectional rear view of the camera of FIG. 30a, showing a state in which the second deformation device is disposed in the film gate. FIG. 32b is a top view schematically illustrating the film gate area of the camera of FIG. 32a, with the second deforming device positioned within the film gate and the first deforming device in the stowed position in accordance with the present invention. Is shown. FIG. 33 is a schematic diagram of a disposable single-lens reflex camera according to another embodiment of the present invention, showing a state in which a pivoting reflector is arranged in a view position. FIG. 33b is a schematic diagram of the camera of FIG. 33a, showing the pivoting mirror being repositioned from the view position to the exposure position in accordance with the present invention. FIG. 33c is a schematic diagram of the camera of FIG. 33a, showing the pivoting mirror in the exposure position according to the present invention. FIG. 34 is a schematic diagram of a camera according to another embodiment of the present invention. FIG. 35 is a schematic diagram of the camera of FIG. 34, including sample images viewed by various elements within the camera. FIG. 36 is a schematic diagram of a deformation device assembly according to another embodiment of the present invention. FIG. 37 is a cross-sectional side view of a camera according to another embodiment of the present invention, with the deforming device assembly of FIG. 36 disposed within the camera. FIG. 38 is a schematic diagram of a deforming device assembly according to another embodiment of the present invention, including three different deforming devices. 39a to 39c are examples of each distortion pattern arranged in each deformation device of FIG. 38 according to the present invention. FIG. 40 is a side view of a camera according to yet another embodiment of the present invention, including a lens attachment. FIG. 41 is a cross-sectional view of the lens attachment of FIG. 40 according to the present invention. 42a to 42c are examples of distortion images using the lens attachments of FIGS. 40 to 41. Detailed Description of the Preferred Embodiment In FIG. Camera body 12, A lens assembly 14 attached to the front of the camera body 12, And a camera 10 (single-lens reflex) with a film frame 16 shown in cross section at a film gate 18 (see FIG. 2c). The optical deformation device 20 according to the first embodiment of the present invention includes: It is arranged in the film gate 18 before the film 16. Since the specific structures of the film gate 18 and the shutter mechanism 19 of the camera 10 are conventional, Not shown in detail. In this embodiment, The shutter mechanism 19 Lens 14, Deformation device 20, And, of course, it is in front of (ie closer to) the frame of film 16. The deformation device 20 shown in more detail below, Between the film 16 and the shutter of the camera 10, The size and the shape fit into the film gate 18. A conventional spring-loaded film pressure plate 21 normally mounted on the inner surface of a camera door (not shown) (used for loading and unloading film) The film is pressed flat and light between the film gates 18 adjacent to the back surface of the deformation device 20. Referring to FIGS. 2a-2c, The deformation device 20 according to an embodiment of the present invention includes: It has a transparent plate 22 and a diffusion pattern 24. The transparent plate 22 Preferably, it is formed to have a raised (ie, thick) central section 26 defining two (thin) edge sections 28. The edge area 28 Designed to contact the camera part adjacent to the film gate 18, As shown in cross section in FIG. With the central area located within the film gate 18 of the camera 10, The entire deformation device 20 is held in the camera. The diffusion pattern 24 Functions as a translucent mask, Before the incident light reaches the film and is exposed, Spread this, Distort. The diffusion pattern 24 Preferably it does not prevent light from reaching the film (ie the pattern is not opaque). The transparent plate 22 of the deformation device 20 Preferably made of optical quality plastic, Optical quality glass can also be used. The diffusion pattern 24 Preferably, it is formed on the back surface 30 of the transparent plate 22 (which faces the film 16 when mounted on the camera 10). A preferred method of forming the diffusion pattern 24 is This is a method of embossing a specific pattern (negative or inverted) on the back surface of the plastic transparent plate 22. First, on the stamp surface of hard material, Machine the inverted pattern. Next, the plastic transparent plate 22 is softened (steam, Electric filament, Or other indirect heating, etc. (Performed by heat without flame) Press on the stamp surface, Transfer the pattern to the back of the plastic plate 22, A diffusion pattern 24 is formed. When the incident light beam passes through the deformation device 20 and strikes a part of the diffusion pattern 24, Before the light reaches the film and is exposed, A specific ray It scatters or diffuses to some extent without interruption. The diffusion pattern 24 Efficiently distorts incoming light under control, Therefore, the image is also efficiently distorted. The transparent plate 22 and the pattern 24 are both arranged on a film surface (also called a focal plane), Because it is soft focus (not sharp) The image is distorted according to a particular visible distortion pattern 24. Pattern 24 is Despite being effectively focused, Not a mask (not opaque), Because it is a light diffuser that slightly diffuses the incident light just before it reaches the film and is exposed, Looks somewhat soft (not sharp focus). By controlling and diffusing light in this way, Desired special effects can be imparted to the exposed image as described below. The deformation device 20 It is preferable to arrange as close to the film surface as physically possible. The deformation device 20 As shown in FIGS. 2a-2c and described above, If the type is stationary with respect to the camera, To avoid scratches when advancing the film, Preferably, the deformation device does not contact the film. Deformation device 20 When placed adjacent to the focal plane of the camera in the film gate 18, There are several embodiments. This will be described below with reference to FIGS. Referring to FIGS. 3 and 4, The optical deformation device 32 of the present invention It is incorporated within the structure of a conventional film cassette 34 (typically referred to as film type 120). The cassette 34 is Film supply unit 36, Film winding section 38, And a connecting section 40 for connecting the film supply section 36 and the film winding section 38. The connecting portion 40 It has a film gate 42 provided integrally, This film gate 42 Aligns with the film gate of a camera (not shown) that is adapted to receive cassette 34. In this embodiment, The deformation device 32 To be positioned adjacent to film 16 across film gate 42; It is preferable to arrange it in the structure forming the connecting portion 40 (at the time of manufacturing the cassette 34). The deformation device 32 As in the embodiments of FIGS. 1 and 2a-2c described above, A specific diffusion pattern 24 is provided. The deformation device 32 All light passing through the film gate 42 also passes through the deformation device, It is arranged to be slightly diffused before it reaches the film and is exposed. 5 and 6, 5 shows a deformation device 50 according to another embodiment of the present invention. In this embodiment, The deformation device 50 It is in the form of a thin strip of translucent plastic (similar to the substrate used in photographic film). The strip-shaped deformation device 50 includes: It is fixed to the inner surface 52 (emulsion side) of a conventional roll-shaped film 16 (35 mm type). The film 16 and the attached strip-shaped deformation device 50 are: It is wound together by a conventional spool 54 into a standard film canister (not shown). The strip-shaped deformation device 50 includes: By heat bonding or a suitable adhesive At the ends or between the frames (not shown) Preferably, it is attached only at selected points 56. The film 16 Although shown in 35mm format, 120, 220, 4x5, 110, And Polaroid ™ type film / paper, etc. Any film format can be used. In this latter format, A deforming device 50 is attached or placed across each sheet of film / paper, Remove after exposing and developing a specific image. FIG. 5 shows (in cross section) a conventional single-lens reflex camera 10 (similar to the camera 10 shown in FIG. 1) loaded with the film 16 of FIG. The strip-shaped deformation device 50 It is shown in front of the film 16 (closer to the lens 14) and across the film gate 18. FIG. 7 and FIG. 5 shows an optical deformation device 60 according to another embodiment of the present invention. This optical deformation device It is similar to that shown in FIGS. 2a-2c and described above. However, in this embodiment, The deformation device 60 The same size as the film gate 18, That is, the deformation device 60 does not have the edge 28. The deformation device 60 For example, using a suitable adhesive, It is permanently mounted in the film gate 18. The deformation device 60 With precision mating or appropriate ridges and / or detents, It may be snap-fitted to a predetermined position in the film gate 18. The deforming device 60 shown in this embodiment includes: It is particularly useful for disposable cameras. 9 to 12, 6 shows yet another optical deformation device 70 according to the present invention. The deformation device 70 It is mounted in the framework structure of the cartridge 72. The cartridge 72 is A thin plate adapted to be inserted into a slot 74 provided in a camera 76; The camera 76 Whether a special slot 74 is provided, Alternatively, a replaceable camera back (not shown) having a slot 74 may be provided. In both cases, The cartridge 72 is The deforming device 70 (mounted in the cartridge 72) is positioned at a position between the film gate 18 and the film 16 as shown in FIGS. Positioned by slot 74. One of the various cartridges 72 (each with a different deformation device 70) can be inserted into the slot 74. Each cartridge 72 has It is preferable to have a handle that is accessible even when inserted into slot 74. Slot 74 and / or insertable cartridge 72 To prevent extra light from entering the camera through the slot opening and exposing the film, It has a suitable light barrier. 13 to 15, 3 shows another embodiment of the present invention. In this embodiment, A deformation device coupler 80 is arranged between the camera body 12 and the lens assembly 14. The deformation device coupler 80 Connecting the lens assembly 14 to the camera body 12, The incident light is passed from the lens assembly 14 to the film gate 18 of the camera 10. The deformation device coupler 80 An image surface 82; A first lens assembly 84; A second lens assembly 86; A deformation device receiving slot 88; And a filter receiving slot 90. In this embodiment, Several different deformation devices 20 Each is placed on a plate 92. Select several plates 92, As shown in FIG. Place on the plate holder 94. The plate holder 94 is It is adapted to be mounted on the deformer coupler 80 adjacent to the deformer receiving slot 88. The plate holder 94 is A selected one of the several plates 92 held is So that it can be aligned with the deforming device receiving slot 88, It is slidably mounted on the deformation device coupler 80. The selected plate 92 is When aligned with the deforming device receiving slot 88, Can be moved into the deformation device coupler 80, The selected deformation device 20 Align with the incident light path from lens assembly 14. The selected plate 92 is FIGS. 14 and 15 show the inserted position. Conventional filters, etc. Other light deformation devices may be inserted into the filter receiving slot 90. When light enters the lens assembly 14, The internal lens of the lens assembly 14 and the first lens assembly 84 The reflected light from the subject is focused on the image plane 82 of the coupler 80 (the image is upside down). The inverted image is The image is deformed by the selected deformation device 20 on the image plane 82. from here, The second lens assembly 86 On the film surface located at the film gate 18 of the camera 10, Refocus the image (and return the image to its original orientation). An important feature of the present invention is that As shown in the above embodiments, Regardless of the arrangement of the focal plane with respect to the film surface, No matter how the deformation device 20 is introduced in the optical path of the image, That is, it is arranged as close as possible to the focal plane of the camera 10. As described in the above embodiment (FIGS. 13 to 15), Usually there is only one focal plane, On the film side, One at a point that is a predetermined distance from the film surface to the subject, Another one on film side 18, It is also possible to create two effective focal planes. 16 to 18, Fig. 4 shows a camera 100 with an optical deformation device assembly 102 according to another embodiment of the present invention. The camera 100 of this embodiment is Manufactured using relatively inexpensive parts, It is intended for a disposable type with a built-in film. The camera 100 of this embodiment includes: not to mention, It can also be a non-disposable type. The camera 100 A camera body 104 having a front surface 106 and a lens stop 108 is included. Commercially available conventional single-use cameras (ie, without the deforming device assembly of the present invention) A lens (not shown) mounted in the stop 108 is provided. A conventional lens (not shown) The subject in front of the camera, Focus on the film frame on the film plane (at the back of the camera). When manufacturing the disposable camera 100, Applicant: Considering replacing a conventional lens (not shown) with the optical deformation device assembly 102. As shown in the sectional view of FIG. The optical deformation device assembly 102 includes: A first outer lens 110 furthest from the film surface; A second inner lens 112 disposed adjacent to the front surface 106 of the camera 100. The optical deformation device 114 Inner lens and outer lens (112, 110) It is movably arranged in a plane parallel to the film plane of the camera 100. The outer lens 110 is The light reflected by the subject in front of the camera, It is focused on the intermediate focal plane 115. The inner lens 112 The image at the intermediate focal plane 115 is Focus on the film surface. As the distortion applied to the light from the subject is recorded on the film with sharp focus (i.e., as the diffusion of light passing through the deformer is in focus), It is desirable to position the optical deformation device 114 close to the intermediate focal plane. As shown in FIG. The optical deformation device 114 It is placed on the arm 116. The arm 116 is It is pivotally connected to a housing 118 of the optical deformation device assembly 102. The user of the camera 100 can touch and move a portion of the arm 116, Incident light passes directly to the film, A storage position (indicated by a dotted line in FIG. 17) that is not distorted (depending on things other than the lens), Between an interference position (shown by a solid line in FIG. 17) where the optical deformation device 114 is located in the light path, The optical deformation device 114 is moved. 19 to 20, The optical deformation device 114 was placed along the edge of the disk 120, 1 shows a preferred embodiment of the invention applied to a single use camera. Disk 120 is At a central pivot point 122 it is pivotally attached to the body of the camera 100. The disc 120 has several peripheral openings 124, Each aperture is provided with one of several different optical deformation devices 114 that achieve different effects. The disk 120 As one of the apertures 124 is arranged in front of the lens stop 108, Is placed. The operator of the camera 100 By rotating the disk 120 until a suitable optical deformation device 114 is aligned with the lens stop 108, Specific effects can be selected. By providing a lever 126, The rotation of the disk 120 may be assisted. Also, For example, an indicator (not shown) indicating a mark provided on the surface of the camera body is provided, Which effect is being used may be displayed. 21 to 22 include: The optical deformation device 114 was mounted on an elongated panel 128, 3 shows another embodiment of the present invention. Panel 128 It has two parallel inner edges 130 defining an elongated window. Several slide plates 132 It is slidably disposed between the two edges 130. Each plate 132 Containment location, Between the usable position arranged in front of the lens aperture 108, So that they can be moved selectively, Panel 128 It is placed on the front of the camera 100. Each plate 132 has an opening 134, One of several different optical deformation devices 114 is arranged in this opening. Each plate 132 With a preferably accessible handle 136, The operator of the camera can grasp this and move the plate 132 with respect to the lens stop 108 as necessary. As an example, A depiction of an undeformed photo (a photo of two flowers) is shown in FIG. One object of the present invention is to The subject image (that is, reflected from the subject, The light that enters the camera) It is to provide visual features that look like paintings. In one particular optical deformation device 114, Transform the image, As shown in FIG. 24, the impression style is applied. here, All the details are distorted, The image is substantially in focus. In another optical deformation device 114, Give the original flower image a "crack" effect (a characteristic of old oil paintings) The resulting print is as shown in FIG. not to mention, Using the deformation device of the present invention, As an optical deformation device or effect, Various pictorial features can be given. Similar to those shown in FIGS. 19 and 20 and described above, Another embodiment is shown in FIGS. This embodiment is: Deformation device housing 200, Deformation device turret 202, And a first lens housing 204. The deformation device housing 200 Although it is preferable to form it integrally with the surface of the disposable camera 206, Formed separately, It can also be adapted to be mounted as a camera attachment on any surface of the camera 206 used. The deformation device housing 200 A front wall 208, An aperture 210 that is aligned with the first lens stop 212 of the camera 206. A second lens tube 214 is disposed behind the front wall 20, A suitable lens (not shown), preferably designed to refocus the image on the film at the intermediate focal plane 216, is provided. The intermediate focal plane 216 is Preferably just before the front wall 208, It is arranged at the position of the deformation device turret 202. As shown in FIG. The deformation device turret 202 With the pivot pin 218, It is pivotally connected to a portion of the deformation device housing 200. The deformation device turret 202 It is rotatable about a pivot pin 218. The first lens housing 204 With the pivot pin 218, Alternatively, by being formed integrally with the camera 206 (or connected in another way), Preferably, it is fixed to the camera 206 and the deformation device housing 200. The first lens housing 204 The first lens 220 is supported. The first lens 220 is Incident light reflected from the image in front of the camera, It is designed to focus on the intermediate focal plane 216. The first lens 220 is It may be placed in the first lens tube 222. The deformation device turret 202 As shown in FIG. It has at least two openings 224. In one of the openings 224, For example, an optical deformation device 226 may be provided. The other opening (or a plurality of openings) shown in FIG. Leave empty or Providing a transparent element 227 or a translucent element with a matte surface, Alternatively, another optical deformation device may be provided. "crack", Impressionist style, Or other variants of the deforming device turret with several different deforming devices to create other pictorial effects are also conceivable. As shown in FIG. The deformation device turret 202 Preferably, the device further includes an indicia 228 or other indicator indicating the type of deformation device being used (or not being used). The operator looks at the mark 228, If a deforming device is arranged, so that it is possible to know which deforming device is disposed in the path of the incident light and has an effect on the film, An indicator aperture 230 may be further provided in the first lens housing 204 to match the indicia printed on the deforming device turret 202. A rubber O-ring 232 is further provided around the turret 202, In order for the operator to grip firmly when turning the turret, Ensure high friction is obtained. The O-ring is shown in FIG. Instead of the rubber O-ring 232 of FIG. As other gripperable surfaces, A rough edge (not shown) or a saw-shaped notch 234 shown in FIG. 28 may be used. During operation, The operator Looking at the mark 228 through the display opening 230, Until the desired deformation device effect is displayed Turn the deforming device turret 202. When an appropriate deformation effect is displayed through the display opening 230, A deformation device is arranged in front of the first lens 220; Therefore, it has an effect on the film. 29a to 29c, 4 shows a camera 300 according to another embodiment of the present invention. This camera 300 A body 302; A lens assembly 304; An eyepiece 306; A film gate 308, A first pivot mounting and deforming device 310 capable of pivoting about a first pivot point 311; A second pivotable mounting and deforming device 312 that can pivot about the second pivot point 313. For simplicity, In this embodiment, two deformation devices 310, Only 312 is shown. Depending on the type of camera and the mechanism that moves each deformation device, This embodiment can also be provided with more than three deformation devices. Each deformation device is When the shutter (not shown) is open, Without blocking incident light entering the camera 300 through the lens assembly 304, It pivots between storage positions to reach a film (not shown) located within the film gate 308. FIG. Deformation device 310, 312 shows a state in which it is in the storage position. in this case, The camera 300 In recording undeformed images on film, It works like a conventional camera. FIG. The first deformation device 310 is held in the storage position, The second deformation device 312 is shown as being located in or in close proximity to the film gate 308 (and in front of the shutter and the film). In this arrangement, Image light entering camera 300 through lens assembly 304 is: Before reaching the film, It must pass through a transparent (or translucent) deformation device 312. So the light from the image is As explained earlier in the present invention, It is changed by the second deformation device 312. FIG. The second deforming device 312 is returned to the storage position and rearranged, The first deformation device 310 is shown in a state where the first deformation device 310 is disposed in or in close proximity to the film gate 308 (and in front of the shutter and the film). In this arrangement, Image light entering camera 300 through lens assembly 304 is: Before reaching the film, It must pass through the deformation device 310 (if the shutter is open). Each deformation device 310, 312 is Preferably, it is biased by a spring to the storage position shown in FIG. The film gate position shown in FIGS. 29b and 29c is to be mechanically pivoted. One or both deformation devices, To pivot between the stowed position and the film gate position, Any suitable mechanism known to those skilled in the art may be used. In operation, The operator of the camera 300 Select the subject to be recorded on the film, Then adjust the image, For example, whether to make it look like a painting, It also selects which type of deformation device (already mounted on camera 300) should be used. If you do not use the deformation device, The camera 300 operates in a conventional manner, Deformation device 310, If you want to deploy 312 from the storage position to the film gate position, Activate a suitable actuator provided on the camera 300, Deformation device 310, One (or both) of 312 From the storage position to the film gate position against the action of the spring bias, It can be pivoted mechanically or electromechanically. After taking each photo, In order to automatically return the deployed deformation device to the storage position, Appropriate electronics and software may be used. 30a to 32b, Body 402, Film gate 404, Film 406, First deformation device 408, Second deformation device 410, Rail 412, And a shutter 414, Fig. 4 shows a camera 400 according to another embodiment of the present invention. This embodiment is: 29a-29c, which is similar to the embodiment shown and described above, Whereas in the previous embodiment the deformation device was pivotally mounted, The deformation device of this embodiment includes: The difference is that it is slidably mounted on the main body 402. In this embodiment, Each deformation device 408, 410 is It is arranged on both sides of the film gate 404, Further, it is slidably mounted on a rail 412 extending to a position in the main body 402 separated from the film gate 404. In operation, Deformation device 408, Either (or both) of the 410 A storage position shown in FIG. Between the film gate positions shown in FIGS. 31b and 32b, It can be slidably moved. Deformation device 408, 410 is It can be moved along the rail 412 by a suitable mechanism. Such a mechanism By an onboard processor (not shown) Alternatively, it can be driven using a built-in electric motor that can be manually controlled by a lever operation directly operated by the user of the camera 400. 30a and 30b Deformation device 408, 410 shows a state where both are in the storage position, Both deformation devices, No change is made before the light of the image entering camera 400 reaches film 406. 31a and 31b To make changes by the first deformation device 408 before the incident light reaches the film 406, A first deformation device 408 is disposed at the film gate position, This shows a state in which the second deforming device 410 remains at the storage position. Similarly, 32a and 32b Before the incident light reaches the film 406, In order to provide an effect only by the second deformation device 410, A second deformation device 410 is arranged at the film gate position, The state where the first deformation device 408 is in the storage position is shown. In this embodiment, When the operator of the camera 400 Depending on the type of transformation you are trying to do, Before opening the shutter of camera 400, A particular deformation device can be selected, either the first deformation device 408 or the second deformation device 410 (in this case shown in FIGS. 30a to 32b). For example, As explained earlier in this application, The first deformation device 408 includes: The light of the statue can be transformed to have an impressionist-like character, The second deformation device 208 includes: Since the light of the image can be transformed to have cracked features, The operator of the camera 400 can use any of these variants, A state where neither deformation is performed (normal image), Alternatively, it is possible to choose to carry out a third further deformation using both deformation devices. In this embodiment, Deformation device 408, Any number of 410s may be provided. For simplicity, Only two deformation devices are shown, Explain. When operating a conventional single-lens reflex (SLR) camera, The camera operator So that you can see the image you are looking through the lens The incident light from the image is Through the lens assembly, The light is reflected toward the eyepiece by the pivoting mirror and the prism (or the second fixed mirror). The lens is typically Means for focusing on the image; An aperture for controlling the amount of light entering the camera. When you press the trigger button on the camera, The shutter curtain is exposed, So that the lens converges on the point directly behind the shutter (on the film behind the shutter) The pivoting reflector pivots. Then the shutter opens at the selected shutter speed, The film is exposed to the converged light for a predetermined time. 33a to 33c, Lens assembly 502, Fixed reflecting mirror 504, Pivoting reflector 506, Viewing screen 508, Eyepiece 510, Film cassette 512, And a film gate 514. FIG. 4 shows a schematic diagram of a single use single lens reflex (SLR) camera 500 according to another embodiment of the present invention. The film cassette 512 and the film gate 514 are Preferably, as shown in FIGS. 33a to 33c, On the front side of the camera 500 and above the lens assembly 502, It is arranged to face the viewing screen 508 and the eyepiece 510. The purpose of this embodiment of the invention is to The advantages of SLR cameras, It is to provide a camera that combines the simplicity and low cost of a disposable camera. The lens assembly 502 includes It preferably has a built-in single speed shutter similar to the type of lens / shutter used in conventional disposable cameras. The pivoting mirror 506 is Mounted pivotably within the camera 500, The angle can be changed between the view position (shown in FIG. 33a) and the exposure position (shown in FIG. 33c). When the pivoting mirror 506 is in the view position, The image light from the subject Enters camera 500 through lens assembly 502 (and shutter (not shown)); The image is projected onto the viewing screen 508 by the fixed reflecting mirror 504 and the pivoting reflecting mirror 506. The image projected on the viewing screen 508 is It can be seen through eyepiece 510 in a conventional manner. When the pivoting mirror 506 is in the view position, The film is not exposed with image light. When the pivoting mirror 506 is in the exposure position, The same image light passing through the lens assembly 502 and shutter (not shown) The light is reflected toward the film gate 514 and the film 512 by the fixed reflecting mirror 504 and the pivoting reflecting mirror 506. When the pivoting mirror 506 is in the exposure position, No image light is visible. The shutter arranged in the lens assembly 502 includes: Open only when the pivoting mirror 506 is in the view position (FIG. 33a) or the exposure position (FIG. 33c). It does not open when the pivoting mirror 506 is moving between the two positions as shown in FIG. 33b. In operation, First, deflect and release the camera shutter, So that the operator can see the image of the subject through the lens (similar to a more expensive single-lens reflex camera) The pivoting mirror 506 assumes a view position. If the operator wants to record a specific image on film, Release the button (not shown) Blocking light from the image from entering the camera 500 by closing the shutter, The pivoting mirror 506 is rotated from the viewing position to the exposure position shown in FIG. When the pivoting mirror 506 assumes the exposed position, The shutter opens automatically, Closes again (preferably at the set shutter speed), An image is exposed on a film frame located within a film gate 514. After the shutter closes again, The pivoting mirror 506 returns to the view position, The shutter opens again, So that you can see the next image, Show the light of the image to the operator. The lens assembly 502 includes Viewing screen 508, Or on one of the films located in the film gate, Focus the light of the image. Therefore, The distance the image light travels from the fixed mirror 504 through the pivot mirror 506 to the viewing screen 508 is It is the same as the distance from the fixed mirror 504 through the pivot mirror 506 to the film gate 514. Using a motor (not shown) Or, operate the pivoting reflector 506, Using a pre-wound mainspring with sufficient rotational energy to expose all films in film cassette 512, The pivoting mirror 506 can be rotated. To operate the shutter in conjunction with the pivoting mirror 506, Any suitable mechanism known to those skilled in the art may be used. In a related embodiment of the invention, As explained earlier in the present invention, The light of the image Before being recorded on film, Deformation, Distorted, Or in any other way, A light deformation device may be provided on both sides or one side of the pivoting reflector 506. The pivoting mirror 506 may have two or more functional surfaces, Several different types of deformation devices may be incorporated and selected. In FIG. Body 602, Lens assembly 604, Aperture 606, Pivoting reflector / prism assembly 608, Eyepiece 610, Shutter 612, And a film 614, 6 schematically illustrates a single lens reflex (SLR) camera 600 according to another embodiment of the present invention. According to the present invention, The camera 600 Multi-segment exposure meter 616, Reference liquid crystal display neutral filter (LCD-ND) filter 620, And a correction LCD-ND filter 622. To illustrate the invention, As will be appreciated by those skilled in the art, The pivoting reflector-prism assembly 608 includes Light rays entering the camera 600 through the lens 604 (as “image light”) It shall be efficiently divided into three independent passages each receiving all of the image light. The first passage is directed through the reference LCD-ND filter 620 to the eyepiece 610, The second passage is directed to a multi-segment exposure meter 616, The third path is directed to film 614 through correction LCD-ND filter 622 and shutter 612. The multi-segment exposure meter 616 In the same manner as a charge coupled device (CCD) converts optical information into electrical signals and records an optical image on videotape, The light of the received optical image is converted (digitized) into an electric signal. The multi-segment exposure meter 616 Preferably, it is a CCD type sensor. If the light of the image was converted to electrical signal data, This information is read by the processor 618. The received information includes The luminance (brightness) of each pixel of the light of the image measured by the multi-segment exposure meter 616 is included. Using the same conventional boundary recognition technology used in illustrator programs such as Adobe's Adobe Illustrator and Photo Work shop, Processor 618 is Using the information from the multi-segment exposure meter 616, Classify the pixels of the multi-segment light meter having a similar contrast level (or exceeding a predetermined luminance level) As contrast with the pixel representing the background image (s), Recognize pixels that represent the subject (s) of the foreground. After forming a pixel group by relative luminance (or contrast), Processor 618 is The information is sent to the reference liquid crystal display neutral filter (LCD-ND filter) 620 and the correction liquid crystal display neutral filter 622 at the same time. LCD-ND filters 620 and 622 Preferably a high resolution clear plate LCD, Functions as a light valve (for each pixel). The reference LCD-ND filter 620 is As described below, It is physically located in front of the eyepiece 610. The correction LCD-ND filter 622 includes: As described below, It is physically located before the shutter 612. Processor 618 is Selectively controlling the collective brightness of each pixel in the selected group, For example, the entire pixel group representing the subject of the foreground can be effectively opaque, By making it even translucent, Forming a "mask" that can be used to block (at least for part of the exposure time) certain areas of the image light (corresponding to "bright" areas of the image) from reaching film 614. it can. Controller 624 is Electrically connected to the processor 618, Used to control the brightness of either the foreground subject or the background image. This is simply LCD-ND filter 620, This can be done by controlling the voltage supplied to 622. LCD-ND filter 620, By changing the voltage supplied to 622, LCD-ND620, The opacity of each of the 622 selected pixels can be changed. Processor 618 uses the digitized image data to LCD-ND filter 620, 622 Select both pixels. The image light directed to the eyepiece 610 by the pivoting mirror / prism assembly 608 is In order to pass the reference L CD-ND filter 620 without fail, The reference LCD-ND filter 620 is disposed in front of the eyepiece 610. The selected pixel of the LCD-ND filter 620 is According to the digitized image data sent to the processor 618, The light of the image directed to the eyepiece 610 is selectively masked. The operator Through the eyepiece 610 Selected “bright” areas of the image The image of the reference LCD-ND filter 620 covered with the superimposed mask of the darkened (selected) pixels can be seen. at the same time, Processor 618 is The image light simultaneously directed to the shutter 612 by the pivoting mirror / prism assembly 608 is Be sure to pass the LCD-ND filter 622 The correction LCD-ND filter 622 is controlled in a similar manner. Similarly, A predetermined time during the exposure of the film 614 (while the shutter 612 is open) To protect selected areas of the film 614, Processor 618 is The selected area of the correction LCD-ND filter 622 is selectively darkened. As will be appreciated by those skilled in the art, Processor 618 further includes According to the specific aperture and shutter speed settings controlled by the operator, The operation of the shutter 612 and the aperture 606 is also controlled, The appropriate exposure time for unmasked areas of the image light is also controlled. The processor also: The relative opacity of a pixel or group of pixels during exposure can also be controlled and changed. this is, During the exposure time (the shutter is open) Throughout the "bright" areas of the statue, Or just along the border of two areas with different contrasts (the bright sky next to the person in the foreground) This is done by rapidly and continuously shifting the darkened pixel or group of pixels. By shifting under control during exposure in this way, It mimics the dodging process used in conventional printing processes. By moving the mask, Reduce the masking effect, More realistic exposure correction can be performed. In FIG. 35, A camera 600 recording an image on film 614 is shown. The image shown here is Against a bright, partially cloudy sky, A woman wearing a black hat is placed in the foreground. The image that enters the camera 600 as described above (see FIG. 34) Multi-segment exposure meter 616, Reference LCD-ND filter 620, And to the LCD-ND filter 622. The multi-segment exposure meter 616 Digitizing the light of the received image, Pixel luminance information is sent to processor 618. Processor 618 receives this, Classify the image into groups of pixels having a luminance above a predetermined level. For example, Pixels representing women and hats are: Since it is judged darker than the sky on a light background, In the same group, As shown in FIG. For both the reference LCD-ND filter 620 and the correction LCD-ND filter 622, As a transparent part, Displayed electronically. This allows the processor 618 to When considering the exposure parameters, the bright sky does not need to be considered. A relatively dark image of the woman and hat is exposed on film 614. By "reading" from a dark subject, As a result of the exposure, The woman / hat theme is correctly exposed, The background sky is very fading. The bright sky part of the statue is Grouped as a zone or area, According to the relative contrast between the sky and the woman / hat theme It is darkened to a predetermined opacity. The darkened pixels representing the bright sky portion of the image are As the mask of the bright sky portion itself is displayed simultaneously in front of the eyepiece 610 and in front of the film 614, LCD-ND filter 620, 622 are accurately positioned. The end result is: A correctly exposed woman / hat theme, The background, which is a correctly exposed bright sky, It is recorded on one frame of the film 614. As shown in FIG. Using the controller 624, Bright zone (area) of the image, And the level of opacity or transparency of both the dark zones (areas) can be varied. For example, Change the exposure of the bright sky, Different exposure, Therefore, the contrast can be relatively different (similar to the bracketing technique used in conventional photographic techniques). In FIG. 35, Of both groups of the original statue (woman / hat theme and bright sky background) Also shown are five corrected image samples with different contrasts controlled by the controller 624. In operation, The operator of the camera 600 While looking at the bright area of the image through the eyepiece 610, Using the controller 624, Can be darkened in real time. Similarly, Using the controller 624, Brighter areas of the image can also be selectively darkened. If the corrected image looks correct (or as desired), An image (with selective correction) may be recorded on film 614 as described above (see FIG. 34). In FIG. 36, According to another embodiment of the present invention, Using two or more deformation devices, The image light is distorted or altered before exposing the film of the camera 700. The first deformation device 702 includes: Preferably stationary with respect to the film, It is arranged in the first plane. The second deformation device 704 is Preferably it is selectively movable in a second plane adjacent and parallel to the first plane. Each deformation device 702, 704 is Texture, Add a pattern, Rough and rough, Others have a distorted surface (either side, Further, a distortion generating element may be provided in the deformation device). When the second deformation device 704 moves with respect to the first deformation device 702, The light of the image from the subject Continuously distorted in an unpredictable manner, Before the light of the image is recorded on the film, Unusual and unique effects are imparted to the image light. This variable distortion effect There are some similarities to the distortion effects obtained when viewing the image through a two layer screen. In this example, If you move one screen slightly (depending on the size of the opening), The image looks different. In FIG. First (stationary) deformation device 702, A second (movable) deformation device 704, Lens assembly 706, Eyepiece 708, Film gate 710, And a film 712 FIG. 37 shows a side sectional view of the camera 700 according to the embodiment of the present invention shown in FIG. 36. Light is Upon entering camera 700 through lens assembly 706 (indicated by the arrow in FIG. 37), Before exposing the film 712 disposed in the film gate 710, It must pass through the second deformation device 704 and the first deformation device 702 (and a shutter (not shown)). The second deformation device 704 is In order to be able to move under control with respect to the film 712 and the first deformation device 702 (in this case, up and down), It is placed on the camera 700. In the second deformation device 704, A button 714 is attached by an arm 716. Between the second deformation device 704 and the camera 700, To urge the button 714 to the rest position, A spring 718 is attached. When operating, the operator Once you have selected a particular subject that will be visible through the eyepiece 708, Press the button 714 to varying degrees, Different degrees of distortion can be provided for each image. In FIG. 38, In connection with the embodiment shown in FIGS. 36 and 37 and described above, Main lens 750, First deformation device 752, A second deformation device 754, Third deformation device 756, Relay lens 758, And film 760 (or a digital input device, scanner, A digitizer, etc.). In this arrangement, Any combination of deformation device 752, 754, 756, It can be moved laterally (in a plane parallel to film 760, respectively) by a selected degree. The main lens transforms the image light from the subject into a deformation device 752, 754, Focus on 756. When the light of the image is deformed by all three deformation devices, It is refocused on film 760 by relay lens 758. The relay lens 758 is As described in the previous embodiment of the invention, Only necessary if the deformation device cannot be placed adjacent to the film 760. FIG. 39a, FIG. 39b, And FIG. 39c, Each of the first deformation devices 752, A second deformation device 754, And an example of the third deformation device 756. In a modification related to the embodiment shown in FIGS. 36 and 37, When the operator is holding and operating the camera 700 in a normal state, In order that the second deformation device 704 can freely move at random in the second plane, The second deformation device 704 is Using an elastic element such as a spring, This includes placing the camera on the camera in a second plane adjacent and parallel to the first deformation device. further, Deformation device 702, One (or both) of 704 may be mounted in a non-parallel orientation with respect to film 712. Movement in either the second or first plane is preferred, Deformation device 702, 704 may be moved or distorted to any plane relative to film 712, A variety of distorted images can be created. Deformation device 702, 704 is It is preferable to make a flat sheet of a hard or semi-hard transparent material such as plastic or glass, To further change the way the image is distorted, Created by an appropriate injection molding process, Curved or bent shape, It is also possible to give a three-dimensional surface texture (for example, surface relief). Also, Deformation device 702, 704 (or both) Loaded into the camera 700 as a roll, It may be made of a flexible transparent film (not shown) that is randomly or at least different in the longitudinal direction. In a film type deformation device (not shown), By selectively moving over film gate 714 (e.g., winding up like a conventional film) Different distortion patterns and textures can be provided in front of the unexposed frames of the film. As described above in the previous embodiment, Applicant: Just as the image is distorted and changed artistically, By placing a deformation device on the film surface in front of the film, the light incident on the camera can be adjusted, Therefore, depending on the deformation device used, It has been found that it is possible to create a quirky and aesthetically pleasing representation of the image (for example, the image can be changed so that the subject looks like an Impressionist painting). Deformation device 702, By selectively moving any of 704 relative to film 714, Can control the sharpness of the changed light reaching the film, Thereby, various effects can be given to one image using one deformation device. Applicant further: The sharpness of the light change is It has been found that control is also possible by changing the main focus of the lens assembly 706. To do this, With the fixed deformation device 702 positioned adjacent to or within the film gate 712, The operator first focuses on the subject, Within a predetermined range, which is then indicated by a mark on the lens and / or camera (or similarly indicated using suitable electronic devices), Changes focus slowly (in either direction) by a controlled degree. By changing the focus to the subject of the lens assembly 706, Softens the light of the image representing the subject entering the camera, Reduce the sharpness and detail of the contrast border defining the subject; Obtain a soft image. This "soft" light is deformed by the deformation device 702, Can be recorded on film. The degree of focus change is Determining the degree and characteristics of the deformation by the deformation device. Alternatively, Or in combination with focus adjustment, Changes in the adjustment can also be controlled by changing the aperture of the lens. 40 and 41, FIG. 10 shows a camera 800 according to another embodiment of the present invention, comprising a body 802 and a lens assembly 804. FIG. According to the present invention, The image light incident on the lens assembly 804 passes through the lens attachment 806 first, Attach the lens attachment 806 to the open end of the lens assembly 804. The lens attachment 806 is A substantially cylindrical housing 808 supporting at least one lens 810 (two shown in the figure) is provided. The lens 810 is So that it stays in the rest position Although it is elastically mounted on the housing 808 by the mount 812, As shown by the arrow in FIG. By applying an inward force to mount 812 along the outer surface of housing 808, It can be moved manually in housing 808 to some extent randomly. In operation, The operator Eyepiece of camera 800, Lens assembly 804, And looking at a specific image (eg, baby) through lens attachment 806, When the mount is twisted (accessible from the outer surface of the housing 808) According to the twisting method and the twisting force of the mount 812, The lens 810 moves from the rest position. As the operator twists mount 812, In the same manner as the distorted mirror in the amusement park, The image of the subject you are looking at is distorted. Mount 812 Preferably annular, Made of suitable semi-rigid to flexible rubber such as silicon, As shown in FIGS. 40 and 41, A part of the housing 808. 42a to 42c, 9 is an example showing how displacing a lens 810 in a housing 808 can distort the subject (baby). The lens 810 is It is preferable to remove the force applied to the mount 812 and return to the original rest position, When the lens 810 is in the stationary position in the housing 808, it is preferable that the image light is not distorted (other than enlargement). In another aspect, Referring to FIG. The lens 810 is It is located adjacent to another lens 811 that defines an intermediate space 814 with the mount 812. Lens 811 or lens 810 (or both) It is made of semi-rigid plastic (such as plastic used to make conventional contact lenses for correcting myopia). A fluid such as an inert gas or a transparent liquid is placed in the intermediate space 814. This fluid is It is enclosed in the intermediate space 814 by a mount 812 (preferably flexible rubber). In operation of this embodiment, When the mount 812 is twisted (or otherwise deformed) by the operator's hand, The fluid in the intermediate space 814 is pressed against the lens 811 and the lens 810. This force causes one (or both) lenses to gradually deform (swell outward), The light of the image that later enters the lens attachment 806 is deformed. The lens attachment 806 is Preferably provided as an attachment to be attached to the lens assembly 804, It can also be provided integrally with the lens assembly 804. The embodiments described above are: The light of the image that enters the “still” type camera, It was related to changing the film before exposing it, Applicant: It is contemplated that this light deformation of the image may be used for other recording media. For example, After creating a negative (or transparency), When developing a print, Attach the negative to the stretching device. The image recorded on the negative is projected by a light source onto photographic paper or a large CCD (for video recording or scanning). According to another feature of the invention, , Adjacent to the negative, Or next to photographic paper, Or place the deformation device at one of the positions in the middle, Before the light exposes the photographic paper (or is downloaded to electronic memory), The light of the image projected in the manner described above can also be modified. The deformation device is It may be placed in a slot provided in the stretching device, It may simply be overlaid on the negative in the negative carrier. further, As mentioned above, The deformation device changes the light of the image, "Recorded" by an electronic scanner, It can also be used to distort before being downloaded to a computer. There are computer software programs that can electronically distort recorded images, This process is very time consuming. By downloading a pre-transformed image to a computer, Save time, Effects that cannot be easily obtained with a computer program can be provided.

[Procedure for Amendment] [Date of Submission] November 15, 1999 (November 15, 1999) [Content of Amendment] [Fig. 33] FIG. 34 FIG. 35

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (GH, KE, LS, MW, S D, SZ, UG), EA (AM, AZ, BY, KG, KZ , MD, RU, TJ, TM), AL, AM, AT, AU , AZ, BA, BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, EE, ES, FI, G B, GE, HU, IL, IS, JP, KE, KG, KP , KR, KZ, LC, LK, LR, LS, LT, LU, LV, MD, MG, MK, MN, MW, MX, NO, N Z, PL, PT, RO, RU, SD, SE, SG, SI , SK, TJ, TM, TR, TT, UA, UG, US, UZ, VN, YU

Claims (1)

[Claims] 1. Camera Attachment for Changing the Light Bundle of an Image Before It Is Recorded on Film Camera, comprising a lens aperture and a film disposed on a film surface. A frame and a lens, and the attachment is   A transparent deformation device that can be arranged adjacent to the film surface;   Means for distorting the light, wherein the means for distorting is provided in the transparent deformation device. The means for distorting is integrally formed on a surface, and the means for distorting light from the image. Transparent to form a distorted image, distorted in the focal plane, and the image is Attachment for camera recorded in. 2. The transparent deformation device is a plate, and the camera attachment is further provided. A slot defining a deformation surface parallel to and adjacent to the film plane. The slot is sized and shaped to receive the transparent plate; The camera attachment according to claim 1. 3. The slot prevents light from entering the camera through the slot. 3. The camera attachment according to claim 2, further comprising: 4. The camera is provided with a shutter operable within a film gate, The shaping device is a semi-rigid plate, between the shutter and the film, Size and shape to fit the film gate The camera attachment according to claim 1, wherein: 5. The semi-rigid transparent plate has a concave portion, and the concave portion connects the transparent plate to the flat plate. Arranged to engage a portion of the camera in such a manner as to be retained within the film gate. The camera attachment according to claim 4, wherein the camera attachment is disposed. 6. The film is loaded into a camera as a cartridge, the cartridge comprising: A film supply roll, a film gate, and a take-up spool; A light deformation device is provided in the film gate between the supply roll and the take-up spool. The camera according to claim 1, wherein the camera is arranged and attached to the cartridge. Attachment. 7. A film for a camera, the film comprising:   An elongated plastic substrate with a photosensitive emulsion;   An elongate plastic translucent deformation device, said translucent deformation device comprising: At least a portion of the light directed at the film is translucent before reaching the emulsion. Attach to a part of the plastic substrate so as to be deformed by the deformation device Film for cameras. 8. The plastic substrate and the translucent deformation device are wound together on a spool. Is a thin strip that is adapted to be The film of claim 7, wherein the film is drawn from a spool. 9. A body having a front surface and a back surface;   A film surface arranged adjacent to the back surface,   An intermediate focal plane arranged a predetermined distance forward from the film surface,   Arranged in front of the intermediate focal plane to focus light from an image onto the intermediate focal plane An adapted first lens,   Being disposed in the intermediate focal plane and selectively deforming at least a portion of light from the image A transparent optical deformation device adapted to   Being located between the intermediate focal plane and the film plane, A second lens adapted to focus the deformed image on the film surface. A disposable camera. Ten. The transparent optical deformation device, wherein the deformation device deforms a part of the light from the image; Between one position and a second position where light from the image reaches the film without deformation. 10. The disposable of claim 9, further comprising means for moving the disposable. camera. 11． Further comprising a second transparent optical deformation device, the first and second transparent optical deformation device One of the light from the image before the film is exposed to the film; Claims: Means for positioning in the intermediate focal plane to deform A disposable camera according to claim 9. 12． Both the first and second transparent optical deformation devices are provided in the intermediate focal plane with copper oxide transfer. The first optical deformation device is mounted on a moving member; A first position for deforming at least a part of the light, and the second optical deformation device Movable between a second position that deforms at least a portion of the light from A disposable camera according to claim 11, wherein: 13. The moving member further allows the light from the image to reach the film without deformation 13. The disposable camera according to claim 12, wherein the camera takes a position. 14. Camera Attachment for Changing the Light Bundle of an Image Before It Is Recorded on Film Camera, comprising a lens aperture and a film disposed on a film surface. A frame and a lens, and the attachment is   Between the film surface and the image, located at a predetermined distance from the film surface Intermediate focal plane,   Means for focusing the aggregate of light from the image on the intermediate focal plane;   A transparent optical deformation device arranged in the intermediate focal plane,   A device for distorting the light, wherein the means for distorting comprises the transparent optical deformation device. And means for distorting the light from the image. Distorted at the intermediate focal plane, transparent to form a focused distorted intermediate image, The attachment is   Refocusing the focused distorted intermediate image from the intermediate focal plane onto the film surface An attachment for a camera, further comprising means for focusing. 15． The transparent optical deformation device, wherein the deformation device deforms a part of the light from the image A first position, and a second position where light from the image reaches the film without being deformed. 15. The turtle according to claim 14, further comprising means for moving between the turtles. Attachment for LA. 16． Further comprising a second transparent optical deformation device, the first and second transparent optical deformation device One of the light from the image before the film is exposed to the film; Claims: Means for positioning in the intermediate focal plane to deform Item 15. Camera attachment according to Item 14. 17． The first and second transparent optical deformation devices are both movable in the intermediate focal plane. The movable moving member is mounted on the moving member, and the first optical deforming device may A first position for changing at least a part of the light, and the second optical deformation device Movable between a second position that changes at least a portion of the light from the Item 17. A camera attachment according to Item 16. 18． The moving member further reaches the film without light from the image being modulated 18. The camera attachment according to claim 17, wherein the attachment for the camera takes a position. 19. The moving member is a turret rotatable about a pivot point. Item 19. A camera attachment according to Item 18. 20. An elongated member slidable between the first position and the second position; 19. The camera attachment according to claim 18, which is a plate.