Patent Description:
In the related art, there is disclosed a technique in which, in a case where an image displayed on an image display device is exposed on an exposure surface of a photosensitive recording medium, the photosensitive recording medium is irradiated with light emitted from the image display device parallel to each other with a collimator (see, for example, <CIT>).

Further, in an electrophotographic image forming device, there is disclosed a technique for correcting unevenness in the amount of light caused by manufacturing variation of an optical element. For example, <CIT> discloses a technique in which a test image is printed, the printed test image is read, density correction data is obtained based on density data of the read test image, and the amount of light from a light source is adjusted based on the density correction data. <CIT> relates to an evaluation of colors in a printed matter with respect to respective colors in a color sample. <CIT> discloses an image-exposure apparatus which irradiates the light. It includes a support unit and a limit element which limits the angle of the light provided between the image display apparatus and the support unit.

In the technique described in <CIT>, a louver film composed of a light transmission part and a light shielding part can be used as a collimator. However, in the louver film, the width between adjacent light shielding parts may not be constant due to manufacturing variation and the like. In a case where the image displayed on the image display device is exposed to the exposure surface of the photosensitive recording medium using such a louver film, the exposure surface of the photosensitive recording medium cannot be uniformly irradiated with light, and a recorded image recorded on the photosensitive recording medium may have density unevenness and streak unevenness.

The present disclosure provides an information processing method capable of suppressing unevenness of recorded images.

According to a first aspect of the present disclosure, there is provided an information processing method comprising: an exposure step of exposing a correction image displayed on an image display device having a plurality of pixels to a photosensitive recording medium via a limiting member, the limiting member being provided between the image display device and an exposure surface of the photosensitive recording medium and limiting an angle of light emitted from the image display device to the photosensitive recording medium; an acquisition step of acquiring recorded image data, which is data of a recorded image recorded on the photosensitive recording medium through the exposure of the correction image; and a derivation step of deriving a correction coefficient K for correcting a pixel value for each pixel of a display image for each pixel of the image display device based on the recorded image data such that the display image including unevenness of which brightness is complementary to unevenness that occur in the recorded image is displayed on the image display device.

In a second aspect of the present disclosure, in the derivation step according to the above aspect, the correction coefficient K may be derived using a pixel value Cr for each pixel of the recorded image and a reference pixel value Cs of the recorded image, which are derived based on the recorded image data.

In a third aspect of the present disclosure, according to the second aspect, the reference pixel value Cs may be an average value of the pixel values Cr for each pixel of the recorded image.

In a fourth aspect of the present disclosure, in the derivation step according to the second and third aspects, in a case where a predetermined constant is denoted by A, the correction coefficient K may be derived based on the following equation (<NUM>).

In a fifth aspect of the present disclosure, according to the above aspects, the correction image may include an alignment pattern, the information processing method may further comprise a modification step of modifying the recorded image data based on the alignment pattern such that a position of the recorded image indicated by the recorded image data and a position of the correction image match, and in the derivation step, the correction coefficient K may be derived based on the recorded image data that has been modified.

In a sixth aspect of the present disclosure, in the modification step according to the fifth aspect, the recorded image data may be modified such that centroid coordinates of the alignment pattern included in the recorded image indicated by the recorded image data match centroid coordinates of the alignment pattern included in the correction image.

In a seventh aspect of the present disclosure, in the acquisition step according to the above aspects, the recorded image data may be acquired at a resolution equal to or higher than a resolution of the image display device.

In an eighth aspect of the present disclosure, according to the above aspects, the information processing method may further comprise a correction step of correcting a pixel value Cb for each pixel of the display image using the correction coefficient K.

In a ninth aspect of the present disclosure, in the correction step according to the eighth aspect, a pixel value Ca after correction of the display image may be derived based on the following equation (<NUM>).

In a tenth aspect of the present disclosure, according to the above aspects, it is preferable that the correction image is a single color image.

In an eleventh aspect of the present disclosure, according to the fifth and sixth aspects, it is preferable that the correction image is a <NUM>% gray image including four marks consisting of black squares having five pixels on each side as the alignment pattern.

In a twelfth aspect of the present disclosure, according to the fourth aspect, it is preferable that the constant A is <NUM> or more and <NUM> or less.

In a thirteenth aspect of the present disclosure, in the acquisition step according to the seventh aspect, the recorded image data is acquired at a resolution equal to or higher than the resolution of the image display device, thereafter in the derivation step, the correction coefficient K may be derived based on the recorded image data in which the resolution of the recorded image data is matched with the resolution of the image display device.

According to the above aspect, the information processing method according to the present disclosure can suppress unevenness of the recorded image.

Hereinafter, an information processing method according to an exemplary embodiment will be described with reference to the drawings.

First, a configuration of an image exposure device <NUM> used in the information processing method according to the present exemplary embodiment will be described. <FIG> shows an exploded perspective view of an example of the image exposure device <NUM>. Further, <FIG> shows a cross-sectional view of an example of the image exposure device <NUM>.

As shown in <FIG> and <FIG>, an image exposure device <NUM> comprises an image display device <NUM>, a support portion <NUM>, and a louver film <NUM>. The image display device <NUM> has a plurality of pixels <NUM>. The support portion <NUM> supports a photosensitive recording medium <NUM> on which a recorded image corresponding to a display image displayed by the image display device <NUM> is recorded. The louver film <NUM> is provided between the image display device <NUM> and the support portion <NUM>, and a protective layer <NUM> is provided on the support portion <NUM> side thereof.

As the image display device <NUM>, a mobile terminal such as a smartphone and a tablet PC, a liquid crystal display (LCD), an organic light emitting diode (OLED), a cathode ray tube (CRT), a light emitting diode (LED), a plasma display device, or the like can be used.

The image display device <NUM> comprises a plurality of pixels <NUM> as a display unit <NUM> for displaying a display image. <FIG> shows one pixel <NUM> as an example of the display unit <NUM>. The pixel <NUM> is a minimum unit of color information constituting an image display surface. Since the pixel <NUM> is provided, the image display device <NUM> can display a display image.

<FIG> shows an example of the pixel <NUM> according to the present exemplary embodiment. The pixel <NUM> includes three sub-pixels. Specifically, as shown in <FIG>, in the pixel <NUM>, a sub-pixel 13R corresponding to a red (R) color, a sub-pixel <NUM> corresponding to a green (G) color, and a sub-pixel 13B corresponding to a blue (B) color are disposed in a row. A plurality of pixels <NUM> are arranged two-dimensionally on a pixel display surface of the image display device <NUM>. Since the pixel <NUM> is provided, the image display device <NUM> can display a color display image.

The two-dimensional in the arrangement of the pixels <NUM> means a state extending in X-Y directions in <FIG>. By setting the distance (that is, pitch) between the adjacent pixels <NUM> to <NUM> or less, the impression of the recorded image as a natural image can be strengthened. Therefore, the pitch of the pixel <NUM> is preferably <NUM> or less, more preferably <NUM> or less, and even more preferably <NUM> or less.

A glass window <NUM> for protecting the pixel <NUM> is provided on a surface side irradiated with light from the image display device <NUM>. The thickness of the glass window <NUM> is preferably thin in order to shorten the distance from the pixel <NUM> to the photosensitive recording medium <NUM>.

The support portion <NUM> supports the photosensitive recording medium <NUM> in a state of being disposed at a position facing the surface irradiated with light from the image display device <NUM>. The support portion <NUM> may directly or indirectly support the photosensitive recording medium <NUM>, and the structure thereof is not particularly limited as long as the support portion <NUM> can support the photosensitive recording medium <NUM>.

As shown in <FIG>, the photosensitive recording medium <NUM> has an exposure surface 14A. The photosensitive recording medium <NUM> can be used without particular limitation as long as it is a recording medium that can be exposed to light emitted from the image display device <NUM> and can form a recorded image. For example, it is possible to use a film pack <NUM> or the like to be attached to an instant camera such as Instax (registered trademark), (trade name: Cheki) manufactured by Fujifilm Corporation.

The film pack <NUM> is formed by incorporating the photosensitive recording medium <NUM> into a case <NUM>. A light shielding sheet (not shown) is provided between a plurality of the photosensitive recording mediums <NUM> provided in the case <NUM> and only the photosensitive recording medium <NUM> present on the uppermost surface of the film pack <NUM> is exposed by the light shielding sheet. In a case where the film pack <NUM> to be attached to the Instax (registered trademark) is applied, the photosensitive recording medium <NUM> and the light shielding sheet are incorporated in the film. As a material used for the photosensitive recording medium <NUM>, for example, photographic light-sensitive materials such as a negative film, a reversal film, printing paper, and a mono-sheet or peel-apart type instant photographic film can be exemplified.

As shown in <FIG>, a plurality of photosensitive recording medium <NUM> is packed in a box-like case <NUM> having light shielding properties. In the case <NUM>, an exposure aperture <NUM> through which light emitted from the image display device <NUM> passes is provided in order to expose the exposure surface 14A of the photosensitive recording medium <NUM>. In addition, a pressing member (not shown) is provided on the side opposite to the exposure aperture <NUM>, and the photosensitive recording medium <NUM> is pressed toward the exposure aperture <NUM> side by using the pressing member. Therefore, the photosensitive recording medium <NUM> is pressed against the periphery of the exposure aperture <NUM>, the distance from the image display device <NUM> becomes close, and a favorable image can be recorded on the photosensitive recording medium <NUM>.

As the case <NUM>, a resin member for a recording material that is used for various recording materials such as a photographic light-sensitive material, a magnetic recording material, and an optical recording material can be used. The resin member for the recording material refers to a case, a lid, and an accessory supplemented thereto which are used to contain, pack, coat, protect, transport, or store the recording material, and support the form of the recording material or various members that mount the recording material and exhibit a function.

The photosensitive recording medium <NUM> after exposure passes through between developing rollers (not shown), whereby a pod portion provided in the photosensitive recording medium breaks. A development treatment liquid is encompassed in the pod portion, and the breakage of the pod portion causes the development treatment liquid to spread in the photosensitive recording medium <NUM>. After one to several minutes elapse, a development treatment is sufficiently advanced, and a recorded image is formed on the photosensitive recording medium <NUM>.

An example of the louver film <NUM> will be described with reference to <FIG> and <FIG>. <FIG> is a schematic cross-sectional view of an example of the image exposure device <NUM>, and is a view for describing a traveling direction of light from the pixel <NUM>. <FIG> is a diagram showing a configuration of an example of the louver film <NUM>. Reference numeral 16A denotes a planar surface 16A of the louver film <NUM>, and reference numeral 16B denotes a side surface 16B of the louver film <NUM>.

In the louver film <NUM>, light transmission parts <NUM> that transmit light and light shielding parts <NUM> that block light are alternately disposed in the first direction (X direction in the planar surface 16A in the example of <FIG>) on a surface parallel to an arrangement surface where the pixels <NUM> of the image display device <NUM> are arranged. In addition, in the louver film <NUM>, the light transmission parts <NUM> and the light shielding parts <NUM> are alternately disposed in the second direction (Y direction in the planar surface 16A in the example of <FIG>) perpendicular to the first direction on the surface parallel to the surface where the pixels of the image display device are arranged.

In this way, in the present exemplary embodiment, the light transmission parts <NUM> are two-dimensionally disposed, and the light shielding parts <NUM> are formed in a lattice form. With such a configuration, the louver film <NUM> can limit an angle of light emitted from the pixel <NUM> of the image display device <NUM> to the exposure surface 14A of the photosensitive recording medium <NUM>. The louver film <NUM> is an example of a limiting member of the present disclosure.

The light emitted from the pixel <NUM> of the image display device <NUM> is emitted in all directions of <NUM>° from an image display surface. The emitted light passes through the glass window <NUM> provided in the image display device <NUM> and is incident on the louver film <NUM>. In the light incident on the louver film <NUM>, light parallel to a straight line connecting the image display device <NUM> and the photosensitive recording medium <NUM> passes through the light transmission parts <NUM> of the louver film <NUM>. In addition, light emitted obliquely to the straight line connecting the image display device <NUM> and the photosensitive recording medium <NUM> is blocked by the light shielding parts <NUM> of the louver film <NUM>. In this way, by limiting the angle of the light emitted from the image display device <NUM>, the image quality of the recorded image recorded on the photosensitive recording medium <NUM> can be improved.

The light transmission parts <NUM> only need to be able to pass through light, and can be provided using a glass material, a transparent silicone rubber, or the like. In addition, portions of the light transmission parts <NUM> can be provided as cavities, and the louver film <NUM> can be composed of only the light shielding parts <NUM>.

The light shielding parts <NUM> may be a light absorbing member that absorbs light, or a light reflecting member that reflects light. A light shielding member <NUM> constituting the light shielding parts <NUM> can use a colored resin material such as a black silicone rubber, for example. In addition, as the material that absorbs light, a neutral density filter (ND filter) can be used. The ND filter means a filter having a neutral optical density, and can absorb light evenly in a wavelength region used for exposure without giving an influence on the wavelength (specifically, absorbance of <NUM>% or more and <NUM>% or less and/or light transmittance of <NUM>% or more and <NUM>% or less).

A width d of the adjacent light shielding parts <NUM> of the louver film <NUM> is preferably <NUM> or less, and more preferably <NUM> or less. In a case where the width d is set to be in the above-described range, it is possible to block obliquely emitted light in light emitted from the pixel <NUM>, and to improve the image quality of the recorded image.

A thickness t of the louver film <NUM> is preferably <NUM> or more and <NUM> or less, more preferably <NUM> or more and <NUM> or less, and still more preferably <NUM> or more and <NUM> or less. By increasing the thickness t of the louver film <NUM>, oblique light at a small angle with respect to parallel light can be blocked. In addition, in a case where the thickness t of the louver film <NUM> is increased, the recorded image is likely to be blurred and thus, the thickness t of the louver film <NUM> is preferably in the above-described range.

The protective layer <NUM> is provided on the photosensitive recording medium <NUM> side of the louver film <NUM> as shown in <FIG>, <FIG>. The protective layer <NUM> protects the louver film <NUM> in a case where the photosensitive recording medium <NUM> and the louver film <NUM> are in contact with each other during exposure. The protective layer <NUM> prevents the louver film <NUM> from being damaged or broken by repeated exposure of the display image displayed on the image display device <NUM> to the photosensitive recording medium <NUM>.

As the protective layer <NUM>, a transparent member capable of transmitting light can be used. For example, a plastic plate formed of an acrylic resin, a polycarbonate, a vinyl chloride resin, or the like can be used.

The thickness of the protective layer <NUM> is preferably <NUM> or more and <NUM> or less. In a case where the thickness of the protective layer <NUM> is set to <NUM> or more, it is possible to make moire inconspicuous in addition to the effect of protecting the louver film <NUM>. In addition, it is possible to make an image defect generated based on the defect or the structure of the louver film <NUM> inconspicuous. Further, in a case where the thickness of the protective layer <NUM> is set to <NUM> or less, it is possible to prevent the recorded image recorded on the photosensitive recording medium <NUM> from being blurred.

Incidentally, the width d between the adjacent light shielding parts <NUM> of the louver film <NUM> may not be constant due to manufacturing variation and the like. In addition, the position, number, degree, and the like where the variation appears may be different. <FIG> is a diagram showing a configuration of an example of the louver film <NUM> having variations in the width d between the light shielding parts <NUM>. <FIG> is a diagram showing a recorded image (a recorded image IMR in the example of <FIG>) obtained by exposing an image (a correction image IMC in the example of <FIG>) displayed on the image display device <NUM> to the photosensitive recording medium <NUM> by using the louver film <NUM> having variations in the width d between the light shielding parts <NUM>. <FIG> illustrates a case where a single color image is used as an image displayed on the image display device <NUM>.

In the louver film <NUM> having variations in the width between the light shielding parts <NUM> as shown in <FIG>, the angle of the light emitted from the pixel <NUM> of the image display device <NUM> to the exposure surface 14A of the photosensitive recording medium <NUM> cannot be uniformly limited, and the exposure surface 14A cannot be thus uniformly irradiated with the light. Therefore, the recorded image recorded on the photosensitive recording medium <NUM> using the louver film <NUM> having variations in the width between the light shielding parts <NUM> may have density unevenness and streak unevenness.

For example, in portions where the width between the light shielding parts <NUM> is narrow as in a width dn1 and a width dn2 shown in <FIG>, since less light can be transmitted than in a portion having a normal width d, the recorded image formed on the photosensitive recording medium <NUM> becomes dark as shown in P2 of <FIG>. Further, for example, in portions where the width between the light shielding parts <NUM> is wide as in a width dw1 and a width dw2 shown in <FIG>, since more light is transmitted than in a portion having a normal width d, the recorded image formed on the photosensitive recording medium <NUM> becomes bright as shown in P3 of <FIG>. Hereinafter, the density unevenness and the streak unevenness caused by the variation in the width between the light shielding parts <NUM> of the louver film <NUM> that occur in this recorded image are simply referred to as "unevenness".

In the information processing method according to the present exemplary embodiment, a correction coefficient K for performing a process of increasing (that is, brightening) the pixel value of the pixel <NUM> corresponding to a portion where dark unevenness appears in the recorded image in advance and of lowering (that is, darkening) the pixel value of the pixel <NUM> corresponding to a portion where bright unevenness appears in the recorded image is derived. According to such a process, unevenness of the recorded image can be suppressed even in the image exposure device <NUM> using the louver film <NUM> having variations in the width between the light shielding parts <NUM>. Hereinafter, the information processing method according to the present exemplary embodiment will be described.

First, an example of an information processing system <NUM> used in the information processing method according to the present exemplary embodiment will be described with reference to <FIG>. As shown in <FIG>, the information processing system <NUM> comprises an image display device <NUM>, a photosensitive recording medium <NUM>, and a reading device <NUM>. The image display device <NUM> comprises a display control unit <NUM>, a position modification unit <NUM>, a derivation unit <NUM>, and a correction unit <NUM> as a functional configuration. The reading device <NUM> may be any device capable of acquiring data of the recorded image recorded on the photosensitive recording medium <NUM> (hereinafter referred to as "recorded image data IMD"), and for example, a scanner and a camera equipped with an imaging element such as a charge coupled device (CCD) can be used.

Next, a hardware configuration of the image display device <NUM> will be described with reference to <FIG>. As shown in <FIG>, the image display device <NUM> comprises a central processing unit (CPU) <NUM>, a memory <NUM> as a temporary storage area, and a nonvolatile storage unit <NUM>. In addition, the image display device <NUM> comprises the display unit <NUM> described above and an input unit <NUM>. The CPU <NUM>, the memory <NUM>, the storage unit <NUM>, the input unit <NUM>, and the display unit <NUM> are connected via a bus <NUM>.

The display unit <NUM> comprises the above-described pixel <NUM> and radiates light according to the display image represented by the pixel <NUM>. For the display unit <NUM>, for example, a liquid crystal in which a lamp such as a backlight radiates light may be applied, or for example, a light emitting diode in which the display unit <NUM> itself radiates light may be applied.

The storage unit <NUM> is realized by a hard disk drive (HDD), a solid state drive (SSD), a flash memory, and the like. An image processing program <NUM> and a correction coefficient K are stored in the storage unit <NUM> as a storage medium. The CPU <NUM> reads the image processing program <NUM> from the storage unit <NUM>, loads the read image processing program <NUM> in the memory <NUM>, and then executes the image processing program <NUM>. In a case where the CPU <NUM> executes the image processing program <NUM>, the CPU <NUM> functions as the display control unit <NUM>, the position modification unit <NUM>, the derivation unit <NUM>, and the correction unit <NUM> shown in <FIG>.

Image data corresponding to the display image displayed on the display unit <NUM> is input to the input unit <NUM>. The image data corresponding to the display image may be input from the outside of the image display device <NUM>, or in a case where the image display device <NUM> or the image exposure device <NUM> has a function of forming or capturing an image, the image data formed or captured by the image display device <NUM> or the image exposure device <NUM> may be input. In addition, the recorded image data IMD acquired by the reading device <NUM> is input to the input unit <NUM>.

Next, with reference to <FIG>, the information processing method according to the present exemplary embodiment using the information processing system <NUM> will be described. <FIG> is a flowchart showing an example of each step included in the information processing method according to the present exemplary embodiment. <FIG> is a flowchart of an example of processes executed by the image display device <NUM> according to each step included in the information processing method according to the present exemplary embodiment. Hereinafter, each step included in the information processing method according to the present exemplary embodiment will be described with reference to <FIG>.

First, as shown in Step S10 of <FIG>, in the exposure step according to the present exemplary embodiment, the correction image IMC displayed on the image display device <NUM> is exposed to the photosensitive recording medium <NUM> via the louver film <NUM>. In the exposure step, the display control unit <NUM> performs control such that the correction image IMC as an example of the display image input to the input unit <NUM> is displayed on the display unit <NUM> (Step S20 in <FIG>). Accordingly, as shown in <FIG>, the recorded image IMR with unevenness is recorded on the photosensitive recording medium <NUM> supported by the image exposure device <NUM>.

As shown in <FIG>, the correction image IMC is preferably a single color image, and in particular, is more preferably a <NUM>% gray (specifically, in a case where the R color, the G color, and the B color have <NUM> gradations, the pixel values of the R color, the G color, and the B color are <NUM>) image. According to such a form, in the recorded image IMR, it can be seen that unevenness appears in the pixel having a pixel value deviating from the pixel value (that is, the reference pixel value Cs to be described later) corresponding to a predetermined pixel value of the correction image IMC. Therefore, in Step S16 of <FIG>, which will be described later, the correction coefficient K corresponding to the unevenness in the recorded image IMR can be accurately derived.

Further, it is preferable that the correction image IMC includes an alignment pattern PP. As an example, <FIG> illustrates a correction image IMC including four marks consisting of black squares having five pixels on each side as the alignment pattern PP. The alignment pattern PP may be any pattern as long as it can detect the position of the recorded image IMR in the recorded image data IMD, and for example, marks such as a rectangle, a circle, a cross, and the like can be applied. Since the correction image IMC includes the alignment pattern PP, even if the recorded image IMR included in the recorded image data IMD acquired in Step S12 of <FIG> is deformed, the deformation of the recorded image IMR can be modified in Step S14 (details will be described below).

Next, as shown in Step S12 of <FIG>, in the acquisition step according to the present exemplary embodiment, the recorded image data IMD, which is data of the recorded image IMR recorded on the photosensitive recording medium <NUM> through the exposure of the correction image IMC, is acquired. In the acquisition step, the reading device <NUM> acquires the data of the recorded image IMR (that is, the recorded image data IMD) as shown in <FIG> by reading the photosensitive recording medium <NUM> on which the recorded image IMR is recorded. Further, in the acquisition step, the image display device <NUM> receives the recorded image data IMD acquired by the reading device <NUM> via the input unit <NUM> (Step S22 in <FIG>).

The recorded image IMR indicated by the recorded image data IMD may be deformed in various ways such as rotation, distortion, bending, and size. For example, <FIG> shows an example in which the recorded image IMR is rotated and the recorded image data IMD includes a region other than the recorded image IMR, such as the film pack <NUM> and a margin.

As shown in Step S14 of <FIG>, in the modification step according to the present exemplary embodiment, the recorded image data IMD is modified based on the alignment pattern PP such that the position of the recorded image IMR indicated by the recorded image data IMD and the position of the correction image IMC match. Specifically, for each of the four alignment patterns PP, the recorded image data IMD is modified such that centroid coordinates of the alignment pattern PP included in the recorded image IMR indicated by the recorded image data IMD match centroid coordinates of the alignment pattern PP included in the correction image IMC.

In the modification step, the position modification unit <NUM> associates the alignment pattern PP of the recorded image IMR with the alignment pattern PP of the correction image IMC for each of the four alignment patterns PP. Further, the position modification unit <NUM> modifies the recorded image data IMD by performing predetermined image processing such that the centroid coordinates of the associated alignment patterns PP match each other (Step S24 in <FIG>). As the predetermined image processing, for example, various types of known image processing such as joint transformation, similarity transformation, affine transformation, projective transformation, and linear transformation can be applied. By these pieces of image processing, the recorded image IMR is subjected to deformation such as movement, rotation, enlargement, and reduction, and the pixels of the recorded image IMR can be associated with each pixel <NUM> of the image display device <NUM>. By such processing, as shown in <FIG>, the deformation of the recorded image IMR indicated by the recorded image data IMD can be modified.

Before describing the derivation step shown in Step S16 of <FIG>, the correction coefficient K derived in the derivation step will be described with reference to <FIG>, and <FIG>. <FIG> is a diagram showing pixel values for each pixel of the correction image IMC and the corrected display image IMA displayed on the display unit <NUM> of the image display device <NUM>. <FIG> is a diagram showing pixel values for each pixel of the recorded image IMR of the correction image IMC indicated by the recorded image data IMD and a recorded image IMR1 obtained by exposing the corrected display image IMA. <FIG> is a diagram showing an example of a display image IMB before correction represented by a pixel value Cb before correction, the corrected display image IMA represented by a pixel value Ca after correction, and the recorded image IMR1 obtained by exposing the corrected display image IMA to the photosensitive recording medium <NUM>. <FIG> illustrates a case where the display image IMB before correction is the same image as the correction image IMC.

As shown in <FIG>, the pixel value Cr of a portion P2 where the recorded image IMR becomes dark due to the variation in the width between the light shielding parts <NUM> of the louver film <NUM> is lower than the pixel value Cr of a portion P1 of normal brightness. Further, the pixel value Cr of a portion P3 where the recorded image IMR becomes dark due to the variation in the width between the light shielding parts <NUM> of the louver film <NUM> is higher than the pixel value Cr of the portion P1 of normal brightness.

Therefore, based on such a pixel value Cr for each pixel of the recorded image IMR, as shown in <FIG> and <FIG>, the display image IMA after correction is obtained, which is corrected such that unevenness of which brightness is complementary to unevenness due to the louver film <NUM> that occur in the recorded image IMR is included. "Unevenness of which brightness is complementary to unevenness that occur in the recorded image IMR" means the unevenness imparted to the corresponding portion of the display image IMA such that the portion brighter than the normal brightness is darker and the portion darker than the normal brightness is brighter, depending on the degree of deviation of the brightness portion that deviates from the normal brightness in the recorded image IMR. In the recorded image IMR1 obtained by exposing the corrected display image IMA corrected to include such unevenness, the unevenness included in the corrected display image IMA and the unevenness due to the louver film <NUM> are offset. Therefore, as shown in <FIG> and <FIG>, the pixel values of the portions P <NUM>, P2, and P3 can be made uniform. That is, in the recorded image IMR1 obtained by exposing the corrected display image IMA, the occurrence of unevenness can be suppressed.

The correction coefficient K is a coefficient for correcting the display image IMB before correction in order to obtain the corrected display image IMA such that the recorded image IMR1 in which the occurrence of unevenness is suppressed can be obtained. Specifically, the correction coefficient K is derived such that the pixel value Cr of the portion P2 where the recorded image IMR becomes dark is corrected to be higher than the pixel value Cr of the portion P1 of normal brightness and the pixel value Cr of the portion P3 where the recorded image IMR becomes bright is corrected to be lower than the pixel value Cr of the portion P <NUM> of normal brightness. That is, the correction coefficient K is derived for each pixel <NUM> of the image display device <NUM> according to the characteristics of the unevenness due to the louver film <NUM>. By using such a correction coefficient K, for the display image IMB before correction, the pixel value Cb of the portion P2 of the display image IMB before correction corresponding to the portion P2 where the recorded image IMR becomes dark can be corrected to be higher than the original pixel value and the pixel value Cb of the portion P3 of the display image IMB before correction corresponding to the portion P3 where the recorded image IMR becomes bright can be corrected to be lower than the original pixel value. Accordingly, it is possible to obtain the corrected display image IMA including unevenness of which brightness is complementary to unevenness due to the louver film <NUM>.

As shown in Step S16 of <FIG>, in the derivation step according to the present exemplary embodiment, the correction coefficient K is derived for each pixel <NUM> of the image display device <NUM> using the pixel value Cr for each pixel of the recorded image IMR and the reference pixel value Cs of the recorded image IMR, which are derived based on the recorded image data IMD modified in Step S14. In the derivation step, the derivation unit <NUM> performs a correction coefficient derivation process of deriving the correction coefficient K for each pixel <NUM> of the image display device <NUM> (Step S26 in <FIG>).

The details of the correction coefficient derivation process will be described with reference to <FIG> is a flowchart of an example of the correction coefficient derivation process. In Step S30, the derivation unit <NUM> calculates the average value of the pixel value Cr for each pixel of the recorded image IMR as the reference pixel value Cs.

In Step S32, the derivation unit <NUM> derives the correction coefficient K for each pixel of the recorded image IMR based on the following equation (<NUM>).

Here, A is a predetermined constant, and is preferably <NUM> or more and <NUM> or less. By setting the constant A to a value of <NUM> or more and <NUM> or less, the unevenness of the recorded image IMR1 recorded on the photosensitive recording medium <NUM> can be appropriately suppressed in a case where the pixel value Cb for each pixel of the display image IMB is corrected by using the correction coefficient K.

The constant A is not limited to the value in the above range, and any value may be used as long as it can suppress the unevenness of the recorded image IMR1 recorded on the photosensitive recording medium <NUM> in a case where the pixel value Cb for each pixel of the display image IMB is corrected by using the correction coefficient K. In addition, the constant A may be a uniform value for each pixel or may be a different value for each pixel.

In a case where the process of Step S32 is completed, the correction coefficient derivation process is completed. The correction coefficient K derived by the correction coefficient derivation process is stored in the storage unit <NUM> as shown in <FIG>.

Next, as shown in Step S18 of <FIG>, in the correction step according to the present exemplary embodiment, the pixel value Cb for each pixel of the display image IMB is corrected by using the correction coefficient K stored in the storage unit <NUM>. In the correction step, the correction unit <NUM> performs a display image correction process of correcting the pixel value Cb for each pixel of the display image IMB (Step S28 in <FIG>).

The details of the display image correction process will be described with reference to <FIG> is a flowchart of an example of the display image correction process. In Step S40 of <FIG>, the correction unit <NUM> acquires the display image IMB input to the input unit <NUM>. In Step S42, the correction unit <NUM> corrects the pixel value Cb for each pixel of the display image IMB. Specifically, the corrected pixel value Ca is derived for each pixel value Cb of the display image IMB based on the following equation (<NUM>).

In Step S44, the correction unit <NUM> causes the display control unit <NUM> to control to display the corrected display image IMA represented by the pixel value Ca derived in Step S42. In a case where the process of Step S44 is completed, the display image correction process is completed.

<FIG> is a diagram showing an example of a case where the above-mentioned display image correction process is performed on a display image IMB2 different from the correction image IMC. With the information processing method according to the present exemplary embodiment, as shown in <FIG>, even if the display image IMB2 has a different pixel value Cb for each pixel, the pixel value Cb can be appropriately corrected. Therefore, by exposing the photosensitive recording medium <NUM> using the display image IMA2 represented by the corrected pixel value Ca, unevenness of the recorded image IMR2 recorded on the photosensitive recording medium <NUM> can be suppressed.

As described above, the information processing method according to the present exemplary embodiment includes an exposure step of exposing the correction image IMC displayed on the image display device <NUM> having the plurality of pixels <NUM> to the photosensitive recording medium <NUM> via the louver film <NUM>, the limiting member being provided between the image display device <NUM> and the exposure surface 14A of the photosensitive recording medium <NUM> and limiting an angle of light emitted from the image display device <NUM> to the photosensitive recording medium <NUM>. Further, the information processing method according to the present exemplary embodiment includes an acquisition step of acquiring the recorded image data IMD, which is data of the recorded image IMR recorded on the photosensitive recording medium <NUM> through the exposure of the correction image IMC. Further, the information processing method according to the present exemplary embodiment includes a derivation step of deriving the correction coefficient K for correcting the pixel value Cb for each pixel of the display image based on the recorded image data IMD such that the display image including unevenness of which brightness is complementary to unevenness that occur in the recorded image IMR is displayed on the image display device <NUM>.

By using the correction coefficient K derived by the information processing method according to the present exemplary embodiment, a display image in which the pixel value Cb is corrected so as to offset the density unevenness and the streak unevenness caused by the variation in the width between the light shielding parts <NUM> of the louver film <NUM> can be displayed on the image display device <NUM>. Therefore, it is possible to suppress the unevenness of the recorded image obtained by exposing the display image displayed on the image display device <NUM> to the photosensitive recording medium <NUM>.

In the acquisition step in Step S12 of <FIG>, it is preferable to acquire the recorded image data IMD at a resolution equal to or higher than the resolution of the image display device <NUM>. Further, in a case where the resolution of the recorded image data IMD exceeds the resolution of the image display device <NUM>, in the derivation step in Step S12 of <FIG>, it is preferable that the resolution of the recorded image data IMD is matched with the resolution of the image display device <NUM>, and the correction coefficient K is derived based on the recorded image data IMD having the same resolution. By setting the resolution of the recorded image data IMD to be equal to or higher than the resolution of the image display device <NUM>, even a small unevenness that appears in only one pixel of the image display device <NUM> can be read. Therefore, the correction coefficient K can be derived with high accuracy.

In a case where the recorded image IMR indicated by the recorded image data IMD acquired in the acquisition step in Step S12 of <FIG> is not deformed in various ways such as rotation, distortion, bending, and size, the modification step in Step S14 may be omitted. In this case, in the derivation step of Step S16, the correction coefficient K may be derived based on the unmodified recorded image data IMD. Further, in this case, the correction image IMC may not include the alignment pattern PP.

Further, in the modification step of Step S14 of <FIG>, the recorded image data IMD may be modified such that the position of the recorded image IMR and the position of the correction image IMC match by using a known feature detection method such as an edge detection method. In this case, the correction image IMC may not include the alignment pattern PP.

Further, in the above exemplary embodiment, the form in which the image display device <NUM> comprises the position modification unit <NUM>, the derivation unit <NUM>, and the correction unit <NUM> has been described, but each of these may be configured by the image display device <NUM> and at least one other device. For example, the CPU of the smartphone as an example of the device different from the image display device <NUM> may function as the position modification unit <NUM> and the derivation unit <NUM> to derive the correction coefficient K. In this case, the correction coefficient K derived from the smartphone is stored in the storage unit <NUM> of the image display device <NUM>, and the image display device <NUM> corrects the pixel value Cb for each pixel of the display image IMB by using the correction coefficient K stored in the storage unit <NUM>. Further, for example, the CPU of the smartphone as an example of the device different from the image display device <NUM> may also function as the correction unit <NUM> to correct the display image IMB based on the derived correction coefficient K. In this case, the corrected display image IMA corrected by the smartphone is transmitted to the image display device <NUM>, and the image display device <NUM> displays the received display image IMA after the correction.

Further, the configuration of the louver film <NUM> is not limited to the form shown in <FIG>. <FIG> show configurations of another example of the louver film <NUM>.

The louver film <NUM> shown in <FIG> is composed of two layers of a first layer <NUM> and a second layer <NUM>. Reference numeral 16B denotes a side surface of the louver film <NUM>, reference numeral 118A denotes a planar surface of the first layer <NUM>, and reference numeral 119A denotes a planar surface of the second layer <NUM>. As shown in the planar surface 118A of the first layer <NUM>, in the first layer <NUM>, the light transmission parts <NUM> and the light shielding parts <NUM> are alternately disposed only in the first direction (X direction in the planar surface 118A in the example of <FIG>). In the second layer <NUM>, the light transmission parts <NUM> and the light shielding parts <NUM> are alternately disposed only in the second direction perpendicular to the first direction (Y direction in the planar surface 119A in the example of <FIG>). The first layer <NUM> and the second layer <NUM> are laminated to form a two-dimensional louver film <NUM>. Thus, even in a case where the two-dimensional louver film <NUM> is formed with a plurality of layers, the same effect as that of the louver film <NUM> formed of one layer can be obtained.

Further, as shown in <FIG>, the louver film <NUM> may have a form in which a protective layer <NUM> for preventing the louver film <NUM> from being damaged or broken is provided on the surface thereof. Specifically, the louver film <NUM> may have a form in which a protective layer <NUM> is provided on each of the planar surface 118A of the first layer <NUM> on the side opposite to the side in contact with the second layer <NUM> and the planar surface 119A of the second layer <NUM> on the side opposite to the side in contact with the first layer <NUM>.

The protective layer <NUM> is not particularly limited as long as it is transparent and can transmit light. For the protective layer <NUM>, for example, a plastic plate formed of an acrylic resin, a polycarbonate, a vinyl chloride resin, or the like can be used.

Further, as shown in <FIG>, at least one of the light shielding parts <NUM> in each column and each row may be composed of a plurality of light shielding members <NUM> having intervals. In the example shown in <FIG>, in the first layer <NUM>, each column of light shielding parts <NUM> arranged along the first direction has a plurality of light shielding members <NUM> provided at predetermined intervals along the second direction. In the second layer <NUM>, each row of light shielding parts <NUM> arranged along the second direction has a plurality of light shielding members <NUM> provided at predetermined intervals along the first direction.

In a case where the film is formed of a plurality of layers such as two layers of the first layer <NUM> and the second layer <NUM> as in the louver film <NUM> shown in <FIG>, the total thickness of the plurality of layers is the thickness t of the louver film <NUM>.

The light shielding parts <NUM> may be disposed with a difference in an angle between XY axes of the pixel as a reference for the arrangement of the pixel <NUM> and an angle between XY axes of the louver as the reference for the arrangement of the light transmission parts <NUM> and the light shielding parts <NUM> of the louver film <NUM>. Moire of the recorded image IMR is suppressed by disposing the pixel <NUM> with the difference in the angle between the XY axes of the pixel <NUM> and the XY axes of the louver. The difference of the angle is preferably <NUM> degree to <NUM> degrees, more preferably <NUM> degrees to <NUM> degrees, and even more preferably <NUM> degrees to <NUM> degrees.

Further, the structure of the louver film <NUM> is not limited to the <FIG> and <FIG>, and may be any limiting member capable of limiting the angle of the light emitted from the image display device <NUM>. For example, the light transmission parts <NUM> and the light shielding parts <NUM> may be disposed aperiodically, and a capillary plate or the like in which holes are randomly formed may be used as the limiting member.

In the above exemplary embodiments, a mode in which each of the plurality of pixels <NUM> of the image display device <NUM> comprises sub-pixels 13R, <NUM>, and 13B to display a color image on the image display device <NUM> has been described, but the configuration of the image display device <NUM> for displaying the color image is not limited to this mode. For example, the image display device <NUM> may be provided with a light source or a filter corresponding to each of the R component, the G component, and the B component.

Further, as hardware structures of processing units that execute various kinds of processing such as each functional unit of the image display device <NUM> in the above exemplary embodiments, various processors shown below can be used. As described above, the various processors include a programmable logic device (PLD) as a processor of which the circuit configuration can be changed after manufacture, such as a field-programmable gate array (FPGA), a dedicated electrical circuit as a processor having a dedicated circuit configuration for executing specific processing such as an application specific integrated circuit (ASIC), and the like, in addition to the CPU as a general-purpose processor that functions as various processing units by executing software (program).

One processing unit may be configured by one of the various processors, or configured by a combination of the same or different kinds of two or more processors (for example, a combination of a plurality of FPGAs or a combination of the CPU and the FPGA). In addition, a plurality of processing units may be configured by one processor. As an example where a plurality of processing units are configured by one processor, first, there is a form in which one processor is configured by a combination of one or more CPUs and software as typified by a computer, such as a client or a server, and this processor functions as a plurality of processing units. Second, as represented by a system on chip (SoC) or the like, there is a form of using a processor for realizing the function of the entire system including a plurality of processing units with one integrated circuit (IC) chip. In this way, various processing units are configured by one or more of the above-described various processors as hardware structures.

Furthermore, as the hardware structure of the various processors, more specifically, an electrical circuit (circuitry) in which circuit elements such as semiconductor elements are combined can be used.

In the above exemplary embodiment, the image processing program <NUM> is described as being stored (installed) in the storage unit <NUM> in advance; however, the present disclosure is not limited thereto. The image processing program <NUM> may be provided in a form recorded in a recording medium such as a compact disc read only memory (CD-ROM), a digital versatile disc read only memory (DVD-ROM), and a universal serial bus (USB) memory. In addition, the image processing program <NUM> may be downloaded from an external device via a network.

Claim 1:
An information processing method comprising:
an exposure step (S10) of exposing a correction image (IMC) displayed on an image display device (<NUM>) having a plurality of pixels to a photosensitive recording medium (<NUM>) via a limiting member (<NUM>), the limiting member (<NUM>) being provided between the image display device (<NUM>) and an exposure surface of the photosensitive recording medium (<NUM>) and limiting an angle of light emitted from the image display device (<NUM>) to the photosensitive recording medium (<NUM>);
an acquisition step (S12) of acquiring recorded image data (IMD), which is data of a recorded image (IMR) recorded on the photosensitive recording medium (<NUM>) through the exposure of the correction image (IMC); and
a derivation step (S16) of deriving a correction coefficient K for correcting a pixel value for each pixel of a display image (IMA) for each pixel (<NUM>) of the image display device (<NUM>) based on the recorded image data (IMD) such that the display image including unevenness of which brightness is complementary to unevenness that occur in the recorded image is displayed on the image display device, characterised in that
wherein in the derivation step (S16), the correction coefficient K is derived using a pixel value Cr for each pixel of the recorded image and a reference pixel value Cs of the recorded image, which are derived based on the recorded image data, and
wherein in the derivation step, in a case where a predetermined constant is denoted by A, the correction coefficient K is derived based on the following equation (<NUM>), <MAT>