CN115457574B - Visual information processing method based on preset distance and visual information carrier - Google Patents
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- 230000000007 visual effect Effects 0.000 title claims abstract description 62
- 230000010365 information processing Effects 0.000 title claims description 30
- 238000003672 processing method Methods 0.000 title claims description 15
- 238000012545 processing Methods 0.000 claims abstract description 111
- 239000000178 monomer Substances 0.000 claims abstract description 105
- 239000000758 substrate Substances 0.000 claims abstract description 20
- 230000007613 environmental effect Effects 0.000 claims description 14
- 230000000694 effects Effects 0.000 abstract description 19
- 239000000463 material Substances 0.000 abstract description 4
- 238000000034 method Methods 0.000 abstract description 4
- 238000012937 correction Methods 0.000 abstract description 3
- 230000035772 mutation Effects 0.000 abstract description 3
- 230000002269 spontaneous effect Effects 0.000 abstract description 3
- 239000010410 layer Substances 0.000 description 122
- 239000003086 colorant Substances 0.000 description 7
- 238000005286 illumination Methods 0.000 description 4
- 241001465754 Metazoa Species 0.000 description 2
- 241000282320 Panthera leo Species 0.000 description 2
- 238000007796 conventional method Methods 0.000 description 2
- 238000010586 diagram Methods 0.000 description 2
- 208000001491 myopia Diseases 0.000 description 2
- 230000004379 myopia Effects 0.000 description 2
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- 210000003710 cerebral cortex Anatomy 0.000 description 1
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- 238000012986 modification Methods 0.000 description 1
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- 239000002356 single layer Substances 0.000 description 1
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- G06V30/10—Character recognition
- G06V30/24—Character recognition characterised by the processing or recognition method
- G06V30/242—Division of the character sequences into groups prior to recognition; Selection of dictionaries
- G06V30/244—Division of the character sequences into groups prior to recognition; Selection of dictionaries using graphical properties, e.g. alphabet type or font
- G06V30/2445—Alphabet recognition, e.g. Latin, Kanji or Katakana
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06V—IMAGE OR VIDEO RECOGNITION OR UNDERSTANDING
- G06V30/00—Character recognition; Recognising digital ink; Document-oriented image-based pattern recognition
- G06V30/10—Character recognition
- G06V30/24—Character recognition characterised by the processing or recognition method
- G06V30/242—Division of the character sequences into groups prior to recognition; Selection of dictionaries
- G06V30/244—Division of the character sequences into groups prior to recognition; Selection of dictionaries using graphical properties, e.g. alphabet type or font
- G06V30/245—Font recognition
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06V—IMAGE OR VIDEO RECOGNITION OR UNDERSTANDING
- G06V30/00—Character recognition; Recognising digital ink; Document-oriented image-based pattern recognition
- G06V30/40—Document-oriented image-based pattern recognition
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Abstract
The invention relates to the technical field of visual information, in particular to visual information and a carrier based on a preset distance, wherein the visual information comprises a background layer and an information layer; the background layer comprises a basic state and a processing state, and the information layer comprises a basic state, a body processing state and a boundary processing state; the background layer basic state comprises a substrate with a preset size, and the processing state comprises a substrate with a plurality of meaning changing areas; the basic state of the information layer comprises monomers, the body processing state comprises changing monomers of the main body structure of the monomers, the changing monomers are inserted into the deliberate area, and the boundary processing state comprises processing monomers with virtual boundaries and unchanged main body structures of the monomers. The invention solves the problems that the prior method for inserting the mutation region in the monomer to realize the spontaneous correction of the eye distance has poor effect when being applied to a printing body with a smaller character size, can not be applied to a printed paper reading material, and can not judge the adjustment range and limit of the eye distance for a user.
Description
Technical Field
The invention relates to the technical field of visual information, in particular to a visual information processing method based on a preset distance and a visual information carrier.
Background
The visual information is information which can be received by the retina of a person and then transmitted to the cerebral cortex for processing, and finally forms a picture perceived by the person. Visual information is typically displayed on tangible media (e.g., newspapers, magazines, books, signs) either permanently or electronically, and the display may be text, symbols, pictures, or a combination thereof. The most effective means of preventing myopia are generally to improve eye distance, shorten near eye time, etc.
Based on the technical means of the prior patent (application number 202110460715.5), the prior visual information enables a user to see the image clearly within a preset distance due to the existence of the image in a short distance by inserting the image on a single body, and further automatically adjusts the distance between eyes.
However, this method is not effective when applied to a print of a small size, and cannot be applied to an already printed paper reading material, and the range and limit of adjustment of the eye distance cannot be determined for the user.
Accordingly, a visual information processing method based on a preset distance and a carrier of visual information have been developed.
Disclosure of Invention
The invention aims to provide a visual information processing method based on a preset distance and a visual information carrier, which mainly solve the problems that the conventional method of inserting a mutation area in a single body to realize spontaneous correction of the eye distance has poor effect when the method is applied to a printing body with a smaller word size, cannot be applied to a printed paper reading material, and cannot judge the adjustment range and limitation of the eye distance for a user.
The invention provides a visual information processing method based on a preset distance, which comprises a background layer and an information layer; the background layer comprises a basic state and a processing state, and the information layer comprises a basic state, an entity processing state and a boundary processing state; the visual information comprises at least one of a processing state of the background layer, an bulk processing state of the information layer and a boundary processing state of the information layer;
the basic state of the background layer comprises a substrate with a preset size, and the processing state comprises the substrate with a plurality of meaning areas;
the basic state of the information layer comprises a monomer, the body processing state comprises a changing monomer of which the main body structure is inserted with a plurality of redirection regions, the boundary processing state comprises a processing monomer of which the boundary is virtual and the main body structure of the monomer is maintained unchanged;
the processing state of the background layer enables the original background layer to be formed with a plurality of meaning changing areas, the existence of the meaning changing areas can influence a user to acquire the meaning of a monomer within a preset distance, or the meaning of the monomer is changed, so that the user must spontaneously adjust the reading distance until the meaning changing areas can be clearly identified, understood and acquired when the existence of the meaning changing areas can be ignored; the processing state of the information layer enables the boundary of the monomer to be virtual or the monomer to be inserted into the redirection region, so that the current monomer cannot be known by a user within a preset distance, and the user must adjust the reading distance spontaneously until the processing structure can be ignored to obtain the meaning of the monomer again;
the carrier of the visual information comprises a physical medium and an electronic medium;
wherein the redirection regions are calculated as,;
the region of interest is calculated as,
y is defined as the size of a single redirecting area on the monomer; s is defined as the nature of the monomer; e is defined as an environmental parameter; m is defined as a visual information carrier parameter; i is defined as a property parameter of the metameric region; alpha is defined as a shape adjustment parameter; x is defined as the size of a single ideographic region on the background layer processing state; l is defined as the nature of the monomer; b is defined as the nature of the substrate; n is defined as an environmental parameter; d is defined as a visual information carrier parameter; g is defined as a redirection region property parameter; beta is defined as the shape adjustment parameter.
More specifically, the property S of the monomer is the color, definition, size of the monomer;
the environmental parameter E is the color temperature, the intensity, the irradiation direction and the irradiation mode of the environmental light;
the visual information carrier parameter M is paper medium or electronic medium, and the lower the background light intensity of the visual information carrier is, the larger the M value is;
the property parameter I of the meaning changing area is larger when the meaning changing area is not easy to identify;
the shape adjusting parameter alpha is larger when the shape of the metameric region is not smooth;
the property L of the monomer is the color, definition and size of the monomer;
the property B of the substrate is the color, definition and size of the substrate;
the environmental parameter N is the color temperature, the intensity, the irradiation direction and the irradiation mode of the environmental light;
the visual information carrier parameter D is paper medium or electronic medium, and the lower the background light intensity of the visual information carrier is, the larger the D value is;
the redirection region property parameter G is larger when the redirection region is not easy to identify;
the shape adjustment parameter β, the greater the β value when the shape of the redirecting area is less smooth.
Preferably, the background layer comprises a background treatment layer and a background base layer; the background treatment layer comprises a treatment state of the background layer, and the background base layer comprises a basic state of the background layer;
the information layer comprises an information processing layer and an information base layer; the information processing layer comprises at least one of an ontology processing state and a boundary processing state of the information layer, and the information base layer comprises a basic state of the information layer;
the visual information includes at least one of the background processing layer and the information processing layer.
Preferably, all the regions of varying meaning include four properties of image, size, shape, and distribution; all the redirection regions comprise four properties of image, size, shape and distribution.
Preferably, all of the regions of variability are distributed outside the monomer.
Preferably, in all the regions of varying significance, the images of any two regions of varying significance are consistent or inconsistent;
in all the disagreeable areas, the sizes of any two disagreeable areas are consistent or inconsistent;
and in all the meaning changing areas, the shapes of any two meaning changing areas are consistent or inconsistent.
Preferably, in all the redirecting areas, the images of any two redirecting areas are consistent or inconsistent;
any two of the redirection regions are consistent or inconsistent in size;
any two of the redirecting areas are identical or inconsistent in shape.
The invention also provides a paper carrier and an electronic carrier, wherein the carrier is carried with the visual information.
From the above, the technical scheme provided by the invention can obtain the following beneficial effects:
firstly, the boundary of the information layer is virtual, so that the meaning of a monomer is changed in the safety eye distance, and therefore, a user can ignore the processing state on the background layer and the processing part on the processing state on the information layer only after adjusting to the safety eye distance, and the meaning of the monomer is known again, thereby effectively ensuring the user to correct the reading distance spontaneously, knowing the distance range and the limit and realizing the safety eye;
secondly, the technical scheme provided by the invention can be used for superposing three modes of the processing state of the background layer, the boundary processing state of the information layer and the body processing state of the information layer, so that any one, any two and any plurality of effects can be reserved, the effects can be selected according to the actual application environment, the size of a monomer and the like as required, and the correcting effect of visual information on the safety eye distance is greatly improved.
Drawings
In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.
FIG. 1 is a diagram showing one of the processing effects of "one" of Chinese characters in an embodiment of the present invention;
FIG. 2 is a diagram showing another processing effect of "one" of Chinese characters according to an embodiment of the present invention;
FIG. 3 shows one of the processing effects of the letter "A" in an embodiment of the present invention.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It will be apparent that the described embodiments are merely some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without any inventive effort, are intended to be within the scope of the invention.
The conventional method is to insert a mutation region in a single body to realize spontaneous correction of the eye distance, but the method has poor effect when applied to a print body with a smaller character size, cannot be applied to printed paper reading materials, and cannot judge the problem of the adjustment range and limitation of the eye distance for a user.
In order to solve the above-mentioned problems, the present embodiment proposes a visual information processing method based on a preset distance, which mainly includes a background layer and an information layer; the background layer comprises a basic state and a processing state, and the information layer comprises a basic state, a body processing state and a boundary processing state; the visual information includes at least one of a processing state of the background layer, an bulk processing state of the information layer, and a boundary processing state of the information layer.
The background layer comprises a substrate with a preset size in a basic state, and the processing state comprises a substrate with a plurality of meaning changing areas; the basic state of the information layer comprises a monomer, the body processing state comprises a plurality of changing monomers with a plurality of redirection regions inserted in the main structure of the monomer, and the boundary processing state comprises a processing monomer with a virtual boundary and a unchanged main structure of the monomer.
Preferably, for the physical medium, the monomers on the information layer in this embodiment are Chinese characters, letters, numbers and images, and the background layer is a printing, printing and etching substrate such as paper and plastic; for electronic media, the information layer in this embodiment is a display screen, a screen, or a projection substrate, and the background layer is a Chinese character, letter, number, image, or video.
Preferably, but not limited to, the boundary blurring on the boundary processing state in this embodiment specifically means that when the monomer is a Chinese character, the boundary is defined as a stroke boundary, that is, blurring is performed on the stroke boundary; when the monomer is a letter, the boundary is defined as the boundary of the letter stroke, i.e., the boundary of the letter stroke is blurred.
In this embodiment, the processing state of the background layer makes the original background layer form a plurality of meaning changing areas, and the existence of the meaning changing areas affects the user to learn the meaning of the monomer within a preset distance, or changes the meaning of the monomer, so the user must spontaneously adjust the reading distance until the meaning changing areas can be clearly identified, understood and learned when the existence of the meaning changing areas is negligible; similarly, the processing state of the information layer causes the boundary of the monomer to be virtual or the monomer to be inserted into the redirection region, that is, the current monomer cannot be known by the user within the preset distance, so that the user also needs to adjust the reading distance spontaneously until the processing structure can be ignored and the meaning of the monomer can be known again; further, when the above two modes are superimposed, the above effect can also be achieved.
In this embodiment, the visual information has the following processing results: a. superposition display of the basic state of the background layer and the boundary processing state of the information layer; b. the basic state of the background layer and the body processing state of the information layer are displayed in a superposition way; c. the basic state of the background layer and the boundary processing state of the information layer are displayed in a superposition way; d. the processing state of the background layer and the basic state of the information layer are displayed in a superposition way; e. superposition display of the processing state of the background layer and the boundary processing state of the information layer; f. the superposition display of the processing state of the background layer and the body processing state of the information layer; g. and superposing and displaying the processing state of the background layer, the boundary processing state of the information layer and the body processing state of the information layer.
In the above processing result b/c/f/g, the redirection region of the changing monomer is a preset shape, and the redirection region of the filling image is specifically calculated as follows:
;
wherein y is defined as the size of a single redirecting area on the monomer; s is defined as the nature of the monomer; e is defined as an environmental parameter; m is defined as a visual information carrier parameter; i is defined as a property parameter of the metameric region; alpha is defined as the shape adjustment parameter.
Where S generally refers to the color, clarity, size, etc. properties of the monomer. The greater the value of S, the clearer the monomer and the greater the area occupied; e generally refers to the color temperature, intensity, direction of illumination, and manner of illumination of the ambient light. The value of E is greater when the light intensity is lower; m generally refers to a carrier of visual information, either paper or electronic, and the value of M is greater as the intensity of background light provided by the visual information carrier is lower; i generally refers to the comprehensive nature of the region of interest, the greater the value of I when the region of interest is less easily identified and seen; alpha generally refers to the shape parameter of the redirection regions. The larger the value of alpha when the shape of the redirection regions is less smooth.
In this embodiment, the distribution of the redirecting areas has a relationship with the monomer properties and the distribution of the preset redirecting areas, while the distribution results of the redirecting areas are not unique. For example: when the monomer is '1', the redirection regions are transversely distributed along the left side and the right side of the '1', and the redirection regions are also transversely distributed on the left side and the right side, so that the treatment effects of the redirection regions and the redirection regions can be well fused.
In this embodiment, the shape of the redirecting area has a relationship with the monomer property and the shape and distribution of the preset redirecting area, and the shape of the redirecting area is not unique. For example: when the monomer is 1, the changing region is circular, or is elliptical or the like, so that the processing effects of the changing region and the changing region can be well fused.
In this embodiment, the image of the redirection region is related to the nature of the monomer, the actual requirements of the application, and the image of the redirection region, while the image of the redirection region is not unique.
Preferably, in d/e/f/g of the foregoing processing result, the region of interest of the background layer in the processing state is a preset shape, and the region of interest of the filled image is specifically calculated as follows:
;
wherein x is defined as the size of a single region of varying meaning on the background layer processing state; l is defined as the nature of the monomer; b is defined as the nature of the substrate; n is defined as an environmental parameter; d is defined as a visual information carrier parameter; g is defined as a redirection region property parameter; beta is defined as the shape adjustment parameter.
Where L generally refers to the color, clarity, size, etc. properties of the monomer. The greater the value of L, the more clear the monomer and the greater the area occupied; b generally refers to the color, clarity, size, etc. properties of the substrate. The greater the value of B when the substrate is clearer and the occupied area is larger; n generally refers to the color temperature, intensity, direction of illumination, and manner of illumination of the ambient light. The value of N is greater as the intensity of light is lower; d generally refers to a carrier of visual information, either paper or electronic, with a larger value for D as the intensity of the background light provided by the visual information carrier is lower; g generally refers to the comprehensive nature of the redirection regions, the greater the value of G when the redirection regions are less easily identified and seen; beta generally refers to the shape parameter of the region of interest. The larger the value of beta when the shape of the region of interest is less smooth.
In this embodiment, the distribution of the deliberate regions is related to the nature of the monomer, the actual requirements of the application, and the distribution of the deliberate regions, while the distribution of the deliberate regions is not unique. The combination of the regions of variation and the monomer may be preset as various desired, satisfactory images of which the monomer is a part. When the preset distance is within, the correct meaning of the monomer cannot be judged and known, only the unified and specific meaning of the combined image can be understood and identified, and when the preset distance is outside, the specific and real meaning of the monomer can be correctly identified and known. For example, for the Chinese character "one", the region of variation and the Chinese character "one" may be intentionally combined into the number "1", and at this time, the Chinese character "one" becomes a part of the number "1". The meaning-changing area and the Chinese character 'one' can be intentionally combined into the animal image 'lion', and then the Chinese character 'one' forms a part of the animal image 'lion'. The specific image which is formed by combining the changing region and the monomer is required to be specifically and comprehensively considered according to the aspects of the characteristics of users, the actual requirements, the economic factors and the like. For example, for the Chinese character "one", the meaning-changing region may be set on the upper and lower sides of "one", on the left and right sides, or in a fully enclosed form, so that "one" is completely enclosed. For a normally printed book, the left-right side spacing between words is generally smaller than the segment spacing between segments, so for a case where the word spacing is dense, the meaning-changing area is generally set on the upper and lower sides, or is a background area with a large space around the word. Specifically, when the redirection regions are longitudinally distributed in the monomer, the redirection regions are longitudinally distributed according to actual conditions, so that the treatment effects of the redirection regions and the redirection regions can be well fused.
In this embodiment, the shape of the deliberate region is related to the nature of the monomer, the actual requirements of the application, and the shape of the deliberate region, while the shape of the deliberate region is not unique. For example, for Chinese character "one", according to actual calculation and experiment, when the redirection region adopts the shape formed by the arc line, the myopia prevention effect is better, and correspondingly, the redirection region also adopts the arc shape such as a circle or an ellipse. Ensuring that the treatment effect of the change region and the change region can be well fused.
In this embodiment, the image of the deliberate area is related to the nature of the monomer, the actual requirement of the application, the combination of the deliberate areas, the preset image of the monomer and the image of the deliberate area, and the image of the deliberate area is not unique.
More specifically, the background layer includes a background treatment layer and a background base layer; the background treatment layer comprises a treatment state of the background layer, and the background base layer comprises a basic state of the background layer; the information layer comprises an information processing layer and an information base layer; the information processing layer comprises at least one of an ontology processing state and a boundary processing state of the information layer, and the information base layer comprises a basic state of the information layer; the visual information includes at least one of a background processing layer and an information processing layer.
In this embodiment, if the processing state of the information layer is a boundary processing state, that is, the boundary of the monomer is virtual, the superposition of the information processing layer and the information base layer is necessarily adopted, that is, the boundary virtual processing is performed on the monomer on the information processing layer, while the information base layer remains unchanged, and the effect of the information processing layer is directly displayed after superposition, that is, the monomer is processed; if the processing state of the information layer in the embodiment is the body processing state, a redirection region can be directly added on the information layer, or the information processing layer with the redirection region is selected for superposition display; in summary, if the information layer processing state in this embodiment is the superposition display of the body processing state and the boundary processing state, the information processing layer is selected, and the information processing layer has both the processing monomer with the virtual boundary and the changing monomer inserted into the redirection region, and the final display result is that the boundary of the monomer is virtual, and the monomer body is inserted into the redirection region.
In this embodiment, there are two processing modes for the processing state of the background layer, one is to insert the redirection region directly on the background layer, and the mode can be directly performed on the single-layer structure; and secondly, a substrate layer with a changeable area is newly added, namely a background treatment layer is newly added, and the background layer treatment state on the background treatment layer is displayed after superposition.
More specifically, all the regions of varying meaning include four properties of image, size, shape, and distribution; all the redirecting areas comprise four properties of images, sizes, shapes and distribution modes.
In this embodiment, the user may set the properties of the changing region and the changing region in advance according to the properties of the background layer or the area ratio of the background layer and the information layer, the color image difference, and the like, and generate visual information according to the set changing region and changing region. Preferably, in this embodiment, the changing area and the changing area may be set to be solid colors, or may be set to be images, specifically may be selected by the user, or may be adjusted by the electronic device.
Preferably, all of the regions of variation are distributed outside the monomer.
In this embodiment, all of the regions of variability are distributed outside the cell, i.e., the visual information is displayed as the regions of variability are disposed around the cell, or on the remaining background outside the cell.
Preferably, in all the regions of varying meaning in the processing state of the background layer, the images of any two regions of varying meaning are consistent or inconsistent; in all the meaning changing areas on the processing state of the background layer, the sizes of any two meaning changing areas are consistent or inconsistent; any two of the regions of varying significance in the treated state of the background layer are identical or inconsistent in shape.
Preferably, but not limited to, the images, sizes, and shapes of all the regions of variation may be different, for example, the images, sizes, and shapes of the regions of variation closest to the single body are the same, and the images, sizes, and shapes of the remaining regions of variation are the same, that is, there are two or more regions of variation in the background layer processing state, and the regions of variation in adjacent layers are different from each other as they change from the region of variation closest to the single body to the distant region.
In the present embodiment, the region of interest may be set as an image, but for convenience of explanation, one of the special cases is as follows: the metameric area is analyzed and illustrated as a solid color patch. Preferably, but not limited to, all the meaning-changing areas comprise meaning-changing areas with the same or similar colors as the colors of the monomers, the colors with the same hue, purity and brightness as the colors of the current meaning-changing areas can be selected, and the colors with the similar hue, purity and brightness as the colors of the current meaning-changing areas can be selected, so long as the meaning of the monomers can be identified outside the preset distance; the color of the color-changing region is different from that of the monomer, namely, the color which belongs to different hues, purities and brightness with the monomer is selected.
Preferably, the images of any two redirection regions are consistent or inconsistent in all redirection regions on the information layer processing state; in all redirection regions in the information layer processing state, the sizes of any two redirection regions are consistent or inconsistent; any two redirection regions in the information layer processing state are identical or inconsistent in shape.
Preferably, but not limited to, the images, sizes, shapes of all of the redirecting areas may be identical, or may be completely different, or may be partially identical, for example, the images, sizes, shapes of a plurality of redirecting areas on the unitary body are identical, and the images, sizes, shapes of a plurality of redirecting areas on the unitary body near the boundary are identical, and are different from the redirecting areas on the unitary body.
In addition, if the information layer processing state shows a boundary processing state, the boundary blurring degree of the processing unit in the boundary processing state changes outwards from the center of the unit, and the change trend of the boundary blurring degree of the processing unit is from low to high. The default background layer is usually a light layer, such as white, and the default monomer is dark, such as black, so that the change trend of the boundary blurring degree of the monomer is from low to high, i.e. the boundary color of the processing monomer is from dark to light in the embodiment.
In this embodiment, after the boundary of the processing monomer is weakened, the boundary should be fused to the background layer or be close to the color of the background layer, so that no obvious boundary exists between the boundary of the processing monomer after the blurring and the background layer, the sharpening degree of the boundary can be considered to be gradually reduced, and the effect that the user knows the meaning of the monomer is further affected by the boundary blurring within a preset distance.
In summary, according to the visual information processing method based on the preset distance provided in this embodiment, the meaning of the monomer is effectively affected by the single effect display and the multi-effect superposition display within the preset distance mainly by performing the interpenetration of the meaning changing area on the background layer or the operation of boundary blurring and the interpenetration of the monomer main body on the monomer, and the reading distance is required to be spontaneously adjusted to achieve the effect of learning the meaning of the monomer.
It should be emphasized that the carrier on which the visual information is mounted also falls within the scope of the present embodiment. If the visual information in the embodiment is a printed matter, books and papers with the printed matter belong to the protection scope of the embodiment; in addition, the decal provided with only the deliberate area and the deliberate area should also belong to the protection scope of the present embodiment, for example, after the decal is superimposed on the printed matter, the decal is displayed as a background layer processing state and an information layer body processing state, that is, the decal is equivalent to directly printing the visual information in the present embodiment.
The above-described embodiments do not limit the scope of the present invention. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the above embodiments should be included in the scope of the present invention.
Claims (8)
1. A visual information processing method based on a preset distance is characterized by comprising the following steps of: comprises a background layer and an information layer; the background layer comprises a basic state and a processing state, and the information layer comprises a basic state, an entity processing state and a boundary processing state; the visual information comprises at least one of a processing state of the background layer, an bulk processing state of the information layer and a boundary processing state of the information layer;
the basic state of the background layer comprises a substrate with a preset size, and the processing state comprises the substrate with a plurality of meaning areas;
the basic state of the information layer comprises a monomer, the body processing state comprises a changing monomer of which the main body structure is inserted with a plurality of redirection regions, the boundary processing state comprises a processing monomer of which the boundary is virtual and the main body structure of the monomer is maintained unchanged;
the processing state of the background layer enables the original background layer to be formed with a plurality of meaning changing areas, the existence of the meaning changing areas can influence a user to acquire the meaning of a monomer within a preset distance, or the meaning of the monomer is changed, so that the user must spontaneously adjust the reading distance until the meaning changing areas can be clearly identified, understood and acquired when the existence of the meaning changing areas can be ignored; the processing state of the information layer enables the boundary of the monomer to be virtual or the monomer to be inserted into the redirection region, so that the current monomer cannot be known by a user within a preset distance, and the user must adjust the reading distance spontaneously until the processing structure can be ignored to obtain the meaning of the monomer again;
the carrier of the visual information comprises a physical medium and an electronic medium;
wherein, the redirection region is calculated as y is less than or equal to 1mm 2 *S*E*M*I*α;
The meaning-changing area is calculated as x is more than or equal to 1mm 2 *L*B*N*D*G*β;
y is defined as the size of a single redirecting area on the monomer; s is defined as the nature of the monomer; e is defined as an environmental parameter; m is defined as a visual information carrier parameter; i is defined as a property parameter of the metameric region; alpha is defined as a shape adjustment parameter; x is defined as the size of a single ideographic region on the background layer processing state; l is defined as the nature of the monomer; b is defined as the nature of the substrate; n is defined as an environmental parameter; d is defined as a visual information carrier parameter; g is defined as a redirection region property parameter; beta is defined as the shape adjustment parameter.
2. The visual information processing method based on a preset distance according to claim 1, wherein:
the property S of the monomer is the color, definition and size of the monomer;
the environmental parameter E is the color temperature, the intensity, the irradiation direction and the irradiation mode of the environmental light;
the visual information carrier parameter M is paper medium or electronic medium, and the lower the background light intensity of the visual information carrier is, the larger the M value is;
the property parameter I of the meaning changing area is larger when the meaning changing area is not easy to identify;
the shape adjusting parameter alpha is larger when the shape of the metameric region is not smooth;
the property L of the monomer is the color, definition and size of the monomer;
the property B of the substrate is the color, definition and size of the substrate;
the environmental parameter N is the color temperature, the intensity, the irradiation direction and the irradiation mode of the environmental light;
the visual information carrier parameter D is paper medium or electronic medium, and the lower the background light intensity of the visual information carrier is, the larger the D value is;
the redirection region property parameter G is larger when the redirection region is not easy to identify;
the shape adjustment parameter β, the greater the β value when the shape of the redirecting area is less smooth.
3. The visual information processing method based on a preset distance according to claim 1, wherein:
the background layer comprises a background treatment layer and a background base layer; the background treatment layer comprises a treatment state of the background layer, and the background base layer comprises a basic state of the background layer;
the information layer comprises an information processing layer and an information base layer; the information processing layer comprises at least one of an ontology processing state and a boundary processing state of the information layer, and the information base layer comprises a basic state of the information layer;
the visual information includes at least one of the background processing layer and the information processing layer.
4. A visual information processing method based on a preset distance according to claim 1 or 3, characterized in that: all the metamorphic regions comprise four properties of images, sizes, shapes and distribution modes; all the redirection regions comprise four properties of image, size, shape and distribution.
5. The visual information processing method based on a preset distance according to claim 4, wherein: all of the regions of variability are distributed outside of the monomer.
6. The visual information processing method based on a preset distance according to claim 4, wherein:
in all the disagreeable areas, the images of any two of the disagreeable areas are consistent or inconsistent;
in all the disagreeable areas, the sizes of any two disagreeable areas are consistent or inconsistent;
and in all the meaning changing areas, the shapes of any two meaning changing areas are consistent or inconsistent.
7. The visual information processing method based on a preset distance according to claim 4, wherein:
in all the redirection regions, the images of any two redirection regions are consistent or inconsistent;
any two of the redirection regions are consistent or inconsistent in size;
any two of the redirecting areas are identical or inconsistent in shape.
8. A paper carrier or electronic carrier, characterized by: the visual information according to any one of claims 1 to 7 is mounted on the carrier.
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