A method of augmenting reality of an image, comprising providing a lenticular lens for viewing an image, wherein the image is a lenticular image comprising at least two interlaced images. At least two fiducial markers are provided in the image. A first sensor located at a first distance from the image detects a first fiducial marker, and a second sensor located at a second distance from the image detects a second fiducial marker, wherein the detection of the each of the first and the second fiducial markers triggers a computing process delivering augmented reality to a user via a screen. The second distance is closer to the image than the first distance, and the second fiducial marker is capable of being detected by the second sensor from the second distance, but not from the first distance.

A method of augmenting reality of an image, comprising providing a lenticular lens for viewing an image, wherein the image is a lenticular image comprising at least two interlaced images. At least two fiducial markers are provided in the image. A first sensor located at a first distance from the image detects a first fiducial marker, and a second sensor located at a second distance from the image detects a second fiducial marker, wherein the detection of the each of the first and the second fiducial markers triggers a computing process delivering augmented reality to a user via a screen. The second distance is closer to the image than the first distance, and the second fiducial marker is capable of being detected by the second sensor from the second distance, but not from the first distance.

A method of augmenting reality of a physical image, comprising the receiving of a demand from a user by a receptor to create an augmented image from information about the physical image and about a digital component to be linked to the physical image. The information is organized according to at least one classification by the receptor, which sends the information to a production tracker for process distribution. The information is tested to ensure the digital component is functioning properly and is compatible with the physical image. The physical image is manufactured, and then blended with the digital component into the augmented image, and finally delivered to the user.

A method of augmenting reality of a physical image, comprising the receiving of a demand from a user by a receptor to create an augmented image from information about the physical image and about a digital component to be linked to the physical image. The information is organized according to at least one classification by the receptor, which sends the information to a production tracker for process distribution. The information is tested to ensure the digital component is functioning properly and is compatible with the physical image. The physical image is manufactured, and then blended with the digital component into the augmented image, and finally delivered to the user.

A method of augmenting reality of a physical garment, comprising the receiving of a demand from a user by a receptor to create an augmented garment from information about the physical garment and about a digital component to be linked to the physical garment. The information is organized according to at least one classification by the receptor, which sends the information to a production tracker for garment process distribution. The information is tested to ensure the digital component is functioning properly and is compatible with the physical garment. The physical garment is manufactured, and then blended with the digital component into the augmented garment, and finally delivered to the user.

A lenticular display includes a lenticular image including an image strip group in which display image strips that are respectively extracted in the form of a stripe from a plurality of display images are arrayed adjacently to each other in their respective corresponding positions, and in which an interpolation image strip is disposed between display image strips that are adjacent to each other, that are extracted from different display images, and that have different colors in at least a portion thereof, the interpolation image strip having a color that is in between the color of one of the adjacent display image strips and the color of the other of the adjacent display image strips.

A systematic approach to producing multi-dimensional photon images on a computer platform having applications to a plurality of input image(s) from various sources, and applications to coordinate and adjust numerous variables which determine the quality of the image, such as the size of the imported images, the output image size, the resolving power of the viewing screen and the width of the resolving elements, the dots per inch of the output device (or pixels per inch), the desired nearest object, the desired furthest object and the determination of the central or the key subject, rules of interphasing, the number of frames or layers, the minimum parallax, and the maximum parallax, and, thus, provide a digital multi-dimensional image without jumping images or fuzzy features or other visual distortions by creating high quality output images both in the form of a printed hardcopy or as a viewed image on an appropriate viewing device. The digital multi-dimensional image platform based system controls the position and path of light from the original object to the human visual system.

A systematic approach to producing multi-dimensional photon images on a computer platform having applications to a plurality of input image(s) from various sources, and applications to coordinate and adjust numerous variables which determine the quality of the image, such as the size of the imported images, the output image size, the resolving power of the viewing screen and the width of the resolving elements, the dots per inch of the output device (or pixels per inch), the desired nearest object, the desired furthest object and the determination of the central or the key subject, rules of interphasing, the number of frames or layers, the minimum parallax, and the maximum parallax, and, thus, provide a digital multi-dimensional image without jumping images or fuzzy features or other visual distortions by creating high quality output images both in the form of a printed hardcopy or as a viewed image on an appropriate viewing device. The digital multi-dimensional image platform based system controls the position and path of light from the original object to the human visual system.

A lenticular display includes a lenticular image including an image strip group in which display image strips that are respectively extracted in the form of a stripe from a plurality of display images are arrayed adjacently to each other in their respective corresponding positions, and in which an interpolation image strip is disposed between display image strips that are adjacent to each other, that are extracted from different display images, and that have different colors in at least a portion thereof, the interpolation image strip having a color that is in between the color of one of the adjacent display image strips and the color of the other of the adjacent display image strips.

A method for a production of a lenticular image. The method comprises feeding a lenticular printing substrate having a corrugated side and a printing side into a digital printing press, feeding at least one nontransparent ink to set a substantially nontransparent layer on a printing blanket of the printing press, feeding a plurality of colored inks to set an interlaced color image layer on top of the substantially nontransparent layer on the printing blanket, and printing with the printing blanket onto the printing side.