Provided is a stereoscopic image forming method for forming a color stereoscopic image on a recording medium having a thermal expansion property, the stereoscopic image forming method including the steps of: fixing a color image on the thermally expandable recording medium using a color material; and irradiating the fixed color image with light of a light source having a maximum emission wavelength in a wavelength range of 280 to 780 nm that is absorbed by a compound contained in the color material to generate heat of the compound.

Provided is a stereoscopic image forming method for forming a color stereoscopic image on a recording medium having a thermal expansion property, the stereoscopic image forming method including the steps of: fixing a color image on the thermally expandable recording medium using a color material; and irradiating the fixed color image with light of a light source having a maximum emission wavelength in a wavelength range of 280 to 780 nm that is absorbed by a compound contained in the color material to generate heat of the compound.

There is provided a decorative sheet which has excellent heat-shielding properties and excellent substrate-concealing properties and which enables easy adjustment of a dark color tone. The decorative sheet includes an infrared-reflective substrate, and a decorative layer disposed on the substrate and including a solid printing layer and a picture layer, wherein the solid printing layer contains an infrared-transparent or infrared-reflective inorganic pigment and a binder resin, and the picture layer contains at least three compounds selected from the organic pigment group consisting of a quinacridone, an isoindolinone, a nickel azo complex and a phthalocyanine, and a binder resin.

A method for manufacture of a digitally printed decorative surfacing material includes applying a textured layer upon a substrate, processing a digital image to compensate for additional surface area provided by the textured layer so as to produce a resultant digital image, digitally printing the resultant digital image upon the textured layer, applying a top coat layer over the digitally printed image. A digitally printed decorative surfacing material in accordance with the method described above is also provided.

A method for manufacture of a digitally printed decorative surfacing material includes applying a textured layer upon a substrate, processing a digital image to compensate for additional surface area provided by the textured layer so as to produce a resultant digital image, digitally printing the resultant digital image upon the textured layer, applying a top coat layer over the digitally printed image. A digitally printed decorative surfacing material in accordance with the method described above is also provided.

Provided is a manufacturing method for a printed matter including a medium and a three-dimensional pattern printed on a surface of the medium. The three-dimensional pattern has a partly-coated resin portion and further has layers including a colored layer and clear layers formed on the colored layer. The three-dimensional pattern is formed by stacking the layers formed of inks at least containing resin on one another. One of the clear layers formed on an outermost surface of the three-dimensional pattern is flattened for a longer duration than at least one of the other one of the clear layers and the colored layer that are formed below the clear layer on the outermost surface, so that the one of the clear layers on the outermost surface is further flattened than at least one of the other one of the clear layers and the colored layer.

Provided is a manufacturing method for a printed matter including a medium and a three-dimensional pattern printed on a surface of the medium. The three-dimensional pattern has a partly-coated resin portion and further has layers including a colored layer and clear layers formed on the colored layer. The three-dimensional pattern is formed by stacking the layers formed of inks at least containing resin on one another. One of the clear layers formed on an outermost surface of the three-dimensional pattern is flattened for a longer duration than at least one of the other one of the clear layers and the colored layer that are formed below the clear layer on the outermost surface, so that the one of the clear layers on the outermost surface is further flattened than at least one of the other one of the clear layers and the colored layer.

A camouflage system adaptively matches the visible and IR spectrum of surrounding vegetation. A bio-chromophore dye solution circulated through an upper channel and distributed by a pulp or fabric matches the visible and biological IR spectrum, while water evaporated from the upper channel or from a separate lower channel matches the water IR spectrum. Dye can be retained in the pulp or continuously circulated. Permanently printed colors and/or patterns can also be included. Petalation cooperative with a channel flow pattern can release evaporated water and inhibit LiDAR detection. An upper waxy layer and surface embossing can avoid specular reflections. The camouflage signature can be compared with the environment and automatically adjusted as needed. Embodiments include thermal management, electromagnetic shielding, and/or radar scattering/absorbing subsystems. An airbag ground plane can match a terrain contour and avoid LiDAR detection. Multiple zones can provide adaptive display of visible and IR patterns.

A camouflage system adaptively matches the visible and IR spectrum of surrounding vegetation. A bio-chromophore dye solution circulated through an upper channel and distributed by a pulp or fabric matches the visible and biological IR spectrum, while water evaporated from the upper channel or from a separate lower channel matches the water IR spectrum. Dye can be retained in the pulp or continuously circulated. Permanently printed colors and/or patterns can also be included. Petalation cooperative with a channel flow pattern can release evaporated water and inhibit LiDAR detection. An upper waxy layer and surface embossing can avoid specular reflections. The camouflage signature can be compared with the environment and automatically adjusted as needed. Embodiments include thermal management, electromagnetic shielding, and/or radar scattering/absorbing subsystems. An airbag ground plane can match a terrain contour and avoid LiDAR detection. Multiple zones can provide adaptive display of visible and IR patterns.

A structure forming method of present invention includes a first step including forming a first pattern serving as a fine pattern using an electromagnetic wave thermal conversion material on a first surface, on the side on which an expansion layer which expands by heating is provided, of a medium including the expansion layer and then irradiating an electromagnetic wave toward the electromagnetic wave thermal conversion material to expand a portion, corresponding to the first pattern, of the expansion layer, and a second step including forming a second pattern including a coarser pattern than the first pattern using an electromagnetic wave thermal conversion material on a second surface, on the opposite side to the side on which the expansion layer is provided, of the medium and then irradiating an electromagnetic wave toward the electromagnetic wave thermal conversion material to expand a portion, corresponding to the second pattern, of the expansion layer.