A system (100) and a method for marking a product (10) utilize an encoding that specifies the presence or absence of each of a plurality of luminescent materials, at least one of which exhibits a predetermined decay behavior. The decay behavior of a plurality of different materials is detected, and based thereon the presence or absence of the luminescent materials is inferred. A corresponding encoding specifies whether or not the respective materials are present. In this way, different encodings can be associated in advance with different properties of the product (10). The luminescent materials that specify the associated encoding can be applied to the product (10) as a mark (20) in accordance with a determined property of the product (10).

Techniques for manufacturing a light field print using a printing press. The techniques include: identifying at least one characteristic of the printing press at least in part by printing at least one calibration pattern; obtaining content to be rendered using the light field print, the content comprising multiple scene views; generating, based at least in part on the content and the at least one characteristic of the printing press, a front target pattern and a back target pattern; and using the printing press to: print the front target pattern on a first side of a substrate; and print the back target pattern on a second side of the substrate.

The present invention is based on a method for marking products using two or more ink formulations, each containing one or more photoluminescent dyes emitting radiation in the range of 380-3000 nm under photon excitation and distinguished by different fluorescence lifetimes, for storing information in serialization and/or track & trace systems and for document security.

The present invention provides a UV-Vis radiation curable security ink for producing a security feature for securing value documents, wherein said security feature exhibits a blue color upon viewing in transmitted light and a metallic yellow color upon viewing in incident light. The UV-Vis radiation curable security ink comprises a cationically curable or a hybrid curable ink vehicle, and silver nanoplatelets bearing a surface stabilizing agent of general formula (I)

##STR00001## wherein the residue R.sup.A is a C.sub.2-C.sub.4alkyl group substituted with a hydroxy group; the residue R.sup.B is selected from a C.sub.1-C.sub.4 alkyl group, and a C.sub.2-C.sub.4alkyl group substituted with a hydroxy group; and Cat.sup.+ is a cation selected from the group consisting of Na.sup.+, K.sup.+, Cs.sup.+ and Rb.sup.+.

Security element including a first and second pattern formed by a first and second material respectively in or on a first and a second region of a substrate respectively, the first pattern partially overlapping with said second pattern, the first material comprising a first luminescent dye, which upon excitation by electromagnetic radiation falling within its excitation wavelength range emits electromagnetic radiation in a first emission wavelength range, the second material comprising a second luminescent dye, which upon excitation by electromagnetic radiation falling within its excitation wavelength range emits electromagnetic radiation in a second emission wavelength range, said first emission wavelength range overlapping with the excitation wavelength range of the second luminescent dye, so that upon irradiation within the excitation wavelength range of the first luminescent dye the second luminescent dye is excited, in the overlapping area of the patterns, to emit electromagnetic radiation in the emission wavelength range.

An intaglio printing ink includes capsule luminescent pigments and a further machine-readable feature substance. The capsule luminescent pigments include at least one core with a luminescent substance and one shell encapsulating the at least one core. They are characterized by their high luminescence intensity and high chemical stability, which enables a simultaneous loading of the intaglio printing ink with a further machine-readable feature. A printing method and a printed product include the intaglio printing ink.

A printing system receives a print request containing patterns of marks to be printed on print media to produce printed output. A processor evaluates the print request to identify non-marking areas and identify different printing densities of the patterns of marks. The processor alters the patterns of marks to create hidden features on the printed output by adding a uniform printed background to the non-marking areas and adding different printing densities of fluorescent spots to different areas of the patterns of marks. The different printing densities of the fluorescent spots are based on the different printing densities of the patterns of marks and on the size of the hidden features. A printing device prints the print request on the print media to produce the printed output.

A system (100) and a method for marking a product (10) utilize an encoding that specifies the presence or absence of each of a plurality of luminescent materials, at least one of which exhibits a predetermined decay behavior. The decay behavior of a plurality of different materials is detected, and based thereon the presence or absence of the luminescent materials is inferred. A corresponding encoding specifies whether or not the respective materials are present. In this way, different encodings can be associated in advance with different properties of the product (10). The luminescent materials that specify the associated encoding can be applied to the product (10) as a mark (20) in accordance with a determined property of the product (10).

Disclosed is a device and process for marking and detecting labels with spectral band authentication features utilizing a reader that can be affixed to a smart phone and positioned so as to align the lens of the phone's camera with a reader aperture. The reader aperture allows the camera to view an item through a spacer, wherein a UV and IR light source is used to reveal indicia within invisible ink. The light source employs a distinct emission spectrum characterized by narrow peaks and gaps which can illuminate pigment of the invisible ink that is selectively responsive at the wavelengths of specific peaks and/or unresponsive at the gaps in the spectrum. The smart phone captures the indicia revealed and interfaces with a cloud-based database to provide verification of authenticity.

A printing system receives a print request containing patterns of marks to be printed on print media to produce printed output. A processor evaluates the print request to identify different printing densities of the patterns of marks. The processor alters the patterns of marks to create hidden features on the printed output by adding different printing densities of fluorescent spots to different areas of the patterns of marks. The different printing densities of the fluorescent spots are based on the different printing densities of the patterns of marks and on the size of the hidden features. A printing device prints the print request on the print media to produce the printed output.