An article is authenticated by providing a magnetic security mark in the form of an optically-passive randomly-generated nanoscale magnetic pattern. The pattern is pre-imaged and this reference image is uploaded to a secure database along with an identifier for the article such as a serial number. A user of the article verifies its authenticity by scanning it magnetically to obtain a scanned image of the magnetic pattern. The serial number is used to retrieve the previously uploaded reference image which is compared to the scanned image. If the images match, the article's authenticity is confirmed. A single article may have multiple magnetic security marks, each unique, placed at predetermined, non-uniform locations. The magnetic patterns are generated using thin film deposition of yttrium iron garnet. In one embodiment the article is a physical key having additional security features, such as mechanical features and a radio-frequency identification chip.

An article is authenticated by providing a magnetic security mark in the form of an optically-passive randomly-generated nanoscale magnetic pattern. The pattern is pre-imaged and this reference image is uploaded to a secure database along with an identifier for the article such as a serial number. A user of the article verifies its authenticity by scanning it magnetically to obtain a scanned image of the magnetic pattern. The serial number is used to retrieve the previously uploaded reference image which is compared to the scanned image. If the images match, the article's authenticity is confirmed. A single article may have multiple magnetic security marks, each unique, placed at predetermined, non-uniform locations. The magnetic patterns are generated using thin film deposition of yttrium iron garnet. In one embodiment the article is a physical key having additional security features, such as mechanical features and a radio-frequency identification chip.

A method and system for automatically verifying the authenticity of documents is provided. The method has: scanning a document to be verified in the visible and ultraviolet light spectrum; detecting in the scanned document digital watermarks printed with visible and ultraviolet ink; decrypting the marks, thereby obtaining an ultraviolet mark identifier and a variable data mark identifier; validating the percentage of the mark by checking for the presence of the digital watermark in different areas of the scanned document; comparing the mark identifiers obtained with mark identifiers stored in a database; and determining the validity of the document on the basis of the comparison. The invention allows the validity of the data printed in the document to be checked automatically, reducing the possibility of the undetected falsification, modification or total or partial alteration of a document.

A method and system for automatically verifying the authenticity of documents is provided. The method has: scanning a document to be verified in the visible and ultraviolet light spectrum; detecting in the scanned document digital watermarks printed with visible and ultraviolet ink; decrypting the marks, thereby obtaining an ultraviolet mark identifier and a variable data mark identifier; validating the percentage of the mark by checking for the presence of the digital watermark in different areas of the scanned document; comparing the mark identifiers obtained with mark identifiers stored in a database; and determining the validity of the document on the basis of the comparison. The invention allows the validity of the data printed in the document to be checked automatically, reducing the possibility of the undetected falsification, modification or total or partial alteration of a document.

A multilayered optical security device has a resonant waveguide grating (RWG) layer on an under layer having a hologram. The RWG layer has plural RWGs for generating one or more patterns. Each RWG has first and second RWG portions, with diffraction gratings of different grating periods, for light coupling-in and coupling-out, respectively. Using the RWGs minimizes interference to a holographic image generated by the under layer. This advantage is especially useful when the holographic image carries digital data such as in digital holographic encryption where an encrypted hologram is used in the under layer. The digital data may contain biometric information such as a fingerprint. In each RWG portion of an individual RWG, scattering elements in a grating are curved to thereby enhance an angular tolerance in azimuthal angle during observing the patterns by an observer while the individual RWG is still selective in elevation angle.

A multilayered optical security device has a resonant waveguide grating (RWG) layer on an under layer having a hologram. The RWG layer has plural RWGs for generating one or more patterns. Each RWG has first and second RWG portions, with diffraction gratings of different grating periods, for light coupling-in and coupling-out, respectively. Using the RWGs minimizes interference to a holographic image generated by the under layer. This advantage is especially useful when the holographic image carries digital data such as in digital holographic encryption where an encrypted hologram is used in the under layer. The digital data may contain biometric information such as a fingerprint. In each RWG portion of an individual RWG, scattering elements in a grating are curved to thereby enhance an angular tolerance in azimuthal angle during observing the patterns by an observer while the individual RWG is still selective in elevation angle.

An article is authenticated by providing a magnetic security mark in the form of an optically-passive randomly-generated nanoscale magnetic pattern. The pattern is pre-imaged and this reference image is uploaded to a secure database along with an identifier for the article such as a serial number. A user of the article verifies its authenticity by scanning it magnetically to obtain a scanned image of the magnetic pattern. The serial number is used to retrieve the previously uploaded reference image which is compared to the scanned image. If the images match, the article's authenticity is confirmed. A single article may have multiple magnetic security marks, each unique, placed at predetermined, non-uniform locations. The magnetic patterns are generated using thin film deposition of yttrium iron garnet. In one embodiment the article is a physical key having additional security features, such as mechanical features and a radio-frequency identification chip.

An article is authenticated by providing a magnetic security mark in the form of an optically-passive randomly-generated nanoscale magnetic pattern. The pattern is pre-imaged and this reference image is uploaded to a secure database along with an identifier for the article such as a serial number. A user of the article verifies its authenticity by scanning it magnetically to obtain a scanned image of the magnetic pattern. The serial number is used to retrieve the previously uploaded reference image which is compared to the scanned image. If the images match, the article's authenticity is confirmed. A single article may have multiple magnetic security marks, each unique, placed at predetermined, non-uniform locations. The magnetic patterns are generated using thin film deposition of yttrium iron garnet. In one embodiment the article is a physical key having additional security features, such as mechanical features and a radio-frequency identification chip.

The present disclosure relates to signal processing such as image processing, signal encoding, digital watermarking and data hiding. One claim recites a method including: capturing imagery corresponding to a printed object with a red or blue illumination source, the red or blue illumination source having an illumination wavelength at or around 660 nm or an illumination wavelength in the range of 60 nm centered around 460 nm, said capturing imagery yielding captured data; wherein the printed object includes a clear coat printed thereon, the clear coat including a material that has a peak absorbance at or around 660 nm or in the range of 60 nm centered around 460 nm, the clear coat printed in a manner to convey an encoded plural-bit message, the encoded plural-bit message corresponding to product information; analyzing the captured data with one or more programmed multi-core processors to decode the encoded plural-bit message, said analyzing yielding the product information; and providing the product information as an output. Of course, other claims, technology and combinations are disclosed.

There is provided systems and methods for generating a multi-layered watermark. The watermark incorporating one or more symbols for placement on a document. The method including: positioning a base layer of the watermark at one or more locations on the document; positioning the one or more symbols overtop of at least a portion of the base layer; and positioning a braid layer of the watermark overtop of the ID, the braid layer and the base layer are substantially aligned, the braid layer including a copy of the base layer incorporating a pattern. The pattern can include one or more of discolorations, holes, and sections of increased opacity.