Abstract: A system for Augmented Reality (AR) document generation receives a request to generate an AR document with a particular amount directed to a particular receiver. The AR document comprises an AR check. The system generates a unique code for the AR check by converting a name of a sender, a name of the particular receiver, the amount, and a serial number associated with the AR check into a hexadecimal format. The system generates the AR check by taking the unique code as an input and writing the name of the sender, name of the particular receiver, the amount, and the serial number on the AR check extracted from the unique code. The system transmits an image of the AR check to a computing device associated with the particular receiver.

Abstract: An Augmented Reality (AR)-enabled Automated Teller Machine (ATM) receives a request to dispense cash equal to amount of an AR document. The AR document comprises an AR check. The AR-enabled ATM fetches a first AR check image from a memory. The AR-enabled ATM extracts a first set of features from the first AR check image. The AR-enabled ATM receives a second AR check image from a computing device associated with the receiver. The AR-enabled ATM extracts a second set of features from the second AR check image. The AR-enabled ATM compares the first AR check image with the second AR check image. The AR-enabled ATM determines whether the first AR check image corresponds to the second AR check image. In response to determining that the first AR check image corresponds to the second AR check image, the AR-enabled ATM dispenses cash equal to the amount.

Abstract: An Augmented Reality (AR)-enabled Automated Teller Machine (ATM) receives a request to dispense cash equal to amount of an AR document. The AR document comprises an AR check. The AR-enabled ATM fetches a first AR check image from a memory. The AR-enabled ATM extracts a first set of features from the first AR check image. The AR-enabled ATM receives a second AR check image from a computing device associated with the receiver. The AR-enabled ATM extracts a second set of features from the second AR check image. The AR-enabled ATM compares the first AR check image with the second AR check image. The AR-enabled ATM determines whether the first AR check image corresponds to the second AR check image. In response to determining that the first AR check image corresponds to the second AR check image, the AR-enabled ATM dispenses cash equal to the amount.

Abstract: An implantable optical sensor (1) comprising a substrate (2) and at least one optical microstructure (3) for evanescent field sensing integrated with the substrate (2), the at least one optical microstructure (3) being positioned to form an optical interaction area (4) on a part of a surface (5) of the substrate (2), the optical assembly (1) further comprising a thin protective layer (6) covering at least the optical interaction area (4), the thin protective layer (6) being in a predetermined material with corrosion-protection characteristics and having a predetermined thickness, so as not to affect the evanescent field sensing.

Abstract: An Augmented Reality (AR)-enabled Automated Teller Machine (ATM) receives a request to dispense cash equal to amount of an AR document. The AR document comprises an AR check. The AR-enabled ATM fetches a first AR check image from a memory. The AR-enabled ATM extracts a first set of features from the first AR check image. The AR-enabled ATM receives a second AR check image from a computing device associated with the receiver. The AR-enabled ATM extracts a second set of features from the second AR check image. The AR-enabled ATM compares the first AR check image with the second AR check image. The AR-enabled ATM determines whether the first AR check image corresponds to the second AR check image. In response to determining that the first AR check image corresponds to the second AR check image, the AR-enabled ATM dispenses cash equal to the amount.

Abstract: A system for Augmented Reality (AR) document generation receives a request to generate an AR document with a particular amount directed to a particular receiver. The AR document comprises an AR check. The system generates a unique code for the AR check by converting a name of a sender, a name of the particular receiver, the amount, and a serial number associated with the AR check into a hexadecimal format. The system generates the AR check by taking the unique code as an input and writing the name of the sender, name of the particular receiver, the amount, and the serial number on the AR check extracted from the unique code. The system transmits an image of the AR check to a computing device associated with the particular receiver.

Abstract: A system for Augmented Reality (AR) document realization receivers a request to transfer an amount of an AR document into account of a receiver. The AR document comprises an AR check. The system fetches a first AR check image from a memory. The system extracts a first set of features from the first AR check image. The system receives a second AR check image from a computing device associated with the receiver. The system extracts a second set of features from the second AR check image. The system compares the first AR check image with the second AR check image. The system determines whether the first AR check image corresponds to the second AR check image. In response to determining that the first AR check image corresponds to the second AR check image, the system transfers the amount into the account of the receiver.

Abstract: A method for testing an optical assembly (1) which has an optical microstructure (3) integrated with a substrate (2). The optical microstructure (3) is positioned to form an external optical interaction area (4) on a part of a surface (5) of the substrate (2). A cover cap (6) seals at least a part of the surface (5) of the substrate (2) adjacent to the optical microstructure (3) to obtain a sealed cavity (9). An optical feedthrough (10) is integrated in the substrate (2) to form an external communication path from within the sealed cavity (9). The optical feedthrough (10) allows communication of a physical parameter value which is measured inside the sealed cavity (9) to outside the sealed cavity (9). The physical parameter value is associated with a measure of hermeticity of the sealed cavity (9).

Abstract: A method for testing an optical assembly (1) which has an optical microstructure (3) integrated with a substrate (2). The optical microstructure (3) is positioned to form an external optical interaction area (4) on a part of a surface (5) of the substrate (2). A cover cap (6) seals at least a part of the surface (5) of the substrate (2) adjacent to the optical microstructure (3) to obtain a sealed cavity (9). An optical feedthrough (10) is integrated in the substrate (2) to form an external communication path from within the sealed cavity (9). The optical feedthrough (10) allows communication of a physical parameter value which is measured inside the sealed cavity (9) to outside the sealed cavity (9). The physical parameter value is associated with a measure of hermeticity of the sealed cavity (9).

Abstract: An implantable optical sensor (1) comprising a substrate (2) and at least one optical microstructure (3) for evanescent field sensing integrated with the substrate (2), the at least one optical microstructure (3) being positioned to form an optical interaction area (4) on a part of a surface (5) of the substrate (2), the optical assembly (1) further comprising a thin protective layer (6) covering at least the optical interaction area (4), the thin protective layer (6) being in a predetermined material with corrosion-protection characteristics and having a predetermined thickness, so as not to affect the evanescent field sensing.

Abstract: An on-chip broadband radiation source, and methods for its manufacture such that a photonics IC comprises an optical waveguide such as a semiconductor waveguide, a thin III-V material membrane with absorption capability for absorbing an optical pump signal induced in the waveguide. The III-V membrane comprises a LED implemented therein. The photonics IC also comprises a coupling means between the waveguide and the membrane. The device provides a broadband radiation source at a wavelength longer than the wavelength of the transferred radiation. The broadband signal can then be coupled out through the waveguide and used in the chip.

Abstract: An on-chip broadband radiation source, and methods for its manufacture such that a photonics IC comprises an optical waveguide such as a semiconductor waveguide, a thin III-V material membrane with absorption capability for absorbing an optical pump signal induced in the waveguide. The III-V membrane comprises a LED implemented therein. The photonics IC also comprises a coupling means between the waveguide and the membrane. The device provides a broadband radiation source at a wavelength longer than the wavelength of the transferred radiation. The broadband signal can then be coupled out through the waveguide and used in the chip.

Abstract: In the present invention, a molecular analysis device comprises a substrate, and a waveguide with a planar integrating element and filter or reflector element adjacent thereto is disposed on the substrate. The waveguide comprises a coupling means configured for coupling a predetermined frequency range of laser radiation into the waveguide. At least one metallic nanostructure is disposed on or adjacent to the planar integrating element, at least one metallic nanostructure is configured such that the field intensity and the gradient of the laser radiation, that is coupled into the waveguide, are enhanced over a sufficiently large volume around the nanostructure to simultaneously cause plasmonic based optical trapping of analyte(s) in a medium, and plasmonic based excitation of the particles to produce Raman scattered radiation. A Raman scattered radiation collection means is disposed on the substrate for collecting said Raman scattered radiation produced by the particles.

Abstract: In the present invention, a molecular analysis device comprises a substrate, and a waveguide with a planar integrating element and filter or reflector element adjacent thereto is disposed on the substrate. The waveguide comprises a coupling means configured for coupling a predetermined frequency range of laser radiation into the waveguide. At least one metallic nanostructure is disposed on or adjacent to the planar integrating element, at least one metallic nanostructure is configured such that the field intensity and the gradient of the laser radiation, that is coupled into the waveguide, are enhanced over a sufficiently large volume around the nanostructure to simultaneously cause plasmonic based optical trapping of analyte(s) in a medium, and plasmonic based excitation of the particles to produce Raman scattered radiation. A Raman scattered radiation collection means is disposed on the substrate for collecting said Raman scattered radiation produced by the particles.

Abstract: A communication device is provided, the communication device comprising a receiving circuit configured to receive a message from another communication device; a time base circuit providing a time base signal that specifies a plurality of time periods; a determining circuit configured to determine, based on an expected reception time of the message and a reception time of the message, a parameter value characterizing a time base offset between the communication device and the other communication device; an offset generating circuit configured to generate a time period offset value specifying a time offset from a point in time, the time period offset value corresponding to a number of time periods from the plurality of time periods, wherein the number of time periods is determined according to the parameter value.

Abstract: A method for transmitting OFDM symbols by a plurality of ad-hoc radio communication devices in an ad-hoc radio communication devices' group is provided. The method includes a first ad-hoc radio communication device of the ad-hoc radio communication devices' group transmitting a first OFDM symbol in a first frequency sub-range of a frequency range selected for transmission in accordance with a frequency hopping pattern, the frequency range comprising a plurality of frequency sub-ranges, and in the same transmission time period, a second ad-hoc radio communication device of the ad-hoc radio communication devices' group transmitting a second OFDM symbol in a second frequency sub-range of the frequency range, wherein the second frequency sub-range is different from the first frequency sub-range.