Abstract: A QKD arrangement with a photon source generating entangled idler and signal photons, with two measuring units, one of which receiving the idler photons and the other one receiving the signal photons, and each including an optical module with photon channels, wherein a photon passes a photon channel as a function of its polarization, and a device for detecting the photons in association to its respective photon channel, as well as a time control for timingly adjusting the detection devices; the photon source is adapted for pulsed emission of photon pairs, and an interrupting unit supplying the signal photons to the optical module in pulsed manner is arranged upstream of the other measuring unit, the photon channels in each optical module including delay units with different delay periods, and only one single-photon detector associates the photons to the photon channels on the basis of a time pattern.

Abstract: The invention relates to a node device (21) for a network (20) comprising quantum cryptographic connections (1) provided with quantum channels (4) and public channels (5), comprising quantum optics means (11) for connecting to the respective quantum channels, for generating secrets or keys by means of quantum cryptography, comprising means (13) for managing symmetrical secrets or keys, cryptography means (14) for generating cryptograms, and driver means (15) connected thereto for transmission via a public channel, wherein the means (15) for managing symmetrical secrets or keys and the cryptography and driver means (14; 15) are combined in a common node module (24) as central components (13, 14, 15) for a plurality of quantum channel connections, while the quantum optics means (11) are provided separately in decentral modules (23) for the plurality of quantum channel connections.

Abstract: For readjusting a polarization drift in the transmission of a polarization-encoded optical signal from a transmitter via a light guide to a receiver, optical auxiliary signals having the same wavelength as the polarization-encoded signal as well as different polarizations as in correspondence with a first base and a second base are fed into the light guide on the side of the transmitter while the transmission of the polarization-encoded signal is interrupted, and the optical auxiliary signals are picked up from the light guide and checked for shifts of the different polarizations by a polariometer on the side of the receiver, whereupon, in the event of the detection of polarization shifts, the different polarizations shifted during the transmission are displaced in the sense of the polarization set values via a polarization controller associated with the light guide.

Abstract: A miniature sensor for detecting acceleration and deceleration processes has at least one bar-like spring element which is formed by a nanowire, which is connected by one end to the detector substrate and projects from the latter and which preferably carries at its free end a coating emitting a permanent magnetic stray field, or a nanoparticle of this type, wherein the nanowire and magnetic stray field coating, or mass, together form the inertial mass. A magnetic field detection layer composed, for example, of magnetoresistive material, is disposed at least in the region near the connected end of the nanowire. The substrate is preferably provided with such a layer which preferably, for its part, as sensor component forms a constituent part of a magnetic field detection unit.

Abstract: An electronic biosensor arrangement (1), comprising a receiving region (2) for biological material, a sensor-electrode arrangement (3) with sensor electrodes (3a, 3b) which intermesh in a comb-like manner being associated therewith, with which sensor electrodes (3a, 3b) a measuring circuit (5) is connectable for measuring an electrical measurement parameter on the sensor electrodes (3a, 3b) and influenced by biological material, wherein the sensor electrodes (3a, 3b) form a plurality of sensor capacitors (Csensor,1 to Csensor,N), with which electronic switching means (S2,1 to S2,N) driven by a control logic (8) are associated for connecting to earth or to a voltage source carrying a measurement voltage (Vdrive), respectively, comprising a reference capacitor (Cref), to which a switching means (S1) driven by the control logic (8) and arranged for optionally connecting to earth or to the measurement voltage (Vdrive) is likewise assigned, wherein the capacitors (Cref, Csensor1?Csensor, N) are also combined to a

Abstract: A measuring device for detecting and evaluating an impact, jolt or the like is formed with an impact face, against which the impact, jolt or pulse which is to be evaluated strikes. A sensor, for example a force sensor, detects values of the force which act on the impact face as a result. A sensor, for example an acceleration sensor, detects values of the acceleration which act on the impact face as a result. An evaluation unit processes the determined force and acceleration values.

Abstract: The invention concerns a fixed support for immobilizing biomolecules, said support being covered, at least in some parts, with a polymer. The invention is characterized in that the polymer is an epoxy resin with functionality ranging between 4 and 15. The invention also concerns a method for making such a support.

Abstract: The invention relates to a miniature sensor for detecting acceleration and deceleration processes, which is characterized—in that it comprises at least one bar-like spring element which is formed by a nanowire (2), which is connected by one end (21) to the detector substrate (5) and projects from the latter and which preferably carries at it free end (22) a coating (3?) emitting a permanent magnetic stray field (ms), or a nanoparticle (3) of this type, wherein the nanowire and magnetic stray field coating, or mass, together form the inertial mass, and—in that a magnetic field detection layer (4), e.g. composed of magnetoresistive material, is arranged at least in the region near the connected end (21) of the nanowire (2),—wherein the substrate is preferably provided with such a layer which preferably, for its part, as sensor component forms a constituent part of a magnetic field detection unit (7).

Abstract: We describe a lattice part made of metal and a method for producing a lattice part made of metal or a metal alloy. The lattice has a thickness of less than 1 mm at a size of the gaps of less than 50 mm2. The lattice comprises a connection made of knots, and perpendicular to the lattice surface has lattice bars and lattice knots of the same thickness. A method for the production of a lattice part made of metal, particularly made of light alloy, is characterized by a primary shaping process according to DIN 8580, wherein a mold is formed in the first step, a primary material is introduced in the mold cavity in the second step, the part is removed from the mold in the third step, and the finishing of the metallic lattice part is carried out in the fourth step.

Abstract: An apparatus for enhancing the contact frequency between two reactants capable of binding to one another, preferably between an analyzer molecule and an analyte molecule, especially for enhancing the binding effectiveness in bioanalysis arrays with the aid of micro- or nanomagnetic particles (75) set in motion in a controlled manner in the fluid reaction medium by means of magnetic fields generated by variably feedable electromagnets (3, 2, 20) arranged on both sides of the reaction fluid film.

Abstract: Disclosed is a method for identification of microbial pathogens in a body fluid sample comprising the following steps: a) providing a body fluid sample; b) lysing the microbial pathogens and performing a nucleic acid amplification reaction on the microbial DNA encoding 16S or 18S rRNA wherein or whereafter the amplified nucleic acids are labelled; c) contacting the labelled amplified nucleic acids of step b) with a microarray comprising on defined areas on the microarray's surface immobilised probes for microbial DNA encoding 16S or 18S rRNA from microbial pathogens; d) detecting the binding of one or more species of the labelled amplified nucleic acids to a probe by detecting a labelled amplified nucleic acid being specifically bound to the microarray; and e) identifying a microbial pathogen in the body fluid sample by correlating the detected binding of the labelled amplified nucleic acids with the defined areas of the immobilised probes for microbial DNA encoding 16S or 18S rRNA from microbial pathogens.

Abstract: The invention relates to a node device (21) for a network (20) comprising quantum cryptographic connections (1) provided with quantum channels (4) and public channels (5), comprising quantum optics means (11) for connecting to the respective quantum channels, for generating secrets or keys by means of quantum cryptography, comprising means (13) for managing symmetrical secrets or keys, cryptography means (14) for generating cryptograms, and driver means (15) connected thereto for transmission via a public channel, wherein the means (15) for managing symmetrical secrets or keys and the cryptography and driver means (14; 15) are combined in a common node module (24) as central components (13, 14, 15) for a plurality of quantum channel connections, while the quantum optics means (11) are provided separately in decentral modules (23) for the plurality of quantum channel connections.

Abstract: An electronic biosensor arrangement (1), comprising a receiving region (2) for biological material, a sensor-electrode arrangement (3) with sensor electrodes (3a, 3b) which intermesh in a comb-like manner being associated therewith, with which sensor electrodes (3a, 3b) a measuring circuit (5) is connectable for measuring an electrical measurement parameter on the sensor electrodes (3a, 3b) and influenced by biological material, wherein the sensor electrodes (3a, 3b) form a plurality of sensor capacitors (Csensor,1 to Csensor,N), with which electronic switching means (S2,1 to S2,N) driven by a control logic (8) are associated for connecting to earth or to a voltage source carrying a measurement voltage (Vdrive), respectively, comprising a reference capacitor (Cref), to which a switching means (S1) driven by the control logic (8) and arranged for optionally connecting to earth or to the measurement voltage (Vdrive) is likewise assigned, wherein the capacitors (Cref, Csensor1-Csensor, N) are also combined to a

Abstract: A QKD arrangement with a photon source generating entangled idler and signal photons, with two measuring units, one of which receiving the idler photons and the other one receiving the signal photons, and each including an optical module with photon channels, wherein a photon passes a photon channel as a function of its polarization, and a device for detecting the photons in association to its respective photon channel, as well as a time control for timingly adjusting the detection devices; the photon source is adapted for pulsed emission of photon pairs, and an interrupting unit supplying the signal photons to the optical module in pulsed manner is arranged upstream of the other measuring unit, the photon channels in each optical module including delay units with different delay periods, and only one single-photon detector associates the photons to the photon channels on the basis of a time pattern.

Abstract: A device for generating polarization-entangled photons by means of parametric down-conversion, comprising a waveguide structure formed in a substrate of an optically non-linear material with periodically poled regions, wherein, when in operation, pump photons can be supplied from a pump laser to the waveguide structure, and wherein a separating means for separating the entangled photons for the separate further conduction of signal photons and idler photons, respectively, is arranged to follow the waveguide structure.

Abstract: For readjusting a polarization drift in the transmission of a polarization-encoded optical signal from a transmitter via a light guide to a receiver, optical auxiliary signals having the same wavelength as the polarization-encoded signal as well as different polarizations as in correspondence with a first base and a second base are fed into the light guide on the side of the transmitter while the transmission of the polarization-encoded signal is interrupted, and the optical auxiliary signals are picked up from the light guide and checked for shifts of the different polarizations by a polariometer on the side of the receiver, whereupon, in the event of the detection of polarization shifts, the different polarizations shifted during the transmission are displaced in the sense of the polarization set values via a polarization controller associated with the light guide.

Abstract: A method is used for analyzing scenes. The scene or objects in the scene and an optical sensor perform a relative movement and the scene information obtained is evaluated. Visual information of the scene is detected by the individual pixels of the optical sensor and pixel co-ordinates of established variations in intensity are determined. A temporization of the established variations in intensity is determined and a local accumulation of the variations in intensity is determined by statistical methods. The local accumulations are evaluated in terms of the number and/or position thereof by statistical methods and data area clearing methods. The determined values are used as parameters of a detected scene region. A parameter is compared with a pre-determined parameter considered characteristic of an object, and when the pre-determined comparison criteria are fulfilled, the evaluated local amassment associated with the respective scene region is seen as an image of the object.