Abstract: A method for measurement of a sequence of recurring electronic signals (10) is proposed, wherein the sequence to be measured consists of n recurring electronic signals, wherein a time-to-digital converter (2) and a memory (5) are provided.

Abstract: Functionalised polyglycine-poly(alkylene imine)-copolymers, the preparation thereof and use thereof for preparing formulations of or for complexing anionic active ingredients and effect substances Disclosed are copolymers comprising structural units of formula (I), of formula (II) and of formula (III) —NR1—CHR3—CHR4-??(I), —NH—CO—CHR7-??(II), —NH—CHR9—CHR10-??(III), or structural units of formula (IV), of formula (V) and of formula (VI) —NR1—CHR3—CHR4—CHR5-??(IV), —NH—CO—CHR7—CHR8-??(V), —NH—CHR9—CHR10—CHR11-??(VI), wherein R1 is a radical of formula —CO—R2, of formula —CO—NH—R2, of formula —CH2—CH(OH)— R12 or of formula —CH2—CH(NH2)—R12, R3, R4, R5, R7, R8, R9, R10 and R11 independently of one another represent hydrogen, methyl, ethyl, propyl or butyl, and R2 and R12 represent hydrogen or selected organic radicals.

Abstract: The invention relates to copolymers that contain structural units of the formula (I), of the formula (II) and optionally of the formula (III) —NR1—CHR3—CHR4— (I), —NH—CO—CHR7— (II), —NH—CHR9—CHR10— (III), or structural units of the formula (IV), of the formula (V) and optionally of the formula (VI) NR1—CHR3—CHR4—CHR5— (IV), —NH—CO—CHR7—CHR8— (V), —NH—CHR9—CHR10—CHR11— (VI), wherein R1 is a residue of the formula —CO—R2, of the formula —CO—NH—R2 or of the formula —CH2—CH(OH)—R12, R3, R4, R5, R7, R8, R9, R10 and R11 independently of each other represent hydrogen, methyl, ethyl, propyl or butyl, and R2 and R12 represent hydrogen or selected organic residues. These copolymers are characterized by good degradability and can be used, for example, for preparing active ingredient formulations.

Abstract: A method is proposed for generating single photons with a predetermined wavelength fV, with the following steps: i) generating a single photon, preferably in a source and a resonator, wherein the single photon has a resonator wavelength fR and a resonator bandwidth fBR, ii) measuring the resonator wavelength fR, preferably in a wavelength standard, wherein the single photon is guided from the resonator to the wavelength standard via a beam guide, iii) comparing the resonator wavelength fR with the predetermined wavelength fV and generating a control signal on the basis of the comparison, preferably in a controller, iv) adjusting the resonator using the control signal in order to change the resonator wavelength fR toward or to the predetermined wavelength fV, v) repeating steps i to iv) until the resonator wavelength fR corresponds to the predetermined wavelength fV and then coupling out.

Abstract: The invention relates to compositions containing water-soluble poly(oxazoline) and organic polymer particles chosen from the group of polyolefins, polyvinyl aromatics, polyvinyl esters, polyesters, polyamides, polyimides, polycarboxylic acids, polycarboxilic acid esters, polycarboxylic acid amides, polynitriles, polysulfonic acids, polyketones, polysulfones, polymeric polyols, polyurethanes, proteins, polymeric carbohydrates, nucleic acids or from a mixture of two or more of these polymers. The water-soluble poly(oxazolin) acts as a stabilizer for the polymer particles and can particularly advantageously be used as a stabilizer in the freeze-drying of aqueous polymer dispersions.

Abstract: The invention relates to a method for welding a first workpiece (11) to a second workpiece (12) by means of a laser. It is an object of the invention to provide a reliable, repeatable and reproducible approach for laser welding of two workpieces one of which consists of a semiconductor material.

Abstract: A method and an apparatus for processing an object by generation of laser radiation as a collimated laser beam, influencing the intensity distribution and/or the phase progression over the cross section of the laser beam, splitting the laser beam into two partial beams, and deflection and focusing of the partial beams so that the partial beams are superimposed in a processing zone in the material of the object.

Abstract: The invention relates to new cationic polymers conjugated with D-fructose, as a result of which they can selectively interact with specific structure elements on cell surfaces. The problem was that of creating novel, biocompatible, easy-to-produce, D-fructose-conjugated cationic polymers that have a higher selectivity with respect to certain cell types. To solve this problem, the invention proposes cationic polymers with covalently bonded D-fructose of general formula (I) with the following components: a) cationic polymer: macromolecular compounds of n repeat units with one or more positive charges; b) linker: a unit that links the cationic polymer with D-fructose or derivatives of D-fructose by means of any alkyl or aryl group, any alkenyl or alkinyl group, an ether, thioether or amine, an ester, amide or other carboxylic acid derivative, a heterocycle (e.g.

Abstract: The invention relates to an optical waveguide with two or more light-guiding cores (1a-1e) extending continuously along the longitudinal extension of the optical waveguide, parallel to one another and spaced apart from one another, from one end of the optical waveguide to the other, and with a first cladding (2) enclosing the cores (1a-1e). It is an object of the invention to provide a multicore optical waveguide for high-power operation with reduced system complexity compared to the prior art.

Abstract: A method for producing an aluminum layer is provided. The method includes depositing a metallic seed layer on a substrate, the seed layer having a thickness of not more than 5 nm, and also includes applying the aluminum layer to the seed layer, wherein the aluminum layer has a thickness of more than 30 nm. Further, an optical element, which can be a mirror layer, is provided including the metallic seed layer and the aluminum layer.

Abstract: The invention relates to a nanostructured active ingredient carrier system, in particular for reducing cytotoxic properties owing to the use of sheath polymer and the transport resulting therefrom, for interactions with cell membranes during the transport of hydrophilic constituents and, in connection therewith, the generation of an early endosomal release of the interaction complex from the carrier system. The problem addressed by the present invention is that of specifying a nanostructured active ingredient carrier system which avoids the disadvantages of the prior art and in particular permits a reduction in cytotoxic properties owing to the use of a sheath polymer and the transport resulting therefrom.

Abstract: The invention relates to a method for stably transmitting laser radiation through an optical waveguide (3), wherein two or more modes of the laser radiation propagating in the optical waveguide (3) interfere and form a mode interference pattern in the optical waveguide, as a result of which a thermally induced refractive index grating is produced in the optical waveguide (3). It is an object of the invention to demonstrate an effective approach for stabilizing the output signal of the optical waveguide (3) in a fiber-based laser/amplifier combination at high output powers, i.e. for avoiding mode instability. The invention achieves this object by virtue of the fact that a relative spatial phase shift between the mode interference pattern and the thermally induced refractive index grating is set in the direction of propagation of the laser radiation.

Abstract: An optical assembly for the illumination and hyperspectral evaluation of an object, having a light source or an optical element at which a light source radiates, wherein the light source or the optical element is designed to divide pairs of unambiguously assignable photons into a first light beam and a second light beam so that the first light beam hits a first detector system and the second light beam is directed at an object and light radiation coming from the object is directed at an optical element which spectrally decomposes light radiation and, from the optical element spectrally decomposing said light radiation, is directed at a second detector system. The first light beam can also be directed at a spectrally decomposing optical element and, from there, at a first detector system, and the light radiation coming from the object can be directed directly at the second detector system.

Abstract: The present invention relates to a composition for producing a polymer, comprising: a) from 20 to 60% by weight, based on the entire composition, of at least one monomer; and b) from 30 to 60% by weight, based on the entire composition, of at least one branched pre-polymer, wherein the composition is liquid at room temperature and under normal pressure; use of the composition, a method for producing a polymer using the composition, as well as an electrically dimmable glazing that encloses the polymer.

Abstract: An optical arrangement for fluorescence microscopy applications. Electromagnetic radiation from a radiation source is directed onto a biological sample in the form of a light sheet. One of more fluorophore(s) is contained in the sample. The radiation photoactivates the fluorophore(s) by exciting them from a state which they cannot be exited to fluoresce to a state which they can be exited to fluoresce by illuminating with electromagnetic radiation of a particular wavelength, and subsequently photodeactivating them. Multiphoton beams of nonclassical light are directed onto a first optical system the beam(s) are directed onto a sample of the light sheet. Fluorescent radiation of fluorophores, can be excited within the light sheet by the plurality of multiphoton beams occurring simultaneously on/in the sample. The fluorescence radiation occurs by means of a second optical system on a detection system which measures in a spatially resolving manner.

Abstract: In the optical arrangement for fluorescent microscopic applications, one or more multiphoton beams, but at least one or two photon pair beams, from a source of non-classical light is/are directed at a first optical system, consisting of an arrangement of at least one lens or one photon-reflecting element or another beam-forming element or a combination thereof. The first optical system (3) is designed to shape the non-classical light into a light sheet (4) or a light sheet-like shape and thence to direct it at a specimen (5), so that fluorescent radiation is excited by means of multiphoton absorption using the multiple multiphoton beams that are simultaneously incident on/in the specimen. Fluorescent radiation (6) obtained by excitation is incident by means of a second optical system (7) on a detection system (8) that is designed for the spatially resolved capture of fluorescent radiation.

Abstract: The invention relates to a method for producing an optical component (1) by means of laser radiation. The object of the invention is that of providing a method that is improved compared with the prior art, which method allows for the correction of deviations of the optical functionality of the component from specified target parameters. For this purpose, the method according to the invention comprises the following method steps: generating a structure in the material of the component (1) which gives the component (1) an optical functionality, and modifying the refractive index in the material of the component (1) by means of laser beams in a pre- and/or post-processing step, i.e. before or after the generation of the structure, in order to correct deviations of the optical functionality of the component (1) from specified target parameters.

Abstract: The invention relates to an apparatus for generating laser pulses. It is an object of the invention to provide a method for generating synchronized laser pulse trains at variable wavelengths (e.g., for coherent Raman spectroscopy/microscopy), wherein the switching time for switching between different wavelengths should be in the sub-?s range. For this purpose the apparatus according to the invention comprises a pump laser (1), which emits pulsed laser radiation at a specified wavelength, an FDML laser (3), which emits continuous wave laser radiation at a cyclically variable wavelength, and a nonlinear conversion medium (4), in which the pulsed laser radiation of the pump laser (1) and the continuous wave laser radiation of the FDML laser (3) are superposed.

Abstract: A method and a device for producing an optical component having at least three monolithically arranged optical functional surfaces and an optical component are disclosed.

Abstract: The invention relates to the optical assembly for the illumination and hyperspectral evaluation of an object, having a light source or an optical element (1) at which a light source radiates, wherein the light source or the optical element is designed to divide pairs of unambiguously assignable photons into a first light beam (2) and a second light beam (5) in such a way that the first light beam hits a first detector system (4) and the second light beam is directed at an object (7) and light radiation coming from the object is directed at an optical element (8) which spectrally decomposes said light radiation and, from the optical element spectrally decomposing said light radiation is directed at a second detector system (9). The first light beam can also be directed at a spectrally decomposing optical element and from there, at a first detector system, and the light radiation coming from the object can be directed directly at the second detector system.