Abstract: A magnetic field sensor having a first magnetic sensor core for measuring a magnetic field in a first measuring direction, and a second magnetic sensor core for measuring a magnetic field in a second measuring direction, the first and second magnetic sensor cores having a shared magnetic anisotropy.

Abstract: A high power laser source comprises a bar of laser diodes having a first coefficient of thermal expansion CTEbar on a submount having a second coefficient CTEsub and a cooler having a third coefficient CTEcool. The submount/cooler assembly shows an effective fourth coefficient CTEeff differing from CTEbar. This difference leads to a deformation of the crystal lattice of the lasers' active regions by mechanical stress. CTEeff is selected to be either lower than both CTEbar and CTEcool or is selected to be between CTEbar and CTEcool. The submount may either comprise layers of materials having different CTEs, e.g., a Cu layer of 10-40 ?m thickness and a Mo layer of 100-400 ?m thickness, or a single material with a varying CTEsub. Both result in a CTEsub varying across the submount's thickness.

Abstract: A process and apparatus for lossless data compression including the step of generating characteristic tables for predicted intensities as a function of radius values f(i,j)) on at least one type of preferred axes. Intensity signals of a detector matrix (I(i,j)) are used to implement the invention.

Abstract: A magnetic field sensor includes a magnetizable core having a curved surface at least sectionally, a magnetization device for magnetizing the core, and a determination device for determining a magnetic field in the core.

Abstract: A high power laser source comprises a bar of laser diodes having a first coefficient of thermal expansion CTEbar on a submount having a second coefficient CTEsub and a cooler having a third coefficient CTEcool. The submount/cooler assembly shows an effective fourth coefficient CTEeff differing from CTEbar. This difference leads to a deformation of the crystal lattice of the lasers' active regions by mechanical stress. CTEeff is selected to be either lower than both CTEbar and CTEcool or is selected to be between CTEbar and CTEcool. The submount may either comprise layers of materials having different CTEs, e.g., a Cu layer of 10-40 ?m thickness and a Mo layer of 100-400 ?m thickness, or a single material with a varying CTEsub. Both result in a CTEsub varying across the submount's thickness.

Abstract: For the administering of medicaments, an adapter is provided for connection to a haemodialysis tube set, which makes possible the direct connection of a standard injection vial to the extracorporeal circuit, avoiding the introduction of air into the circuit. The adapter has two conduit pathways. The conduit pathway for the application of medicament contains a gas-blocking element. The second conduit pathway serves for the aeration of the injection vial.

Abstract: A magnetic field sensor for measuring a magnetic field at a sensor location has a printed circuit board, including electrically insulating material; a magnetic field sensor element situated on the printed circuit board and connected via electrical contacts to first printed conductors provided on the printed circuit board; and at least one second printed conductor for generating a test magnetic field, the second printed conductor being provided on the printed circuit board and generating a predetermined test magnetic field when a calibration current is applied at the sensor location.

Abstract: A semiconductor chip having contact surfaces on an upper side parallel to the wafer plane has terminal pads on a terminal-pad side perpendicular to the upper side, each terminal pad being conductively connected to an assigned contact surface. This allows vertical mounting of the chip on a substrate and contacting with the aid of customary bonding techniques. A manufacturing method and two mounting methods are described.

Abstract: A method for calibrating a triaxial magnetic field sensor includes steps for determining an offset of recorded measured values of the magnetic field sensor using a superposed signal and for determining the sensitivity of the magnetic field sensor along the first measuring axes. The determination of the sensitivity includes steps for determining the sensitivity of the magnetic field sensor along a first measuring axis and for determining the sensitivity of the magnetic field sensor along the other measuring axes based on the sensitivity of the first measuring axis and the determined offset.

Abstract: In a method for manufacturing a micromechanical component, a cavity is produced in the substrate from an opening at the rear of a monocrystalline semiconductor substrate. The etching process used for this purpose and the monocrystalline semiconductor substrate used are controlled in such a way that a largely rectangular cavity is formed.

Abstract: A manufacturing method for a micromechanical component having the following steps: at least partially covering a first side of a substrate using a first insulating layer, forming at least one actuator plate electrode, at least one contact terminal, and at least one spring component from at least one first conductive material, covering at least the at least one actuator plate electrode, the at least one contact terminal, and the at least one spring component using a second insulating layer, forming at least one stator plate electrode from at least one second conductive material, forming at least one first trench in the substrate for producing a displaceable mass and a frame of a mounting, etching being performed in a first direction, and removing at least one partial mass of the second insulating layer, which is between the at least one actuator plate electrode and the at least one stator plate electrode, etching being performed in a second direction. Also described is a related micromechanical component.

Abstract: A micromechanical structure and a method for producing a micromechanical structure are provided, the micromechanical structure being configured for receiving and/or generating acoustic signals in a medium at least partially surrounding the structure. The structure includes a first counterelement that has first openings and essentially forms a first side of the structure, a second counterelement that has second openings and essentially forms a second side of the structure, and an essentially closed diaphragm disposed between the first counterelement and the second counterelement.

Abstract: A high power laser source comprises at least a bar of laser diodes with a first coefficient of thermal expansion (CTEbar), a submount onto which said laser bar is affixed with a second coefficient of thermal expansion (CTEsub), and a cooler onto which said submount is affixed with a third coefficient of thermal expansion (CTEcool). The submount/cooling assembly exhibits an effective fourth coefficient of expansion (CTEeff). According to the invention, mechanical stress exerted to the laser bar improves reliability and optical performance. To effect this, CTEeff must differ from CTEbar, CTEeff?CTEbar. Preferably, CTEeff should differ by a predetermined amount from CTEbar. The difference is achieved in two ways: either by selecting CTEsub>CTEbar and CTEsub?CTEcool, or by selecting CTEsub<CTEbar and CTEsub<CTEcool. Thereby, all coefficients must be selected such that CTEeff differs from CTEbar: CTEeff?CTEbar, preferably by a percentage of 5% or by a predetermined amount of +/?3-4×10?7K?1.

Abstract: A method for producing a micromechanical diaphragm sensor, and a micromechanical diaphragm sensor produced with the method. The micromechanical diaphragm sensor has at least one first diaphragm as well as a second diaphragm, which is disposed essentially on top of the first diaphragm. Furthermore, the micromechanical diaphragm sensor has a first cavity and a second cavity, which is essentially disposed above the first cavity.

Abstract: A micromechanical structure and a method for producing a micromechanical structure are provided, the micromechanical structure being configured for receiving and/or generating acoustic signals in a medium at least partially surrounding the structure. The structure includes a first counterelement that has first openings and essentially forms a first side of the structure, a second counterelement that has second openings and essentially forms a second side of the structure, and an essentially closed diaphragm disposed between the first counterelement and the second counterelement.

Abstract: A process and apparatus for lossless data compression including the step of generating characteristic tables for predicted intensities as a function of radius values f(i,j)) on at least one type of preferred axes. Intensity signals of a detector matrix (I(i,j)) are used to implement the invention.

Abstract: A damping system arranged in the region of an injector base between a cylinder head and an injector mounted thereon of an internal combustion engine has a multi-part construction. A damping element forming part of the damping system is constructed as a metal cushion.

Abstract: A method for producing a micromechanical diaphragm sensor, and a micromechanical diaphragm sensor produced with the method. The micromechanical diaphragm sensor has at least one first diaphragm as well as a second diaphragm, which is disposed essentially on top of the first diaphragm. Furthermore, the micromechanical diaphragm sensor has a first cavity and a second cavity, which is essentially disposed above the first cavity.

Abstract: A high power laser source comprises a bar of laser diodes, a submount onto which said laser bar is affixed, and a cooler onto which said submount is affixed. The laser bar has a first coefficient of thermal expansion (CTEbar), the submount has a second coefficient of thermal expansion (CTEsub), and the cooler has a third coefficient of thermal expansion (CTEcool) the third coefficient (CTEcool) being higher than both said first coefficient (CTEbar) and said second coefficient (CTEsub). Contrary to the usual approach with a CTEsub matching the CTEbar, the second coefficient (CTEsub) is selected lower than both said first coefficient (CTEbar) and said third coefficient (CTEcool) according to the invention. A preferred range is CTEsub=k*CTEbar, with 0.4<k<0.9. The submount may consist of or comprise two or more layers of different materials having different CTEs, e.g.

Abstract: A damping system arranged in the region of an injector base between a cylinder head and an injector mounted thereon of an internal combustion engine has a multi-part construction. A damping element forming part of the damping system is constructed as a metal cushion.