Abstract: An electrode comb for a micromechanical component includes at least one electrode finger for which a first electrode finger subunit with a first central longitudinal axis and a second electrode finger subunit with a second central longitudinal axis are defined. The second central longitudinal axis are defined is inclined in relation to the first central longitudinal axis about a bend angle not equal to 0° and not equal to 180°.

Abstract: A micromechanical sensor element (1) is provided, which has a sealed diaphragm (2) affixed in a frame (3), exhibits high sensitivity at high overload resistance and has a small size, and which allows a piezoresistive measured-value acquisition. To this end, at least one carrier element (4), which is connected to the frame (3) via at least one connection link (5), is formed in the region of the diaphragm (2). Furthermore, piezoresistors (6) for detecting a deformation are situated in the region of the connection link (5).

Abstract: A micromechanical component includes: a mirror element with a reflective surface on a first outer side of the mirror element, which is designed in such a way that a first potential is applied to a first electrode surface on a second outer side of the mirror element opposite from the first outer side; a counterelectrode situated adjacent to the second outer side of the mirror element and which is designed in such a way that a second potential is applied to a second electrode surface of the counterelectrode; and a voltage control unit configured to apply a temporally varying voltage signal between the first electrode surface and the second electrode surface

Abstract: The present invention relates to a magnetic yoke (300) having a yoke core that has a magnet (202), on which a first yoke arm (210) and a second yoke arm (210) are developed in such a way that the magnet (202) and the two yoke arms (210) open up a yoke opening, and having a first pair of pole pieces (212), which extend into the yoke opening and are positioned at a distance to each other in a first direction in such a way that a first gap (214) is developed between the first pair of pole pieces (212) and having a second pair of pole pieces (254), which extend into the yoke opening and are positioned in a second direction, that is aligned perpendicular to the first direction, at a distance from each other in such a way that a second gap (256) is developed between the second pair of pole pieces (254). The present invention also relates to a micromechanical component having such a magnetic yoke (300).

Abstract: An electrostatic drive having at least three intermediate frames, each two adjacent intermediate frames being connected to one another via at least one intermediate spring whose longitudinal directions lie on a first axis of rotation, and intermediate electrode fingers being situated on frame girders oriented parallel to the first axis of rotation of the intermediate frames, and having an outer frame that surrounds the intermediate frames and that is connected to the outermost intermediate frame via at least one outer spring whose longitudinal direction lies on a second axis of rotation that is oriented non-parallel to the first axis of rotation, and outer electrode fingers being situated on frame girders oriented parallel to the second axis of rotation of the outer frame and of the outermost intermediate frame of the at least three intermediate frames.

Abstract: A method and a micromechanical component which counteract manufacturing-process-related mechanical stresses in the membrane are provided. The membrane is formed on a substrate in a layer system and spans a cavity in the substrate. The layer system includes at least one base layer formed on the substrate for circuit elements. At least one structured masking layer is also formed on the base layer for defining the circuit elements. The masking layer is structured in the area of the membrane in such a way that mechanical stresses acting in the area of the membrane under vacuum are at least partially compensated, the intrinsic stress of the masking layer being taken into account in the layout of the structuring.

Abstract: A micromechanical device and a method for producing this device are provided, the device having a sensor pattern that includes a spring pattern and a seismic mass. The seismic mass may be connected to the substrate material via the spring pattern, and a clearance may be provided in a direction perpendicular to the major substrate plane between the spring pattern and the substrate material. Alternatively, the spring pattern and the seismic mass may have a common, essentially continuous, front side surface.

Abstract: A micromechanical sensor element (1) is provided, which has a sealed diaphragm (2) affixed in a frame (3), exhibits high sensitivity at high overload resistance and has a small size, and which allows a piezoresistive measured-value acquisition. To this end, at least one carrier element (4), which is connected to the frame (3) via at least one connection link (5), is formed in the region of the diaphragm (2). Furthermore, piezoresistors (6) for detecting a deformation are situated in the region of the connection link (5).

Abstract: A pressure sensor having a pressure sensor element, the pressure sensor element having a diaphragm area and a first fixing area, the pressure to be measured exerting a force action on the diaphragm area, the first fixing area being connected to a second fixing area of a fixing element to fix the pressure sensor element, and the first fixing area and the second fixing area being pressure-loaded by the force action.

Abstract: A micromechanical sensor and a method for manufacturing a micromechanical sensor which has at least one membrane are provided. The membrane is made of a first material which is accommodated in a surrounding second material, and the membrane is configured for sensing a medium surrounding it. The membrane is reinforced, at least partly, by a third material at break-sensitive points on the membrane rim. Reinforcement of the membrane rim increases the stability and thus also the service life of the membrane and the sensor.

Abstract: A micromechanical piezoresistive pressure sensor device having a sensor substrate, in which an essentially rectangular diaphragm region is provided; a piezoresistive resistance device having at least one piezoresistive resistor strip, which runs parallel to the longitudinal edges of the diaphragm device across the entire length of the diaphragm device and onto the surrounding sensor substrate; the piezoresistive resistor strip having a narrow center region and widened end regions and the widened end regions running across the short edges of the diaphragm device.

Abstract: A micromechanical device and a method for producing this device are provided, the device having a sensor pattern that includes a spring pattern and a seismic mass. The seismic mass may be connected to the substrate material via the spring pattern, and a clearance may be provided in a direction perpendicular to the major substrate plane between the spring pattern and the substrate material. Alternatively, the spring pattern and the seismic mass may have a common, essentially continuous, front side surface.

Abstract: A pressure sensor having a pressure sensor element, the pressure sensor element having a diaphragm area and a first fixing area, the pressure to be measured exerting a force action on the diaphragm area, the first fixing area being connected to a second fixing area of a fixing element to fix the pressure sensor element, and the first fixing area and the second fixing area being pressure-loaded by the force action.

Abstract: A micromechanical pressure sensor which is made up of at least one first component element and a second component element bordering on the first component element. In this context, the first component element includes at least one diaphragm and one cavity. The cavity is arranged or structured so that the medium to be measured gains access to the diaphragm through the cavity. In addition, in the second component element an opening is provided which guides the medium to be measured to the cavity. At least a part of the cavity represents an extension, without a transition, of the opening in the second component.

Abstract: A method and a micromechanical component which counteract manufacturing-process-related mechanical stresses in the membrane are provided. The membrane is formed on a substrate in a layer system and spans a cavity in the substrate. The layer system includes at least one base layer formed on the substrate for circuit elements. At least one structured masking layer is also formed on the base layer for defining the circuit elements. The masking layer is structured in the area of the membrane in such a way that mechanical stresses acting in the area of the membrane under vacuum are at least partially compensated, the intrinsic stress of the masking layer being taken into account in the layout of the structuring.

Abstract: The present invention creates a micromechanical piezoresistive pressure sensor device having a sensor substrate (1), in which an essentially rectangular diaphragm region (50) is provided; a piezoresistive resistance device (S1-S4; S1, S2, S3?, S4?) having at least one piezoresistive resistor strip (S1-S4; S1, S2), which runs parallel to the longitudinal edges (55a, 55b) of the diaphragm device (50) across the entire length of the diaphragm device (50) and onto the surrounding sensor substrate (1); the piezoresistive resistor strip (S1-S4; S1, S2) having a narrow center region (S10-S40; S10, S20, S30?, S40?) and widened end regions (S11, S12, S21, S22, S31, S32, S41, S42; S11, S12, S21, S22, S31?, S32?, S41?, S42?) and the widened end regions (S11, S12, S21, S22, S31, S32, S41, S42; S11, S12, S21, S22, S31?, S32?, S41?, S42?) running across the short edges (56a, 56b) of the diaphragm device (50).

Abstract: A micromechanical apparatus, a pressure sensor, and a method, a closed cavity being provided beneath a membrane, the membrane having a greater thickness in a first membrane region than in a second membrane region.

Abstract: A micromechanical pressure sensor which is made up of at least one first component element and a second component element bordering on the first component element. In this context, the first component element includes at least one diaphragm and one cavity. The cavity is arranged or structured so that the medium to be measured gains access to the diaphragm through the cavity. In addition, in the second component element an opening is provided which guides the medium to be measured to the cavity. At least a part of the cavity represents an extension, without a transition, of the opening in the second component.

Abstract: A micromechanical component, in particular a pressure sensor, including a substrate that has a membrane region, a surrounding region of the membrane region, at least one measuring resistance provided in the membrane region and modifiable by deformation of the membrane region, and a corresponding evaluation circuit provided in the surrounding region. An interference effect on the measuring resistance is producible by way of a deformation of parts, in particular conductor paths, of the evaluation circuit relative to the substrate. The invention also creates a corresponding equalization method on a test chip or as an individual final equalization.

Abstract: A micromechanical pressure sensor device, particularly for measuring low absolute pressures and/or small differential pressures. The device includes a frame that is formed at least partially by a semiconductor material, a membrane retained by the frame, at least one measuring resistor that is disposed at a first location in or on the membrane and whose resistance value is a function of pressure-induced mechanical stresses in the membrane, and at least one compensating resistor that is disposed at a second location in or on the membrane and whose resistance value is a function of pressure-induced mechanical stresses in the membrane. The resistance value changes at the first location with a first linear component and a first quadratic component as a function of the pressure, and the resistance value changes at the second location approximately without a linear component and with a second quadratic component, which is proportional to the first quadratic component, as a function of the pressure.