Abstract: An electrically driven motor vehicle has current collectors for pickup from a dual-pole power transmission line device. A device determines the voltages between a vehicle chassis and the current collectors. The device is a bridge circuit with two equal voltage divider resistors connected in series between the two current collectors and a bridge shunt resistor electrically connected to a center tap between the voltage divider resistors and to the vehicle chassis, or the device has two voltage measurement devices for determining a voltage between the first current collector and the vehicle chassis and a voltage between the second current collector and the vehicle chassis. There is also described a method for operating the motor vehicle and a system with the motor vehicle and a dual-pole power transmission line device.

Abstract: The present invention relates to a method of diagnosing Head and Neck Squamous Cell Carcinoma (HNSCC) in an individual. In addition, the present invention relates to a method of providing a survival prognosis to an individual suffering from Head and Neck Squamous Cell Carcinoma (HNSCC). Moreover, the present invention relates to a kit for performing the above-mentioned methods.

Abstract: A disconnecting device for interrupting the direct current between a direct current source, in particular in the direct voltage range between 300 VDc and/or in the nominal current range between 4A and 250A, and a load. The device has at least one protection switch with a protection switch arrangement having a magnetic trigger, and has semiconductor electronics which are connected in parallel to the at least one protection switch and which block the current when the protection switch arrangement is in a current-conducting state and which conducts current at least temporarily when the protection switch arrangement is triggered. A current, in particular an electric arc current generated as a result of an electric arc, is switched, when the protection switch arrangement is triggered, from the at least one protection switch to the semiconductor electronics.

Abstract: The present invention relates to a method of diagnosing Head and Neck Squamous Cell Carcinoma (HNSCC) in an individual. In addition, the present invention relates to a method of providing a survival prognosis to an individual suffering from Head and Neck Squamous Cell Carcinoma (HNSCC). Moreover, the present invention relates to a kit for performing the above-mentioned methods.

Abstract: An example circuit arrangement and method for actuating an electromagnetic drive system for electromechanical devices is disclosed, the example circuit arrangement including a mechanically locked end position, a control voltage source, a regulating and control circuit, a drive system, a transformer, a rectifier bridge a smoothing capacitor, and a main switching transistor, by means of which the drive system can be controlled in a characteristic pulse tracking system. In the example, the main switching transistor is connected in series to a primary branch of the transformer, the transformer is connected to the supply voltage, and the secondary winding of the transformer supplies the rectifier bridge, the output DC voltage of which is smoothed by the smoothing capacitor and added to the voltage of the control voltage source so as to result in a DC voltage feed having a chronological supply progression.

Abstract: Methods and apparatuses are provided for evaluating or testing stiction in Microelectromechanical Systems (MEMS) devices utilizing a mechanized shock pulse generation approach. In one embodiment, the method includes the step or process of loading a MEMS device, such as a multi-axis MEMS accelerometer, into a socket provided on a Device-Under-Test (DUT) board. After loading the MEMS device into the socket, a series of controlled shock pulses is generated and transmitted through the MEMS device utilizing a mechanized test apparatus. The mechanized test apparatus may, for example, repeatedly move the DUT board over a predefined motion path to generate the controlled shock pulses. In certain cases, transverse vibrations may also be directed through the tested MEMS device in conjunction with the shock pulses. An output of the MEMS device is then monitored to determine whether stiction of the MEMS device occurs during each of the series of controlled shock pulses.

Abstract: A circuit breaker having, in a current path, a switching device having a thermal and/or magnetic tripping device for interruption of a current circuit having the current path comprehensive in an event of overcurrent or short-circuit, wherein a functional component of the switching device connected into the current path is bridged by means of a bypass which carries the load current detected by means of a current sensor when the current is below a current threshold, and is shut off when the current threshold is exceeded.

Abstract: An example circuit arrangement and method for actuating an electromagnetic drive system for electromechanical devices is disclosed, the example circuit arrangement including a mechanically locked end position, a control voltage source, a regulating and control circuit, a drive system, a transformer, a rectifier bridge a smoothing capacitor, and a main switching transistor, by means of which the drive system can be controlled in a characteristic pulse tracking system. In the example, the main switching transistor is connected in series to a primary branch of the transformer, the transformer is connected to the supply voltage, and the secondary winding of the transformer supplies the rectifier bridge, the output DC voltage of which is smoothed by the smoothing capacitor and added to the voltage of the control voltage source so as to result in a DC voltage feed having a chronological supply progression.

Abstract: A MEMS device includes a movable mass having a central region overlying a sense electrode and an opening in which a suspension structure and spring system are located. The suspension structure includes an anchor coupled to a substrate and rigid links extending from opposing sides of the anchor. The spring system includes a first and second spring heads coupled to each of the rigid links. A first drive spring is coupled to the first spring head and to the movable mass, and a second drive spring is coupled to the second spring head and to the movable mass. The movable mass is resiliently suspended above the surface of the substrate via the suspension structure and the spring system. The spring system enables drive motion of the movable mass in the drive direction and sense motion of the movable mass in a sense direction perpendicular to the surface of the substrate.

Abstract: The embodiments described herein provide microelectromechanical systems (MEMS) devices, such as three-axis MEMS devices that can sense acceleration in three orthogonal axes (e.g., x-axis, y-axis, and z-axis). In general, the embodiments described can provide decoupling between the sense motions of all three axes from each other. This decoupling is facilitated by the use of an inner frame, and an outer frame, and the use of rotative spring elements combined with translatory spring elements that have asymmetric stiffness. Specifically, the translatory spring elements facilitate translatory motion in two directions (e.g., the x-direction and y-direction) and have an asymmetric stiffness configured to compensate for an asymmetric mass used to sense in the third direction (e.g., the z-direction).

Abstract: A MEMS device includes a movable mass having a central region overlying a sense electrode and an opening in which a suspension structure and spring system are located. The suspension structure includes an anchor coupled to a substrate and rigid links extending from opposing sides of the anchor. The spring system includes a first and second spring heads coupled to each of the rigid links. A first drive spring is coupled to the first spring head and to the movable mass, and a second drive spring is coupled to the second spring head and to the movable mass. The movable mass is resiliently suspended above the surface of the substrate via the suspension structure and the spring system. The spring system enables drive motion of the movable mass in the drive direction and sense motion of the movable mass in a sense direction perpendicular to the surface of the substrate.

Abstract: Methods and apparatuses are provided for evaluating or testing stiction in Microelectromechanical Systems (MEMS) devices utilizing a mechanized shock pulse generation approach. In one embodiment, the method includes the step or process of loading a MEMS device, such as a multi-axis MEMS accelerometer, into a socket provided on a Device-Under-Test (DUT) board. After loading the MEMS device into the socket, a series of controlled shock pulses is generated and transmitted through the MEMS device utilizing a mechanized test apparatus. The mechanized test apparatus may, for example, repeatedly move the DUT board over a predefined motion path to generate the controlled shock pulses. In certain cases, transverse vibrations may also be directed through the tested MEMS device in conjunction with the shock pulses. An output of the MEMS device is then monitored to determine whether stiction of the MEMS device occurs during each of the series of controlled shock pulses.

Abstract: A sensor device includes a substrate having a port extending through it and a membrane including a first electrode spanning across the port. The port exposes the membrane to a pressure stimulus from an external environment. A second electrode is spaced apart from the first electrode by a gap having a first width. A control circuit applies an actuation voltage to move the second electrode closer to the first electrode and change the gap to a second width that is less than the first width. When the gap is set to the second width, the pressure sensor exhibits a greater sensitivity then when the gap is set to the first width. The membrane with the first electrode is movable in response to the pressure stimulus and the pressure stimulus is sensed as movement of the first electrode relative to the second electrode while the actuation voltage is applied.

Abstract: A circuit breaker having, in a current path, a switching device having a thermal and/or magnetic tripping device for interruption of a current circuit having the current path comprehensive in an event of overcurrent or short-circuit, wherein a functional component of the switching device connected into the current path is bridged by means of a bypass which carries the load current detected by means of a current sensor when the current is below a current threshold, and is shut off when the current threshold is exceeded.

Abstract: A sensor device includes a substrate having a port extending through it and a membrane including a first electrode spanning across the port. The port exposes the membrane to a pressure stimulus from an external environment. A second electrode is spaced apart from the first electrode by a gap having a first width. A control circuit applies an actuation voltage to move the second electrode closer to the first electrode and change the gap to a second width that is less than the first width. When the gap is set to the second width, the pressure sensor exhibits a greater sensitivity then when the gap is set to the first width. The membrane with the first electrode is movable in response to the pressure stimulus and the pressure stimulus is sensed as movement of the first electrode relative to the second electrode while the actuation voltage is applied.

Abstract: A disconnecting device for interrupting the direct current between a direct current source, in particular in the direct voltage range between 300VDc and/or in the nominal current range between 4 A and 250 A, and a load. The device has at least one protection switch with a protection switch arrangement having a magnetic trigger, and has semiconductor electronics which are connected in parallel to the at least one protection switch and which block the current when the protection switch arrangement is in a current-conducting state and which conducts current at least temporarily when the protection switch arrangement is triggered. A current, in particular an electric arc current generated as a result of an electric arc, is switched, when the protection switch arrangement is triggered, from the at least one protection switch to the semiconductor electronics.

Abstract: Microelectromechanical system (MEMS) devices and methods for forming MEMS devices are provided. The MEMS devices include a substrate, an anchored structure fixedly coupled to the substrate, and a movable structure resiliently coupled to the substrate. The movable structure has an opening formed therethrough and is positioned such that the anchored structure is at least partially within the opening and is in a capacitor-forming relationship with the movable structure. The movable structure comprises a movable structure finger extending only partially across the opening.

Abstract: A MEMS sensor includes a movable element positioned in spaced apart relationship above a surface of a substrate and a single centrally located suspension anchor formed on the surface of the substrate. First and second rigid beams are coupled to opposing sides of the suspension anchor and are suspended above the surface of the substrate. A first torsion spring is interconnected between the movable element and the first rigid beam, and a second torsion spring is interconnected between the movable element and the first rigid beam. The rigid beams and the torsion springs are stiff in a lateral direction relative to the surface of the substrate so as to limit slide displacement of the movable element under the condition of a multi-directional overload situation.

Abstract: A micromechanical shock sensor includes a proof mass coupled to a surface of a substrate and a projection element extending laterally from the proof mass. The shock sensor further includes a latch mechanism and a retention anchor. The latch mechanism has a latch spring attached to the surface and a latch tip extending from a movable end of the latch spring. The retention anchor is attached to the surface and is located proximate the latch tip. The proof mass is configured for planar movement relative to the substrate when the proof mass is subjected to a force of at least a threshold magnitude. Movement of the proof mass in response to the force causes the latch tip to become retained between the projection element and the retention anchor to place the shock sensor in a latched state. The latched state may be detected by optical inspection, probe, or external readout.

Abstract: A microelectromechanical systems (MEMS) device is provided, which includes a substrate; a proof mass positioned in space above a surface of the substrate, where the proof mass is configured to move relative to the substrate; a flexible travel stop structure formed within the proof mass, where the flexible travel stop structure includes a contact lever connected to the proof mass via flexible elements; and a bumper formed on the surface of the substrate, where the contact lever is aligned to make contact with the bumper when the proof mass moves toward the substrate.