Abstract: A control device for semiautomatic gearshifting mechanisms of motor vehicles has a selector shaft of a gearshifting mechanism and at least one rotatable shifting element acting on the selector shaft so as to rotate and axially move the selector shaft for selecting a gutter and shifting a gear. A switching valve actuates the at least one shifting element for rotating the selector shaft and for axially moving the selector shaft. The shifting element is a shift drum with at least one control curve. The control curve is a groove in the mantle of the shifting element. The control device provides a simplified hydraulic control of the switching valves and has a simplified configuration.

Abstract: An actuating device for a differential lock has a piston housing having a pressure chamber. An actuator piston is arranged in the pressure chamber of the piston housing. A hydraulic medium tank is provided. A pump conveys a hydraulic medium from the tank to one end of the actuator piston, wherein the actuator piston can move in the pressure chamber and acts on the lock when loaded by the hydraulic medium. One or more conduits connect the hydraulic medium tank and the pressure chamber to one another. The conduit has a temperature-dependent throttle element for adjusting a flow cross-section for the hydraulic medium based on the temperature of the hydraulic medium.

Abstract: An electronic-hydraulic control device for gearboxes of vehicles, preferably motor vehicles, includes a housing in which an electronic unit for controlling magnetic valves is accommodated. The valves are supplied with a pressure medium. The housing has a magnetic housing part in which magnetic parts of the magnetic valves and the electronic unit of the control device are accommodated and which lies outside the gearbox, and a hydraulic housing part in which hydraulic parts of the magnetic valves are located and which is positioned at least partially inside the gearbox housing.

Abstract: A hydraulic system for actuating at least two operating systems of a motor vehicle has a first hydraulic medium reservoir for storing a hydraulic medium. A distribution valve is connected to the first hydraulic medium reservoir and to the operating systems of the motor vehicle. A control unit is connected to the distribution valve which is configured to distribute the hydraulic medium from the first hydraulic medium reservoir to the operating systems of the motor vehicle and to control flow of the hydraulic medium to the operating systems of the motor vehicle such that one of the operating systems has priority with regard to supply of the hydraulic medium. A first one of the operating systems is a brake device having a brake power assist unit, a brake valve, and a master brake cylinder. The brake power assist unit is connected via the brake valve to the control unit.

Abstract: A semiconductor component includes an asymmetric transistor having two lightly doped drain regions (1300, 1701), a channel region (1702), a source region (1916) located within the channel region (1702), a drain region located outside the channel region (1702), a dielectric structure (1404) located over at least one of the two lightly doped drain regions (1300, 1701), two gate electrodes (1902, 1903) located at opposite sides of the dielectric structure (1404), a drain electrode (1901) overlying the drain region (1915), and a source electrode (1904) overlying the source region (1916). The semiconductor component also includes another transistor having an emitter electrode (122) located between a base electrode (121) and a collector electrode (123) where the base electrode (121) is formed over a dielectric structure (1405).

Abstract: An insulated gate semiconductor device (10) has a double spacer gate structure (45). To form the gate structure (45), a stack having sidewalls (22) is formed over a major surface (12) of a semiconductor substrate (11). A gate oxide (23) is then formed over the major surface (12) adjacent the sidewalls (22). A first polysilicon layer (24) is deposited on the gate oxide (23) and the stack. The first polysilicon layer (24) is etched to form a first conductive spacer (32) of the gate structure (45). A second polysilicon layer (44) is deposited on first spacer (32) and the stack. The second polysilicon layer (44) is then etched to form a second conductive spacer (46) of the gate structure (45). Because the double spacer gate structure (45) is formed without relying on photolithographic techniques, its size is smaller than the size of a gate structure formed using conventional photolithography.

Abstract: A semiconductor component includes an asymmetric transistor having two lightly doped drain regions (1300, 1701), a channel region (1702), a source region (1916) located within the channel region (1702), a drain region located outside the channel region (1702), a dielectric structure (1404) located over at least one of the two lightly doped drain regions (1300, 1701), two gate electrodes (1902, 1903) located at opposite sides of the dielectric structure (1404), a drain electrode (1901) overlying the drain region (1915), and a source electrode (1904) overlying the source region (1916). The semiconductor component also includes another transistor having an emitter electrode (122) located between a base electrode (121) and a collector electrode (123) where the base electrode (121) is formed over a dielectric structure (1405).

Abstract: A graded-channel semiconductor device (10) is formed in a pedestal (12). The pedestal (12) is formed on a substrate (11) and improves the electrical characteristics of the device (10) compared to conventional device structures. The pedestal (12) has sides (13) that are bordered by a first dielectric layer (24) to provide electrical isolation. An interconnect structure (90) can be optionally formed in conjunction with the formation of the device (10). The interconnect structure (90) has a plurality of conductors (60,97) that can be used to transport electrical signals across the device (10).

Abstract: A semiconductor device (10) is formed in a pedestal structure (16) overlying an epitaxial layer (12) and a semiconductor substrate (11). The semiconductor device (10) includes a doped region (13) that forms a PN junction with the epitaxial layer (12). The semiconductor device (10) also includes a dielectric layer (22) that has an opening (23) that exposes a portion of the doped region (13) and an opening (24) that exposes a portion of the epitaxial layer (12). The openings (23, 24) are filled with a conductive material (36, 37) to provide contacts (100, 101). Due to the presence of the PN junction, the contacts (100, 101) are capacitively coupled to each other.

Abstract: A circuit and method protect a transistor (68, 70) from damage when controlling an input signal (V.sub.PROG) that exceeds a gate to channel stress voltage of the transistor. A small, low current protection transistor (64, 66) is serially coupled to the gate electrode of the transistor being protected. The gate of the protection transistor is biased to a voltage (V.sub.P, V.sub.N) of lower magnitude than the input signal to limit the voltage applied to the gate of the protected transistor to a value within the stress voltage of the protected transistor.

Abstract: An SRAM memory cell (40) uses GCMOS transistors (42, 44, 56, and 58) for improving discharge of complementary bit lines (60 and 62). The GCMOS transistors (42, 44, 56, and 58) have a graded-channel region on only the source side of the transistors. Configuring the pass-transistors (56 and 58) having the drain terminals connected to the complementary bit lines (60 and 62) and the cross-coupled transistors (42 and 44) having drain terminals connected to the memory cell outputs improves timing for a read operation of the memory cell (40).

Abstract: The invention concerns an implantable infusion pump for dosed emission of medicines into the human body comprising a pump chamber formed by an upper chamber portion (3) and a lower chamber portion (2), whereby said pump chamber is divided by a flexible membrane (6) into a pressure chamber (8) and a medicine reservoir (7). Refill apertures (12, 14) covered by septa (13, 15) are further provided. The septa (13, 15) are hermetically clamped by holders (4, 5). According to the invention, catch connections are used as main connections (31, 32, 33) and as ancillary connections (34, 35) for the connection of the pump components (2, 3, 4, 5), whereby the main connections (31, 32, 33) substantially support the interior pressure strain generated under normal operating load and the locked ancillary connections (34, 35) are hereby not or only nimimally brought into operation due to respective arrangement and dimensioning of the catch members.

Abstract: A graded-channel semiconductor device (10) is formed in a pedestal (12). The pedestal (12) is formed on a substrate (11) and improves the electrical characteristics of the device (10) compared to conventional device structures. The pedestal (12) has sides (13) that are bordered by a first dielectric layer (24) to provide electrical isolation. An interconnect structure (90) can be optionally formed in conjunction with the formation of the device (10). The interconnect structure (90) has a plurality of conductors (60, 97) that can be used to transport electrical signals across the device (10).

Abstract: An insulated gate semiconductor device (10) has a double spacer gate structure (45). To form the gate structure (45), a stack having sidewalls (22) is formed over a major surface (12) of a semiconductor substrate (11). A gate oxide (23) is then formed over the major surface (12) adjacent the sidewalls (22). A first polysilicon layer (24) is deposited on the gate oxide (23) and the stack. The first polysilicon layer (24) is etched to form a first conductive spacer (32) of the gate structure (45). A second polysilicon layer (44) is deposited on first spacer (32) and the stack. The second polysilicon layer (44) is then etched to form a second conductive spacer (46) of the gate structure (45). Because the double spacer gate structure (45) is formed without relying on photolithographic techniques, its size is smaller than the size of a gate structure formed using conventional photolithography.

Abstract: A differential amplifier (10) includes three unilateral field effect transistors (12, 14, 16) formed in a common well (40) of a semiconductor material. Each of the three unilateral field effect transistors (12, 14, 16) has an asymmetric channel doping profile. The performance of the differential amplifier (10) is significantly improved by properly orienting the three unilateral field effect transistors (12, 14, 16).

Abstract: A graded-channel semiconductor device (10) is formed in a pedestal (12). The pedestal (12) is formed on a substrate (11) and improves the electrical characteristics of the device (10) compared to conventional device structures. The pedestal (12) has sides (13) that are bordered by a first dielectric layer (24) to provide electrical isolation. An interconnect structure (90) can be optionally formed in conjunction with the formation of the device (10). The interconnect structure (90) has a plurality of conductors (60,97) that can be used to transport electrical signals across the device (10).

Abstract: A body fluid measurement apparatus for continually monitoring the body fluids produced by a catheterized patient is disclosed. The apparatus comprises a discharge hose in fluid communication with the patient, a housing that supports the discharge hose, a dripping chamber for temporarily holding the body fluid while temperature and electrical conductivity measurements are made, a force transducer for producing a signal representing the weight of the body fluid mass collected, a container for collecting the body fluid that is suspended from the force transducer, a storage cell power source, and a computer for processing a signal generated by the force transducer, for generating a timing signal, and for computing the patient's body fluid volume flow in a certain time interval. All computed measurements are sent to a display also located on the apparatus.

Abstract: A compact diode-connected semiconductor device (20) and a method of manufacturing the field effect transistor (10). A doped layer (44) is formed in a semiconductor substrate (41) which serves as a drain extension region. An oxide layer (46) is formed on the semiconductor substrate (41) and an opening (50) is formed in the oxide layer (46). A gate structure (81) having an active gate portion (78) and a gate shorting structure (22) are formed on the oxide layer (46). The gate shorting structure (22) and the portion of the semiconductor substrate (41) adjacent the active gate portion (78) are doped with an impurity material of the same conductivity type as the doped layer (44). The gate shorting structure (22) serves as a source of impurity material for the drain region.

Abstract: A graded-channel semiconductor device (10) includes a substrate region (11) having a major surface (12). A source region (13) and a drain region (14) are formed in the substrate region (11) and are spaced apart to form a channel region (16). A doped region (18) is formed in the channel region (16) and is spaced apart from the source region (13), the drain region (14), and the major surface (12). The doped region (18) has the same conductivity type as the channel region (16), but has a higher dopant concentration. The device (10) exhibits an enhanced punch-through resistance and improved performance compared to prior art short channel structures.

Abstract: An insulated gate field effect transistor (10) having an reduced gate to drain capacitance and a method of manufacturing the field effect transistor (10). A dopant well (13) is formed in a semiconductor substrate (11). A gate oxide layer (26) is formed on the dopant well (13) wherein the gate oxide layer (26) and a gate structure (41) having a gate contact portion (43) and a gate extension portion (44). The gate contact portion (43) permits electrical contact to the gate structure (41), whereas the gate extension portion (44) serves as the active gate portion. A portion of the gate oxide (26) adjacent the gate contact portion (43) is thickened to lower a gate to drain capacitance of the field effect transistor (10) and thereby increase a bandwidth of the insulated gate field effect transistor (10).