Abstract: A semiconductor component has a semiconductor body comprising a blocking pn junction, a source zone of a first conductivity type connected to a first electrode and bordering on a zone forming the blocking pn junction of a second conductivity type complementary to the first conductivity type, and a drain zone of the first conductivity type connected to a second electrode. The side of the zone of the second conductivity type facing the drain zone forms a first surface, and in the region between the first surface and a second surface located between the first surface and the drain zone, comprises areas of the first and second conductivity type nested in one another. The second surface is positioned at a distance from the drain zone such that the areas of the first and second conductivity type nested in each other do not reach the drain zone.

Abstract: A semiconductor component has at least one first terminal zone of a first conductivity type in a semiconductor body. The first terminal zone is contact-connected by a first terminal electrode. A drift zone of the first conductivity type is adjoined by a second terminal zone of the second conductivity type. A channel zone of a second conductivity type is formed between the at least one first terminal zone and the drift zone. A control electrode is insulated from the semiconductor body and adjacent to the channel zone. A first channel is formed by the channel zone in a region adjacent to the control electrode, the first channel conducts only upon application of a control voltage that is not equal to zero between the control electrode and the first terminal zone. The first terminal electrode is connected to the drift zone via at least one second channel of the first conductivity type, which already conducts in the event of a control voltage equal to zero.

Abstract: A vertical or lateral semiconductor component derives a signal from a high load voltage. This signal can be used directly for driving the semiconductor component or, alternatively, a control device.

Abstract: The invention relates to a configuration for generating a low-voltage signal proportional to the high voltage present between the source and the drain of a power transistor. For this purpose, a capacitive voltage divider including the source-gate capacitance serving as a low-voltage tap and the source-drain capacitance serving as a high-voltage element is situated in a voltage sense region.

Abstract: A semiconductor component has a semiconductor body comprising blocking pn junction, a source zone of a first conductivity type connected to a first electrode and bordering on a zone forming the blocking pn junction of a second conductivity type complementary to the first conductivity type, and a drain zone of the first conductivity type connected to a second electrode. The side of the zone of the second conductivity type facing the drain zone forms a first surface, and in the region between the first surface and a second surface located between the first surface and the drain zone, comprises areas of the first and second conductivity type nested in one another. The second surface coincides with the surface of the drain zone facing the source zone, such that the regions of the first and second conductivity type nested inside each other reach the drain zone.

Abstract: The invention relates to a high voltage resistant edge structure in the edge region of a semiconductor component which has floating guard rings of the first conductivity type and inter-ring zones of the second conductivity type which are arranged between the floating guard rings, wherein the conductivities and/or the inter-ring zones are set such that their charge carriers are totally depleted when blocking voltage is applied. The inventive edge structure achieves a modulation of the electrical field both at the surface and in the volume of the semiconductor body. If the inventive edge structure is suitably dimensioned, the field intensity maximum can easily be situated in the depth; that is, in the region of the vertical p-n junction. Thus, a suitable edge construction which permits a “soft” leakage of the electrical field in the volume can always be provided over a wide range of concentrations of p and n doping.

Abstract: A semiconductor component has at least one first terminal zone of a first conductivity type in a semiconductor body. The first terminal zone is contact-connected by a first terminal electrode. A drift zone of the first conductivity type is adjoined by a second terminal zone of the second conductivity type. A channel zone of a second conductivity type is formed between the at least one first terminal zone and the drift zone. A control electrode is insulated from the semiconductor body and adjacent to the channel zone. A first channel is formed by the channel zone in a region adjacent to the control electrode, the first channel conducts only upon application of a control voltage that is not equal to zero between the control electrode and the first terminal zone. The first terminal electrode is connected to the drift zone via at least one second channel of the first conductivity type, which already conducts in the event of a control voltage equal to zero.

Abstract: The invention relates to a configuration for generating a low-voltage signal proportional to the high voltage present between the source and the drain of a power transistor. For this purpose, a capacitive voltage divider including the source-gate capacitance serving as a low-voltage tap and the source-drain capacitance serving as a high-voltage element is situated in a voltage sense region.

Abstract: A vertical semiconductor component having a semiconductor body of a first conductivity type is described. In a surface region of the semiconductor body, at least one zone of a second conductivity type, opposite to the first conductivity type, is embedded. Regions of the second conductivity type are provided in the semiconductor body in a plane running substantially parallel to the surface of the surface region. The regions are in this case sufficiently highly doped that they cannot be depleted of charge carriers when a voltage is applied.

Abstract: The invention relates to a semiconductor component, in which regions of the conduction type opposite to the conduction type of the drift zone are incorporated in the drift zone and also in the region of the active zones.

Abstract: A vertically structured semiconductor power component is described. A layer thickness of a substrate of the power module between a pn junction and a metallized back is chosen in such a manner that a space charge region produced in the semiconductor component extends as far as the back when a blocking voltage between a source and a drain electrode is applied before a field strength produced by the applied blocking voltage reaches a critical value.

Abstract: A semiconductor component having a semiconductor body comprises a blocking pn junction, a source zone of a first conductivity type and bordering on a zone forming the blocking pn junction of a second conductivity type complementary to the first conductivity type, and a drain zone of the first conductivity type. The side of the zone of the second conductivity type faces the drain zone forming a first surface, and in the region between the first surface and a second surface areas of the first and second conductivity type are nested in one another. The areas of the first and second conductivity type are variably so doped that near the first surface doping atoms of the second conductivity type predominate, and near the second surface doping atoms of the first conductivity type predominate. Furthermore a plurality of floating zones of the first and second conductivity type is provided.

Abstract: A process for manufacturing of a semiconductor device comprising a blocking pn junction, a source zone of a first conductivity type connected to a first electrode and bordering on a zone forming the blocking pn junction of a second conductivity type complementary to the first conductivity type, and a drain zone of the first conductivity type connected to a second electrode, the side of the zone of the second conductivity type facing the drain zone forming a first surface, and in the region between the first surface and a second surface located between the first surface and the drain zone, areas of the first and second conductivity type nested in one another, comprises the step of: varying in individual semiconductor layers, by doping, the degree of compensation in the regions of the second conductivity type.

Abstract: A switching power supply including a power factor correction circuit comprises a rectifier, an inductor coupled in series with the rectifier, a semiconductor switch formed by a compensation device coupled in parallel with the rectifier and the inductor. The output circuit comprises a diode coupled in series with a capacitor both coupled in parallel with the semiconductor switch. An input current sensor, and a control unit for controlling the compensation device are provided.

Abstract: The invention relates to a semiconductor component having a first semiconductor zone of a first conduction type, a second semiconductor zone of a second conduction type and a drift zone arranged between the first and second semiconductor zones, which drift zone has at least two semiconductor zones doped complementarily to one another, the degree of compensation varying at least in a section of the drift zone in a direction perpendicular to a current flow direction running between the first and second semiconductor zones.

Abstract: A semiconductor component includes first and second connection zones formed in a semiconductor body, a channel zone surrounding the second connection zone in the semiconductor body, and a drift path that is formed between the channel zone and the first connection zone and contains a compensation zone. The compensation zone has a complementary conduction type with respect to the drift zone and includes at least two segments. A distance between the two adjacent segments is chosen such that the punch-through voltage between these segments lies in a voltage range that corresponds to the voltage range assumed by the voltage drop across the drift path at currents situated between the rated current and twice the rated current.

Abstract: A switching power supply including a power factor correction circuit comprises a rectifier, an inductor coupled in series with the rectifier, a semiconductor switch formed by a compensation device coupled in parallel with the rectifier and the inductor. The output circuit comprises a diode coupled in series with a capacitor both coupled in parallel with the semiconductor switch. An input current sensor, and a control unit for controlling the compensation device are provided.

Abstract: A semiconductor component has a semiconductor body comprising blocking pn junction, a source zone of a first conductivity type connected to a first electrode and bordering on a zone forming the blocking pn junction of a second conductivity type complementary to the first conductivity type, and a drain zone of the first conductivity type connected to a second electrode. The side of the zone of the second conductivity type facing the drain zone forms a first surface, and in the region between the first surface and a second surface located between the first surface and the drain zone, comprises areas of the first and second conductivity type nested in one another. The second surface coincides with the surface of the drain zone facing the source zone, such that the regions of the first and second conductivity type nested inside each other reach the drain zone.

Abstract: A semiconductor component has a semiconductor body comprising a blocking pn junction, a source zone of a first conductivity type connected to a first electrode and bordering on a zone forming the blocking pn junction of a second conductivity type complementary to the first conductivity type, and a drain zone of the first conductivity type connected to a second electrode. The side of the zone of the second conductivity type facing the drain zone forms a first surface, and in the region between the first surface and a second surface located between the first surface and the drain zone, comprises areas of the first and second conductivity type nested in one another. The second surface is positioned at a distance from the drain zone such that the areas of the first and second conductivity type nested in each other do not reach the drain zone.

Abstract: A semiconductor component having a semiconductor body comprises a blocking pn junction, a source zone of a first conductivity type and bordering on a zone forming the blocking pn junction of a second conductivity type complementary to the first conductivity type, and a drain zone of the first conductivity type. The side of the zone of the second conductivity type faces the drain zone forming a first surface, and in the region between the first surface and a second surface areas of the first and second conductivity type are nested in one another. The areas of the first and second conductivity type are variably so doped that near the first surface doping atoms of the second conductivity type predominate, and near the second surface doping atoms of the first conductivity type predominate. Furthermore a plurality of floating zones of the first and second conductivity type is provided.