A semiconductor device includes a substrate, a thermal conduction layer on the substrate, a first wire pattern on the thermal conduction layer, a first semiconductor pattern a second semiconductor pattern, and a gate electrode between the first semiconductor pattern and the second semiconductor pattern. The gate electrode surrounds a periphery of the first wire pattern. A concentration of impurity of the thermal conduction layer is different from that of the substrate. The first wire pattern includes a first end and a second end. The concentration of impurity contained in the first wire pattern is higher than that contained in the thermal conduction layer and that contained in the substrate. The first semiconductor pattern is in contact with the first end of the first wire pattern and the thermal conduction layer. The second semiconductor pattern is in contact with the second end of the first wire pattern.

Methods and apparatus for a power regulator according to various aspects of the present invention may comprise a sensor adapted to generate a measurement of a voltage or a current. A memory may store a correction parameter that corresponds to the measurement, and a correction system may be adapted to adjust the measurement according to the correction parameter.

A semiconductor device includes a plurality of die pad sections, a plurality of semiconductor chips, each of which is arranged in each of the die pad sections, a resin encapsulation portion having a recess portion for exposing at least a portion of the die pad sections, the resin encapsulation portion configured to cover the die pad sections and the semiconductor chips, and a heat radiation layer arranged in the recess portion. The heat radiation layer includes an elastic layer exposed toward a direction in which the recess portion is opened. The heat radiation layer directly faces at least a portion of the die pad sections. The elastic layer overlaps with at least a portion of the die pad sections when seen in a thickness direction of the heat radiation layer.

A power transistor includes an ambient temperature input, a local temperature sensor, an array of transistor cells, and a thermal feedback circuit. The ambient temperature input is configured to receive an ambient temperature signal that is representative of an ambient temperature of the power transistor. The array of transistor cells has a control input. The local temperature sensor is configured to provide a local temperature signal that is representative of a temperature of the array of transistor cells. The thermal feedback circuit is coupled to the ambient temperature input, the local temperature sensor, and the control input. The thermal feedback circuit is configured to modulate a control signal provided at the control input based on a difference between the ambient temperature signal and the local temperature signal.

A semiconductor device with a FINFET, which provides enhanced reliability. The semiconductor device includes a first N channel FET and a second N channel FET which are coupled in series between a wiring for output of a 2-input NAND circuit and a wiring for a second power potential. In plan view, a local wiring is disposed between a first N gate electrode of the first N channel FET and a second N gate electrode of the second N channel FET which extend in a second direction, and crosses a semiconductor layer extending in a first direction and extends in the second direction. The local wiring is coupled to a wiring for heat dissipation.

A semiconductor device includes a first gate electrode, a plurality of first source electrodes, a second gate electrode, and a plurality of second source electrodes. The first gate electrode is arranged with no other electrode between the first gate electrode and a first short side of the semiconductor substrate. The plurality of first source electrodes include a plurality of approximately rectangular first source electrodes arranged in stripes extending parallel to the lengthwise direction of the semiconductor substrate. The second gate electrode is arranged with no other electrode between the second gate electrode and a second short side of the semiconductor substrate. The plurality of second source electrodes include a plurality of approximately rectangular second source electrodes arranged in stripes extending parallel to the lengthwise direction of the semiconductor substrate.

A circuit layout includes a first device having a first set of fingers, wherein the first set of fingers is separated into a first finger group and a second finger group, the first finger group comprising a first number of fingers, and the second finger group comprising a second number of fingers. The circuit layout further includes a second device having a second set of fingers, wherein the second set of fingers includes a third finger group having a third number of fingers. The first finger group, the second finger group and the third finger group extend across a first doped region, and the third finger group is between the first finger group and the second finger group.

To provide a semiconductor device capable of restricting the substrate bias effect of a high-side transistor while enhancing the heat radiation property of a low-side transistor. A high-side NMOS transistor 101 is formed in a region S1 on the surface of a SOI substrate 30. A trench 41 surrounds the high-side NMOS transistor 101. SiO.sub.2 (first insulator) embeds the trench 41. A low-side NMOS transistor 102 is formed in a region S2 on the surface of the SOI substrate 30 around the trench 41. The side face Sf connecting the region S2 forming the low-side NMOS transistor 102 therein and the backside of the SOI substrate 30 is exposed.

A method of manufacturing an integrated circuit device includes providing a substrate comprising a semiconductor active layer, and forming source/drain regions, temperature sensors, and heating elements either in the semiconductor active layer or on the front side of the semiconductor active layer. The semiconductor active layer has channel regions between adjacent source/drain regions, and each of the heating elements is aligned over at least a portion of a corresponding temperature sensor. The method also includes forming a metal interconnect structure over the front side of the semiconductor active layer and exposing the channel regions from the back side of the semiconductor active layer substrate. A fluid gate dielectric layer is formed over the exposed channel regions.

Provided is a semiconductor device with a reduced variation in temperature among a plurality of unit transistors. A semiconductor device includes: a semiconductor substrate; and a transistor group including at least one column in which a plurality of unit transistors are aligned and arranged along a first axis on the semiconductor substrate. A first column of the at least one column includes: a first group of transistors including two of the unit transistors that are adjacent to each other with a first distance therebetween, and a second group of transistors including two of the unit transistors that are adjacent to each other with a second distance therebetween, the first group of transistors is disposed at a position closer to a center of the first column along the first axis than the second group of transistors, and the first distance is larger than the second distance.