Abstract: The performance of a semiconductor device is improved. An emitter electrode is coupled to a P-type body region and an N+-type emitter region of a linear active cell region via a contact groove formed on an interlayer insulating film and is coupled to a P-type body region of a linear hole connector cell region via a contact groove. The contact grooves arranged in the linear hole connector cell region are shorter than the contact groove in plan view.

Abstract: A semiconductor device includes a power device and a temperature detection diode. The semiconductor device has a device structure configured to insulate between a power lien of the power device and the temperature detection diode.

Abstract: A coil component has a magnetic body of rectangular solid shape, a coil with N turns (N is a positive number of 2 or greater) provided inside the magnetic body, an insulating intermediate part, and external electrodes. The coil has a first conductor layer, a second conductor layer, and an inter-layer connection part. The first conductor layer has a first multiple winding part which is wound around one axis with a first spacing. The second conductor layer has a second multiple winding part which is wound around the one axis with the first spacing and faces the first conductor layer. The insulating intermediate part is provided inside the magnetic body and forms, between the first conductor layer and second conductor layer, a second spacing corresponding to a thickness equal to or less than the product of the first spacing and (N?1).

Abstract: A linear active cell region is formed from a plurality of divided active cell regions arranged apart from each other in a second direction (y direction). The linear hole collector cell region is formed from a plurality of divided hole collector cell regions arranged apart from each other in the second direction (y direction). A P-type floating region is formed in a semiconductor substrate between the linear active cell region and the linear hole collector cell region adjacent to each other in a first direction (x direction), between the divided active cell regions adjacent to each other in the second direction (y direction), and between the divided hole collector cell regions adjacent to each other in the second direction (y direction).

Abstract: A semiconductor device includes: a semiconductor substrate having a main surface; a first insulating film formed in a convex shape and provided on the main surface of the semiconductor substrate; a first diffusion layer formed on the semiconductor substrate and provided to surround the first insulating film formed in a convex shape, the first diffusion layer being different in conductivity type from the semiconductor substrate; a first conductive layer formed so as to extend across the first insulating film formed in a convex shape, the first conductive layer forming a fuse element; and a second insulating film provided on the first conductive layer.

Abstract: A coil component is of the type where a helical coil is directly contacting a magnetic body where such coil component still meets the demand for electrical current amplification. The coil component is structured in such a way that a helical coil is covered with a magnetic body. The magnetic body is mainly constituted by magnetic alloy grains and contains substantially no glass component, and each of the magnetic alloy grains has an oxide film of the grain on its surface.

Abstract: In a method of further enhancing the performance of a narrow active cell IE type trench gate IGBT having the width of active cells narrower than that of inactive cells, it is effective to shrink the cells so that the IE effects are enhanced. However, when the cells are shrunk simply, the switching speed is reduced due to increased gate capacitance. A cell formation area of the IE type trench gate IGBT is basically composed of first linear unit cell areas having linear active cell areas, second linear unit cell areas having linear hole collector areas and linear inactive cell areas disposed therebetween.

Abstract: Reduction of power consumption of a semiconductor device is aimed. The semiconductor device includes a cell region where a vertical power MOSFET is formed and an intermediate region surrounding the cell region. In each of the cell region and the intermediate region, a plurality of p-type column regions and a plurality of n-type column regions are alternately formed. The n-type column region arranged in the cell region has a defect region formed therein, whereas the n-type column region arranged in the intermediate region does not have the defect region. A defect density in the n-type column region arranged in the cell region is larger than that in the n-type column region arranged in the intermediate region.

Abstract: In a method of further enhancing the performance of a narrow active cell IE type trench gate IGBT having the width of active cells narrower than that of inactive cells, it is effective to shrink the cells so that the IE effects are enhanced. However, when the cells are shrunk simply, the switching speed is reduced due to increased gate capacitance. A cell formation area of the IE type trench gate IGBT is basically composed of first linear unit cell areas having linear active cell areas, second linear unit cell areas having linear hole collector areas and linear inactive cell areas disposed therebetween.

Abstract: A semiconductor device includes a trench-gate IGBT enabling the fine adjustment of a gate capacitance independent from cell performance. In a gate wiring lead-out region, a plurality of trenches is arranged spaced apart from each other in an X direction perpendicular to a Y direction. Each trench has a shape enclosed by a rectangular outer outline and a rectangular inner outline in plan view. A trench gate electrode is provided in each of the trenches so as to be electrically coupled to an extraction electrode. To obtain an adequate breakdown voltage between a collector and an emitter, the trenches are formed in a p-type floating region. An n?-type drift region is formed in a region located inside an inner outline of the trench in plan view, whereby a capacitance formed between the trench gate electrode and the n?-type drift region is used as the reverse transfer capacitance.

Abstract: A switching loss is prevented from being deteriorated by suppressing increase in a gate capacitance due to a cell shrink of an IE type trench gate IGBT. A cell formation region is configured of a linear active cell region, a linear hole collector cell region, and a linear inactive cell region between them. Then, upper surfaces of the third and fourth linear trench gate electrodes which are formed so as to sandwich both sides of the linear hole collector cell region and electrically connected to an emitter electrode are positioned to be lower than upper surfaces of the first and second linear trench gate electrodes which are formed so as to sandwich both sides of the linear active cell region and electrically connected to a gate electrode.

Abstract: A semiconductor device includes: a semiconductor substrate having a main surface; a first insulating film formed in a convex shape and provided on the main surface of the semiconductor substrate; a first diffusion layer formed on the semiconductor substrate and provided to surround the first insulating film formed in a convex shape, the first diffusion layer being different in conductivity type from the semiconductor substrate; a first conductive layer formed so as to extend across the first insulating film formed in a convex shape, the first conductive layer forming a fuse element; and a second insulating film provided on the first conductive layer.

Abstract: To achieve a semiconductor device equipped with a low ON voltage and high load short circuit withstand trench gate IGBT. A collector region on a back surface of a semiconductor substrate is comprised of a relatively lightly-doped P+ type first collector region and a relatively heavily-doped P++ type second collector region. The P++ type second collector region includes, in plan view, interfaces between a first trench having therein a first linear trench gate electrode and an N+ type emitter region formed on the side surface of the first trench and between a second trench having therein a second linear trench gate electrode and an N+ type emitter region formed on the side surface of the second trench. This enables electrons injected from the surface side of the semiconductor substrate to reach the P++ type second collector region and offset, with them, holes injected from the back surface side of the semiconductor substrate.

Abstract: The surface of an interlayer insulating film formed over an emitter coupling portion and the surface of an emitter electrode formed over the interlayer insulating film are caused to have a gentle shape, in particular, at the end of the emitter coupling portion, by forming the emitter coupling portion over a main surface of a semiconductor substrate and integrally with trench gate electrodes in order to form a spacer over the sidewall of the emitter coupling portion. Thereby, stress is dispersed, not concentrated in an acute angle portion of the emitter coupling portion when an emitter wire is coupled to the emitter electrode (emitter pad), and hence occurrence of a crack can be suppressed. Further, by forming the spacer, the concavities and convexities to be formed in the surface of the emitter electrode can be reduced, whereby the adhesiveness between the emitter electrode and the emitter wire can be improved.

Abstract: The performance of a semiconductor device is improved. An emitter electrode is coupled to a P-type body region and an N+-type emitter region of a linear active cell region via a contact groove formed on an interlayer insulating film and is coupled to a P-type body region of a linear hole connector cell region via a contact groove. The contact grooves arranged in the linear hole connector cell region are shorter than the contact groove in plan view.

Abstract: A semiconductor device includes trench gate electrodes, an emitter coupling section that couples them with each other, an interlayer insulating film arranged in a hybrid sub-cell region and an inactive cell region, and a contact trench penetrating it. Also, the contact trench is divided in a crossing region of extending directions of the hybrid sub-cell region and the emitter coupling section. Further, an n+-type emitter region is disposed so as to be apart from an end of the divided contact trench. With such configuration of not forming the contact trench in the crossing region, the working failure of the contact trench can be reduced. Also, because the n+-type emitter region is disposed so as to be apart from the end of the contact trench, the breakdown resistance of the semiconductor device can be improved.

Abstract: A semiconductor device including an IGBT element having features of a low on-state voltage and a low turn-off loss is provided. The semiconductor device is comprised of a trench gate type IGBT element. The IGBT element includes: a plurality of gate trench electrodes to which gate potential is given; and a plurality of emitter trench electrodes to which emitter potential is given. Between adjacent trench electrodes, a contact to an emitter electrode layer is formed. In this regard, there is formed, in the semiconductor substrate, a P type floating region which is in contact with bottom portions of at least some of the emitter trench electrodes via an interlayer insulation layer.

Abstract: In characteristic test measurements of double-gate-in-trench p-channel power MOSFETs each having a p+ polysilicon gate electrode and a p+ field plate electrode in a trench, which were fabricated according to common design techniques, it has been found that, under conditions where a negative gate bias is applied continuously at high temperature with respect to the substrate, an absolute value of threshold voltage tends to increase steeply after the lapse of a certain period of stress application time. To solve this problem, the present invention provides a p-channel power MOSFET having an n-type polysilicon linear field plate electrode and an n-type polysilicon linear gate electrode in each trench part thereof.

Abstract: A method for manufacturing a magnetic grain compact, includes: providing multiple metal grains constituted by soft magnetic alloy containing Fe, Si, and a metal element M that oxidizes more easily than Fe; compacting the metal grains; and forming oxide film formed on a surface of the metal grains, and forming first bonding parts where adjacent metal grains are directly contacted and bonded together, and second bonding parts where adjacent metal grains are bonded together via the oxide film formed around the entire surface of said adjacent metal grains other than the first bonding parts, by applying heat treatment to the compacted metal grains, thereby obtaining a magnetic grain compact.

Abstract: Respective outer peripheral surfaces (33, 35) of opening-side end portions (30, 31) of a front cover (12) and a pump shell (7), which have been shaped by pressing, are formed by slimming such that the outside diameters of the slimmed outer peripheral surfaces are equal to each other. With the opening-side end portions abutting against each other, a high-energy beam such as a laser beam (R) is radiated toward the abutment surfaces (30, 31) from the radially outer side to weld the abutment surfaces to each other. Consequently, it is possible to perform welding accurately through easy processing in order to easily manufacture a fluid coupling with high precision that facilitates post-processing.