This semiconductor module includes: a base plate formed in a plate shape; a terminal member; an electronic component joined to one surface of the base plate; and mold resin sealing the base plate, the terminal member, and the electronic component. The base plate and the terminal member are conductive members and are arranged with an interval therebetween on the same plane. Each of the base plate and the terminal member has a body portion and a terminal portion exposed to outside from the mold resin. The base plate has a through hole at an extension part which is a part extending toward the terminal portion and connected to the terminal portion, in the body portion.

Embodiments described herein provide techniques for testing a semiconductor package by using a diode to couple a test pad to a contact pad. In one scenario, a package comprises a die stack comprising one or more dies and a molding compound encapsulating the die stack. In this package, a substrate is over the molding compound. Also, a test pad and a contact pad are on a surface of the substrate. The contact pad is coupled to the die stack. A diode couples the test pad to the contact pad. In one example, the test pad is coupled to a P side of the diode's P-N junction and the contact pad is coupled to an N side of the diode's P-N junction. In operation, current can flow from the test pad through the contact pad (and the die stack), but current cannot flow from the contact pad through the test pad.

A semiconductor package includes a first die pad, a first semiconductor die mounted on the first die pad, an encapsulant body of electrically insulating material that encapsulates first die pad and the first semiconductor die, a plurality of package leads that each protrude out of a first outer face of the encapsulant body, a connection lug that protrudes out of a second outer face of the encapsulant body, the second outer face being opposite from the first outer face. The first semiconductor die includes first and second voltage blocking terminals. The connection lug is electrically connected to one of the first and second voltage blocking terminals of the first semiconductor die. A first one of the package leads is electrically connected to an opposite one of the first and second voltage blocking terminals of the first semiconductor die that the first connection lug is electrically connected to.

A semiconductor device, including an insulated circuit substrate that has a base plate, a resin layer disposed on a front surface of the base plate, and a circuit pattern disposed on a front surface of the resin layer; and a semiconductor chip that is rectangular in a plan view of the semiconductor device and is bonded to a front surface of the circuit pattern in such a manner that a side edge of the semiconductor chip is spaced inwardly from an outer peripheral edge of the circuit pattern by at least a predetermined distance. Both the predetermined distance and a thickness of the circuit pattern are greater than or equal to 0.1 of a length of one side of the semiconductor chip.

A half bridge power module (1) comprising a substrate (2) comprising an inner load track (11), two intermediate load tracks (12, 14) and two outer load tracks (10,13), wherein an external terminal is mounted on one of the intermediate load tracks (12, 14), an external terminal (3, 4) is mounted on one of the outer load tracks (10, 13) and an external terminal (5) is mounted on the inner load track (11); wherein semiconductor switches (101, 12, 105, 106) are mounted on the outer load tracks (10, 13) and are electrically connected to the intermediate load track (12); and semiconductor switches (103, 104, 107, 108) are mounted on the intermediate load tracks (12, 14) and are electrically connected to the inner load track (11).

A radio-frequency module includes: a transmitting circuit disposed on a mounting substrate to process a radio-frequency signal input from a transmission terminal and to output a resultant signal to a common terminal; a receiving circuit disposed on the mounting substrate to process a radio-frequency signal input from the common terminal and to output a resultant signal to a reception terminal; a first inductor included in a first transmitting circuit; and a bonding wire connected to the ground and bridging over the first inductor.

Provided is a semiconductor module having a P-side arm circuit and an N-side arm circuit. The semiconductor module comprises: a P terminal on a high-voltage side; an N terminal on a low-voltage side; a plurality of wiring patterns separated from each other; and a transistor and a diode connected in parallel in each of the circuits, wherein the plurality of wiring patterns include a first wiring pattern, a second wiring pattern, and a third wiring pattern, the P terminal is connected to the first wiring pattern, the N terminal is connected to the second wiring pattern, an anode electrode of the diode of the N-side arm circuit is arranged above the second wiring pattern and is connected to the second wiring pattern, and an anode electrode of the diode of the P-side arm circuit is arranged above the third wiring pattern and is connected to the third wiring pattern.

According to the present disclosure, a method of manufacturing a semiconductor device includes the steps of (a) preparing a lead frame including a switching element die pad, a control element die pad, and a third-side side rail portion, (b) mounting a switching element and a diode element on the switching element die pad and mounting a control element configured to control the switching element on the control element die pad, (c) sealing the switching element, the diode element, and the control element with a mold resin such that the power side terminal, the control side terminal, and a part of the third-side side rail portion protrude outward, and (d) forming a third-side side rail terminal by cutting the third-side side rail portion, the third-side side rail terminal extending from a part of the third-side side rail portion.

A power module includes a substrate that is electrically insulative and includes a substrate main surface and a substrate back surface at opposite sides in a thickness direction. The power module also includes a mounting layer that is conductive and arranged on the substrate main surface. The power module further includes a graphite plate having anisotropic thermal conductivity and including a plate main surface and a plate back surface at opposite sides in the thickness direction. The plate back surface is connected to the mounting layer. The power module further includes a power semiconductor element arranged on the plate main surface.

In order to improve productivity of a semiconductor device, while improving stability of the blocking voltage of the semiconductor device, this semiconductor device is characterized by having a semiconductor element, and a laminated structure having three resin layers, said laminated structure being in a peripheral section surrounding a main electrode on one surface of the semiconductor element. The semiconductor device is also characterized in that the laminated structure has, on the center section side of the semiconductor element, a region where a lower resin layer is in contact with an intermediate resin layer, and a region where the lower resin layer is in contact with an upper resin layer.