The present invention relates to an improved electronic circuit, as well as an improved substrate with electronic circuits, with an identification pattern. The invention makes it possible to make them identifiable and amongst other things to retrace the circuit(s) in this way through the production process. Furthermore, the invention relates to an improved production method for circuits and substrates according to the invention.

The present application provides a semiconductor module and a power conversion device wherein wiring inductance is reduced. The semiconductor module is characterized by including a semiconductor element, a first terminal on which the semiconductor element is mounted, a second terminal disposed in a periphery of the semiconductor element and having a multiple of wiring portions, and a multiple of connection lines extending in multiple directions from an upper face of the semiconductor element and connected to each of the multiple of wiring portions of the second terminal, wherein a free region is provided among the multiple of wiring portions, and the multiple of connection lines and the multiple of wiring portions forming current paths with each of the multiple of connection lines are of the same potential.

A semiconductor device includes a semiconductor chip having a device forming surface on which a device structure is formed, a first conductive layer formed on the device forming surface of the semiconductor chip, a second conductive layer formed on the first conductive layer, a first wire that is connected to the second conductive layer and that is made of a material composed mainly of copper, and a third conductive layer that is formed between the first conductive layer and the second conductive layer and that includes a material harder than copper.

An object is to provide a technique capable of improving the power efficiency of a semiconductor device. The semiconductor device includes first to sixth parallel connection bodies, each including a semiconductor switching element and a diode connected in antiparallel to the semiconductor switching element. At least one of the voltage drops of the second parallel connection body and the third parallel connection body is smaller than a voltage drop of at least one of the first parallel connection body, the fourth parallel connection body, the fifth parallel connection body, and the sixth parallel connection body.

A circuit is disclosed. The circuit includes a first transistor including a first drain terminal, a first gate terminal and a first source terminal, a depletion-mode transistor including a second drain terminal, a second gate terminal and a second source terminal, the second drain terminal connected to the first drain terminal, the depletion-mode transistor arranged to sense a first voltage at the first drain terminal and generate a second voltage at the second source terminal, and a comparator arranged to receive the second voltage, and transition the first transistor from an on state to an off state in response to the first transistor entering its saturation region of operation. In one aspect, the first transistor includes gallium nitride (GaN). In another aspect, the circuit further includes a logic circuit arranged to receive an output voltage generated by the comparator and to drive the first gate terminal.

A semiconductor package includes a package substrate having a first side portion adjacent to a first edge, and a second side portion adjacent to a second edge opposite the first edge; a plurality of first substrate pads on the package substrate at the first side portion of the package substrate; a first chip on the package substrate; a second chip stacked on the first chip in a step-wise manner to result in a first exposure region exposing a portion of a surface of the first chip with respect to the second chip due to the step-wise stacking, the first exposure region being adjacent to a first edge of the first chip; a plurality of first bonding pads on a first portion of the first exposure region, the first portion of the first exposure region being adjacent to the first edge of the first chip; a plurality of second bonding pads on a second portion of the first exposure region, the second portion of the first exposure region further from the first edge of the first chip than the first portion of the first exposure region is to the first edge of the first chip, the plurality of second bonding pads being electrically insulated from any circuit components in the first chip; a plurality of third bonding pads on a surface of the second chip; and a plurality of bonding wires electrically connecting the third bonding pads to the first substrate pads via the second bonding pads.

Multichip package manufacturing process is disclosed to form external pins at one side or each side of die-bonding area of package carrier board and to bond first IC and second IC to die-bonding area in stack. First IC and second IC each comprise transistor layer with core circuits, plurality of metal layers, plurality of VIA layers and solder pad layer. During production of first IC, design of at least one metal layer, VIA layer and dummy pads can be modified according to change of design of second IC. After chip probing, die sawing and bonding, wire bonding, packaging and final test are performed to package the package carrier board, first IC and second IC into automotive multichip package, achieving purpose of first IC only need to modify at least one layer or more than one layer to cooperate with second IC design change to carry out multichip packaging process.

A semiconductor device includes a substrate, a semiconductor chip, a plurality of bonding pads on a surface of the semiconductor chip, a plurality of probe pads on a surface of the semiconductor chip, a plurality of connection pads on a surface of the substrate, and a plurality of bonding wires that electrically connect the bonding pads and the connection pads. The plurality of bonding pads include a first bonding pad and a second bonding pad, the plurality of probe pads include a first probe pad and a second probe pad, and a part of the first probe pad is disposed between the second bonding pad and the second probe pad.

A semiconductor device of embodiments includes: a die pad including a first region and a second region surrounding the first region and thinner than the first region; a semiconductor chip including an upper electrode, a lower electrode, and a silicon carbide layer between the upper electrode and the lower electrode and provided on an inner side rather than the second region on a surface of the die pad; and a connection layer for connecting the lower electrode to the surface.

A semiconductor device of an aspect of the disclosure includes a switching element, a substrate, a front electroconductive layer, first through third terminals and a sealing resin. The first through third terminals project toward the same side from the sealing resin along a first direction crossing the substrate thickness direction. The first through third terminals are spaced apart in a second direction crossing the thickness and first directions. The first terminal is at an outermost side in the second direction among the first through third terminals. The sealing resin has root-side and tip-side parts. The root-side part is between the first and third terminals in the second direction and offset in the first direction toward the switching element side of the first and third terminals. The tip-side part is offset in the first direction toward the tip side of the first and third terminals exposed from the sealing resin.