An electronic device has a fuse circuit including a semiconductor die and first and second bond wires, the semiconductor die having a bond pad and a fuse, the fuse having first and second portions, the bond pad coupled to the first portion of the fuse, and the second portion of the fuse coupled to a protected circuit, the first bond wire having a first end coupled to the bond pad and a second end coupled to a conductive terminal, and the second bond wire having a first end coupled to the second end of the first bond wire and a second end coupled to the conductive terminal.

A semiconductor package comprising a substrate including substrate pads on a top surface thereof, a first upper semiconductor chip on the substrate and including conductive chip pads, and bonding wires coupled to the substrate pads and the first upper semiconductor chip. The bonding wires include first and second bonding wires. The substrate has a first region between the conductive chip pads and the substrate pads, and a second region between the first region and the substrate pads. The second bonding wire has a maximum vertical level on the first region of the substrate. On the first region of the substrate, the first bonding wire is at a level higher than that of the second bonding wire. On the second region of the substrate, the second bonding wire is at a level higher than that of the first bonding wire.

A circuit structure including a pad assembly, a bonding pad assembly, and a bonding assembly is provided. The pad assembly includes a first pad, a second pad, and a third pad which are separated from one another. The bonding pad assembly is located on one side of the pad assembly and includes a first bonding pad. The bonding assembly includes a first bonding wire, a second bonding wire, and a plurality of bonding members. The first bonding wire is connected to the first bonding pad and the first pad. The second bonding wire is connected to the first bonding pad and the third pad. The bonding members are connected among the first pad, the second pad, and the third pad. The circuit structure provided here may have an improved wire bonding efficiency and an increased distribution density of bonding points, and the number of bonding wires may be reduced.

A semiconductor package includes a first semiconductor die, a semiconductor device comprising a second semiconductor die, and one or more wire bond structures. The wire bond structure includes a bond interface portion. The wire bond structure is arranged next to the first semiconductor die. The first semiconductor die and the bond interface portion of the wire bond structure are arranged at the same side of the semiconductor device. An interface contact structure of the semiconductor device is electrically connected to the wire bond structure.

An intelligent power module (IPM) comprises a first, second, third and fourth die supporting elements, a first group of insulated gate bipolar transistors (IGBTs), a second group of IGBTs, a first group of super-junction metal-oxide-semiconductor field-effect transistors (MOSFETs), a second group of super-junction MOSFETs, a fifth die supporting element, a low voltage IC, a high voltage IC, and a molding encapsulation. The low and high voltage ICs are attached to the fifth die supporting element. The molding encapsulation encloses the first, second, third and fourth die supporting elements, the first group of IGBTs, the second group of IGBTs, the first group of super-junction MOSFETs, the second group of super-junction MOSFETs, the fifth die supporting element, the low voltage IC, the high voltage IC.

Systems, methods, and devices related to techniques for repeating inter-die signals within a multi-die package of a memory device are disclosed. The multi-die package includes a memory stack including a first memory die handling interfacing with a host for the package and at least one second memory die coupled to and configured to communicate with the first memory die via an inter-die connection. A technique involves incorporating the use of a multiplexer positioned in front of the transmitter of each die to facilitate repetition of inter-die signals within the memory stack as needed depending on various factors associated with the memory stack, such as, but not limited to, the type of signal, the intended recipient of the inter-die signals, and the stack height of the memory stack.

Systems, methods, and devices related to techniques for reducing inter-die signal loads within a multi-die package are disclosed. The multi-die package includes a first memory die handling interfacing with a host for the package and at least one second memory die coupled to and configured to communication with the first memory die via an inter-die connection. A technique involves adding an additional wirebond pad to each die in the multi-die package. When the inter-die connections are made, the wirebond pad associated with the first memory die transmitter is connected to the wirebond pad associated with the receiver of a second memory die that is not connected to the transmitter of the second memory die. By not connecting to the transmitter of the second memory die, the first memory die transmits inter-die signals to the second memory die such that a lower signal load is achieved within the multi-die package.

An intelligent power module (IPM) comprises a first, second, third and fourth die supporting elements, a first group of insulated gate bipolar transistors (IGBTs), a second group of IGBTs, a first group of super-junction metal-oxide-semiconductor field-effect transistors (MOSFETs), a second group of super-junction MOSFETs, a fifth die supporting element, a low voltage IC, a high voltage IC, and a molding encapsulation. The low and high voltage ICs are attached to the fifth die supporting element. The molding encapsulation encloses the first, second, third and fourth die supporting elements, the first group of IGBTs, the second group of IGBTs, the first group of super-junction MOSFETs, the second group of super-junction MOSFETs, the fifth die supporting element, the low voltage IC, the high voltage IC.

A semiconductor package includes a first semiconductor die, a semiconductor device comprising a second semiconductor die, and one or more wire bond structures. The wire bond structure includes a bond interface portion. The wire bond structure is arranged next to the first semiconductor die. The first semiconductor die and the bond interface portion of the wire bond structure are arranged at the same side of the semiconductor device. An interface contact structure of the semiconductor device is electrically connected to the wire bond structure.

A circuit structure including a pad assembly, a bonding pad assembly, and a bonding assembly is provided. The pad assembly includes a first pad, a second pad, and a third pad which are separated from one another. The bonding pad assembly is located on one side of the pad assembly and includes a first bonding pad. The bonding assembly includes a first bonding wire, a second bonding wire, and a plurality of bonding members. The first bonding wire is connected to the first bonding pad and the first pad. The second bonding wire is connected to the first bonding pad and the third pad. The bonding members are connected among the first pad, the second pad, and the third pad. The circuit structure provided here may have an improved wire bonding efficiency and an increased distribution density of bonding points, and the number of bonding wires may be reduced.