The present disclosure relates to a power semiconductor module including: a carrier; a plurality of semiconductor dies mounted onto the carrier; a housing including a frame enclosing the carrier circumferentially; a first external connection electrically connected to a first subset of the semiconductor dies, the first external connection protruding laterally from the housing at a first level; and an insert including an electrically isolating material and a second external connection mounted onto the electrically isolating material. The insert is at least partially mounted to the frame and at least partially covers the carrier and/or the first subset of the plurality of semiconductor dies. The second external connection is connected to a second subset of the plurality of semiconductor dies. The second external connection protrudes from the housing.

A display device includes: a first substrate; a plurality of light-emitting elements on the first substrate; a second substrate opposite to the first substrate, and including one face facing the first substrate, and an opposite face to the one face; a plurality of grooves at the opposite face of the second substrate; a plurality of wavelength conversion layers, each of the wavelength conversion layers being located in a corresponding groove of the plurality of grooves to convert a wavelength of light emitted from a corresponding light-emitting element of the plurality of light-emitting elements; and a plurality of color filters on the wavelength conversion layers, respectively.

The present disclosure generally relates to a capacitor on an integrated circuit (IC) die. In an example, a package includes first and second IC dice. The first IC die includes a first circuit, a capacitor, and a polyimide layer. The first circuit is on a substrate. The capacitor includes a bottom plate over the substrate and a top plate over the bottom plate. The polyimide layer is at least partially over the top plate. A distance from a top surface of the top plate to a bottom surface of the polyimide layer is at least 30% of a distance from a top surface of the bottom plate to a bottom surface of the top plate. A signal path, including the capacitor, is electrically coupled between the first circuit and a second circuit in the second IC die, which does not include a galvanic isolation capacitor in the signal path.

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.

Aspects disclosed in the detailed description include an integrated circuit (IC) package employing a metal block with metal interconnects thermally coupling a semiconductor die (die) to an interposer substrate for dissipating thermal energy in the die. The die is coupled to a package substrate to provide signal routing paths to the die. To facilitate additional dies being stacked in the IC package as a three-dimensional (3D) IC (3DIC) package, the IC package also includes an interposer substrate adjacent to the die. The interposer substrate supports providing additional signal routing paths to the package substrate. The interposer substrate also includes a metal block which comprises a plurality of metal layers and is thermally coupled to the die and a metal interconnect(s) in the interposer substrate to dissipate thermal energy from the die through the metal block and through the coupled metal interconnect(s).

A method of determining a sequence for creating a plurality of wire loops is provided. The method includes (a) providing workpiece data for a workpiece. The workpiece data includes (i) position data for bonding locations of the workpiece, and (ii) wire loop data for a plurality of wire loops providing interconnection between ones of the bonding locations. The method also includes (b) analyzing the workpiece data. The step of analyzing includes considering overlap conditions between ones of the plurality of wire loops, considering wire loop heights of ones of the plurality of wire loops, considering lateral bend conditions between ones of the plurality of wire loops, and considering wire loop positions for ones of the plurality of wire loops. The method also includes (c) providing a sequence of creating the plurality of wire loops in connection with the workpiece at least partially based on the results of step (b).

Implementations of a semiconductor package may include a metal containing substrate including a solder preform coupled thereto and a laminated substrate including an opening. The laminated substrate may be fixedly coupled to the metal containing substrate through the solder preform.

A semiconductor package includes: a package substrate including a plurality of insulating layers and a plurality of metal pattern layers respectively disposed on the plurality of insulating layers, wherein each of the plurality of metal pattern layers has an interconnection layer; at least one semiconductor chip disposed on an upper surface of the package substrate, and connected to the interconnection layer; contact pads disposed on a lower surface of the package substrate, and connected to the interconnection layer; and non-contact pads disposed on the lower surface of the package substrate, and insulated from the interconnection layer, wherein a lowermost metal pattern layer among the plurality of metal pattern layers has a first open region at least partially overlapping at least one non-contact pad among the non-contact pads, in a direction perpendicular to the upper surface of the package substrate.

A semiconductor package includes a package substrate, a plurality of first semiconductor chips stacked on an upper surface of the package substrate in a stair-step configuration, the plurality of first semiconductor chips having an uppermost semiconductor chip at a first height from the upper surface of the package substrate, the uppermost semiconductor chip including a free end portion. Conductive wires respectively electrically connect chip pads of the first semiconductor chips to substrate pads of the package substrate. A plurality of first support structures each have a first end attached to the upper surface of the package substrate and an opposite second end attached to the free end portion of the uppermost semiconductor chip. The first support structures are inclined at an angle relative to the package substrate.