A power delivery device includes a printed circuit board (PCB), a package device, and a chip connecting device. The PCB is configured to receive a first reference voltage and a second reference voltage. The package device is coupled to the PCB, and includes a bump array. The chip connecting device is coupled to the bump array of the package device, and configured to output a first supply voltage and a second supply voltage. The bump array includes first bumps and second bumps. The first bumps are configured to transmit the first reference voltage. The second bumps are configured to transmit the second reference voltage. The first bumps and the second bumps are disposed in parallel.

Embodiments may relate to a microelectronic package that includes a die coupled with a package substrate. A plurality of solder thermal interface material (STIM) thermal interconnects may be coupled with the die and an integrated heat spreader (IHS) may be coupled with the plurality of STIM thermal interconnects. A thermal underfill material may be positioned between the IHS and the die such that the thermal underfill material at least partially surrounds the plurality of STIM thermal interconnects. Other embodiments may be described or claimed.

An RF flip chip is provided in which a local bump region adjacent a die corner includes a balun having a centrally-located bump.

A semiconductor package includes a semiconductor chip with a normal connection electrode and a measurement connection electrode, formed on a first surface, and a substrate with a normal substrate pad, connected to the normal connection electrode, and a measurement substrate pad, connected to the measurement connection electrode. The normal substrate pad and the measurement substrate pad are formed on a surface that faces the first surface. The measurement connection electrode includes first and second edge measurement connection electrodes and first and second center measurement connection electrodes. The measurement substrate pad includes a center measurement substrate pad, a first edge measurement substrate pad, and a second edge measurement substrate pad. The first edge measurement connection electrode and the first center measurement connection electrode are electrically connected to each other, and the second edge measurement connection electrode and the second center measurement connection electrode are electrically connected to each other.

A driving chip and a display device are provided herein. The driving chip includes a substrate, a plurality of connection bumps and a plurality of buffer bumps on the substrate. Each of the connection bumps and the buffer bumps is disposed on a first substrate of the substrate. The buffer bump includes a first end face with a height a, and the connection bump has a connection bump end face with a height b, a<b. The height is a distance from a corresponding end face of the connection bump or the buffer bump to the first surface. With the buffer bumps on the driving chip, stress buffering can be achieved, which can further improve the bonding effect of the driving chip.

A driving chip and a display device are provided herein. The driving chip includes a substrate, a plurality of connection bumps and a plurality of buffer bumps on the substrate. Each of the connection bumps and the buffer bumps is disposed on a first substrate of the substrate. The buffer bump includes a first end face with a height a, and the connection bump has a connection bump end face with a height b, a<b. The height is a distance from a corresponding end face of the connection bump or the buffer bump to the first surface. With the buffer bumps on the driving chip, stress buffering can be achieved, which can further improve the bonding effect of the driving chip.

The present invention discloses a lead structure of the circuit, which comprises a first lead and a second lead. The first lead includes a first bump connecting part and a first lead segment. The first lead segment is connected to the first bump connecting part. The width of the first lead segment is smaller than the width of the first bump connecting part. The second lead is adjacent to the first lead and there is a lead gap therebetween. The second lead also includes a second bump connecting part and a first lead segment. The first lead segment of the second lead is connected to the second bump connecting part. The second bump connecting part and the first bump connecting part are arranged staggeredly. The second bump connecting part is adjacent to the first lead segment of the first lead.

A method for manufacturing an electronic package and a suction device are provided. The method includes: providing an electronic component having a first surface and including at least one conductive stud on the first surface; providing a suction device having at least one recess; and moving the electronic component with the suction device, wherein an edge of the at least one recess does not overlap the at least one conductive stud from a top view while moving the electronic component with the suction device.

Disclosed herein are microelectronic packages having thermally conductive layers and methods for manufacturing the same. The microelectronics packages may include a substrate and a plurality of dies connected to the substrate and/or each other to form a die stack. The dies may have a perimeter. A thermally conductive layer may be located in between the respective dies. The thermally conductive layers may extend past at least a portion of the perimeters, thereby providing enhanced cooling of the die stack.

A semiconductor package is provided. The semiconductor package includes a substrate including first and second surfaces opposite to each other, a redistribution layer on the first surface and having third and fourth surfaces opposite to each other wherein the third surface of the redistribution layer faces the first surface, a semiconductor chip between the substrate and the redistribution layer, the semiconductor chip spaced apart from the first surface and electrically connected to the third surface, a connection structure between the substrate and the redistribution layer and horizontally spaced apart from the semiconductor chip wherein the connection structure is electrically connected to the first surface and the third surface, and a dielectric layer between the substrate and the redistribution layer. The dielectric layer covers the semiconductor chip and the connection structure and extends between the semiconductor chip and the first surface.