A package structure is disclosed. The package structure includes processor die connected to a top surface of a package substrate. The package structure further includes a DC-DC power converter attached to a bottom surface of the package substrate. The DC-DC power converter is located at least within an open area of an interconnect component that connects the bottom surface of the package substrate and a top surface of a motherboard.

An electronic assembly includes an electronic package connected to a host circuit board. The electronic assembly includes interposer assemblies electrically connected to the electronic package. The electronic assembly includes cable modules coupled to upper separable interface of the interposer assemblies. The electronic assembly includes carrier assemblies configured to be coupled to an upper surface of the electronic package. Each carrier assembly includes a carrier base block and a carrier lid configured to hold at least one interposer assembly and at least one cable module. The carrier assemblies hold the cable modules with the module contacts in electrical connection with upper mating interfaces of the interposer contacts. The carrier assemblies hold lower mating interfaces of the interposer contacts in electrical connection with upper package contacts of the electronic package. The carrier assemblies are separately removable from the electronic package to separate the interposer assemblies from the electronic package.

A method of manufacturing an electronic module includes supplying paste to an electronic component and/or a wiring board. The paste includes solder powder and first resin. The method includes supplying second resin to the electronic component and/or the wiring board. The method includes placing one of the electronic component and the wiring board on another. The method includes curing the second resin to form a second resin portion. The method includes heating the paste to a temperature equal to or higher than a solder melting point after the second resin portion is formed. The method includes solidifying molten solder at a temperature lower than the solder melting point to form a solder portion that bonds the electronic component and the wiring board. The method includes curing the first resin after the solder portion is formed, to form a first resin portion.

This application relates to the field of power supply packaging technologies, and in particular, to a PCB-pinout based packaged module, including a packaged module and a pin exposed outside the packaged module. The packaged module includes a PCB and a power component. The PCB has a first surface and a second surface that are disposed opposite to each other, and the power component is disposed on the first surface or the second surface of the PCB. The power component performs communication connection with a pin located on one side of the first surface or one side of the second surface of the PCB through surface-layer copper of the PCB. The pin located on one side of the first surface or one side of the second surface of the PCB is a surface-layer copper etching pattern that is located on the PCB and that is exposed outside the packaged module.

Various exemplary embodiments relate to a printed circuit board (PCB) for electrically connecting a discrete array component including a pattern formed on the PCB which is a merger of a set of via pads and a discrete array component; wherein the pattern is generated by a pin mapping between the discrete array component and a via grid array on the PCB; and wherein the pattern is formed of a metal etched during a manufacturing process of the PCB.

In various embodiments, a chip card module is provided. The chip card module includes a chip card module contact array having six contact pads that are arranged in two rows having three contact pads each in accordance with ISO 7816, and three additional contact pads that are arranged between the two rows. Each additional contact pad is electrically conductively connected to a respective associated contact pad from a row from the two rows.

A communication method and system for converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT) are provided. The disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. According to the disclosure, an antenna module includes a first substrate layer on which at least one substrate is stacked; an antenna coupled to an upper end surface of the first substrate layer; a second substrate layer having an upper end surface coupled to a lower end surface of the first substrate layer and on which at least one substrate is stacked; and a radio frequency (RF) element coupled to a lower end surface of the second substrate layer.

Apparatuses, systems and methods associated with electrical fast transient tolerant input/output (I/O) communication (e.g., universal serial bus (USB)) design are disclosed herein. In embodiments, an apparatus to mount an integrated circuit (IC) package, may include a printed circuit board (PCB), a plurality of pogo pins, and a mounting mechanism. The plurality of pogo pins may be mounted to electrical contacts of the PCB, the plurality of pogo pins may be coupled to the electrical contacts at first ends of the plurality of pogo pins and may be to couple to the IC package at second ends of the plurality of pogo pins. The mounting mechanism may position the IC package on the second ends of the plurality of pogo pins. Other embodiments may be described and/or claimed.

A printed circuit board (PCB) system includes an integrated circuit (IC) package having a main IC chip that is electrically coupled to a top surface of a package substrate. A first printed circuit board (PCB) is electrically coupled to first contact structures on a bottom surface of the package substrate. A heat dissipation member is coupled to the main IC chip. A memory module is configured to electrically couple, via an interposer, with second contact structures on a top surface of the package substrate while the heat dissipation member dissipates heat from the main IC chip away from one or more memory IC chips on the memory module. The interposer is configured to electrically couple the second contact structures of the IC package with the memory module while the heat dissipation member dissipates heat from the main IC chip away from the one or more memory IC chips.

Described are apparatuses for modular printed circuit boards (PCB) and methods for producing modular PCBs. An apparatus may include a first PCB module with a first pattern of routing structures on one or more layers of the first PCB module. The apparatus may further include a second PCB module with a second pattern of routing structures on one or more layers of the second PCB module. The second pattern of routing structures may be aligned with and electrically coupled to the first pattern of routing structures without connectors. Other embodiments may be described and/or claimed.