A three dimensional circuit module can include: a plurality of PCBs located on different faces, where surfaces of the PCBs include circuit modules; a plurality of circuit assemblies connected through components; where the plurality of circuit assemblies comprises at least one first circuit assembly having a first main board and at least one first side board that are located on different faces, where the first main board and at least one first side board of the first circuit assembly are obtained by integrated curing molding process; and where the first main board of the first circuit assembly is located on one PCB board, and the first side board is located on an adjacent PCB board, in order to realize connection of adjacent PCBs.

The electronic module has a three-dimensional frame, a printed circuit board and a plurality of electronic devices. The printed circuit board is fixed to the three-dimensional frame and has a plurality of support portions which extend transversely to each other in space. The electronic devices are fixed to the printed circuit board and are operatively coupled to each other. The electronic devices are arranged on at least one support portion of the printed circuit board.

A charger comprises a housing, a first multi-layer printed circuit board (PCB), a second multi-layer PCB, and a third multi-layer PCB. The first PCB comprises at least a portion of a primary side circuit. The second PCB comprises at least a portion of a secondary side circuit. The third PCB is perpendicular to the first PCB and the second PCB. An isolation coupling element is disposed on the third PCB. The isolation coupling element comprises a multi-layer PCB. The first PCB comprises a high voltage (HV) semiconductor package. A surface of a die paddle of the HV semiconductor package is exposed from a molding encapsulation of the HV semiconductor package.

Three-dimensional (3-D) volumetric board architectural design provides technical solutions to technical problems facing miniaturization of circuit boards. The 3-D volumetric architecture includes using more of the unused volume in the vertical dimension (e.g., Z-dimension) to increase the utilization of the total circuit board volume. The 3-D volumetric architecture is realized by mounting components on a first PCB and on a second PCB, and inverting and suspending the second PCB above the first PCB. The use of 3-D volumetric board architectural design further enables formation of a shielded FEMIE, providing shielding and improved volumetric use with little or no reduction in system performance or increase in system Z-height.

An illuminated modular decorative article includes a base control panel and a side panel. The base control panel includes a base, a first electrical/mechanical connection interface, and a power source. The side panel includes a base, a second electrical/mechanical connection interface, and illumination sources. The first electrical/mechanical connection interface connects to the second electrical/mechanical connection interface to electrically connect the base control panel to the side panel and to mechanically connect the base control panel substantially orthogonally to the side panel.

Configurable smart object systems with methods of making modules and contactors are provided. Example systems implement machine learning based on neural networks that draw low power for use in smart phones, watches, drones, automobiles, and medical devices. Example assemblies can be configured from pluggable, interchangeable modules that have compatible ports for interconnecting and integrating functionally dissimilar sensor systems. An example method includes mounting an element of a configurable machine learning assembly on a substrate, creating at least one fold in the substrate, folding the substrate at the fold into a housing of a module of the configurable machine learning assembly, and adding a molding material to the housing to at least partially fill the module of the configurable machine learning assembly. The example module construction may also form contactors on folded edges of the module for making physical and electrical contact with other modules of the smart object machine learning assembly.

A method for manufacturing a printed circuit board (PCB) with high component density includes at least two reinforcing plates, at least two connecting plates, a first circuit board unit, and a second circuit board unit. The reinforcing plate includes a supporting portion, a first connecting portion, and a second connecting portion. The first connecting portion and the second connecting portion connect to ends of the supporting portion. The connecting plates are bendable circuit boards. Each connecting plate is attached to the supporting portion, the first connecting portion, and the second connecting portion of a reinforcing plate. The first circuit board unit is fixed and electrically connected to a connecting plate away from first connecting portion. The second circuit board unit is fixed and electrically connected to a connecting plate away from the second connecting portion.

Various embodiments of the present invention relate to an electronic device including a stacked circuit board. The electronic device comprises: a first circuit board; a second circuit board; one or more circuit elements disposed on the second circuit board; and a connecting member disposed between the first circuit board and the second circuit board facing the first circuit board to form an internal space surrounding at least some of the one or more circuit elements, and to electrically connect the first and second circuit boards, wherein the internal space may be filled with a phase change material (PCM) that absorbs heat generated by the at least some circuit elements to change the state of the material. Various other embodiments of the present invention may be additionally provided.

A novel 3D package configuration is provided by stacking a plurality of semiconductor package units or a folded flexible circuit board structure on a package substrate and electrically connected therewith based on the foldable characteristics of the flexible circuit board, and the high temperature resistance of the flexible circuit board which is suitable for insulating layer process, metal layer process, photolithography process, etching and development process, to make conventional semiconductor dies of various functions be bonded on one die and/or two side of a flexible circuit board and electrically connected therewith in advance.

A circuit board includes a substrate, a first circuit layer, a second circuit layer, and a third circuit layer. The substrate includes a base layer, a first metal layer formed on the base layer, and a seed layer formed on the first metal layer. The first circuit layer is located on the substrate and includes the first metal layer and a signal layer formed on a surface of the first metal layer. The second circuit layer is coupled to the first circuit layer and includes the first metal layer, the seed layer, and a connection pillar formed on a surface of the first metal layer and the seed layer. The third circuit layer is coupled to the second circuit layer and includes the seed layer and a coil formed on a surface of the seed layer.