The present disclosure provides a battery protection circuit board and a preparation method thereof. The battery protection circuit board includes a first battery protection board and a second battery protection board, a hardness of the first battery protection board being greater than a hardness of the second battery protection board. The soldering method includes: preparing a first to-be-soldered region of the first battery protection board and preparing a second to-be-soldered region of the second battery protection board; preparing a first copper paste in the first to-be-soldered region of the first battery protection board and preparing a second copper paste in the second to-be-soldered region of the second battery protection board; and bonding the first to-be-soldered region of the first battery protection board and the second to-be-soldered region of the second battery protection board by the first copper paste and the second copper paste.

Disclosed herein are unitary printed circuit boards (PCBs) and methods of using them for testing an integrated circuit (IC). In some embodiments, a unitary PCB comprises a main board portion and a flexible PCB portion, which are configured to be detached from each other at a separation location on the unitary PCB. The main board portion comprises a plurality of pads, and the flexible PCB portion comprises a plurality of through-holes, where a layout of the through-holes corresponds to a layout of the plurality of pads. In some embodiments, a method of testing an IC of a device comprises separating the unitary PBC into a main board portion and a flexible PCB portion, attaching the IC to the main board portion, soldering the main board portion to a platform PCB of the device, and attaching the flexible PCB portion to the main board portion.

A circuit board includes a multilayer body including a main surface, a mounted conductor, and a signal conductor at an intermediate position in the lamination direction of the multilayer body, and a ground conductor on the main surface. The multilayer body includes a connection portion including a portion overlapping the mounted conductor and overlapping an external board joined via a conductive joint material through use of the mounted conductor, and a circuit portion. A first region, which is the region of a circuit portion of the ground conductor, includes opening holes and a second region, which is the region of a connection portion of the ground conductor, includes opening holes. The ratio of the opening area of the opening holes to that of the second region is larger than the ratio of the opening area of the opening holes to that of the first region.

A display device includes a display panel including panel pads adjacent to the side surface of a display panel; connection pads disposed on the side surface of the display panel and connected to the panel pads; and a circuit board disposed on the side surface of the display panel and including lead signal lines directly bonded to the connection pads, wherein the connection pads include a first connection pad, a second connection pad disposed on the first connection pad, and a third connection pad disposed on the second connection pad, and the first connection pad is in contact with corresponding one of the panel pads, and the third connection pad is directly bonded to corresponding one of the lead signal lines.

A vibration isolator and method of assembly utilize “flex circuits” to provide both vibration/shock isolation and integrated electrically isolated conductive paths to support lightweight devices (<100 grams) such as crystal oscillators, IC chips, MEMs devices and the like. Each flex circuit includes a least one polymer layer and at least one of the flex circuits includes at least one patterned conductive layer. The isolator may be integrally formed from a stack of polymer layers and patterned conductive layers to provide the plurality of flex circuits, platform and connectors. Most typically, flex circuits are Type 4 in which the multiple polymer layers have a loose leaf or bonded configuration. Flex circuits are easy to produce in large quantities at low cost with standardized and repeatable performance characteristics.

A connection FPC 75 includes a plurality of metal wires 750 between a support layer 751 and a covering layer 752, and an exposed region including contacts 753 serving as end portions of the metal wires 750 is exposed from the covering layer 752. A bending-position guide 760 is provided on the surface of the support layer 751 opposite from the surface on which the metal wires 750 are provided. An edge 760a of the bending-position guide 760 serves as a bending line along which the connection FPC 75 is bent and is disposed in a covering-layer projection area E where the covering layer 752 is projected on the support layer 751. The connection FPC 75 is bent at portions of the metal wires 750 covered with the covering layer 752, that is, at reinforced portions.

An electronic device comprises a supporting substrate, a flexible substrate disposed on the supporting substrate, a plurality of electronic units and a conductive pattern layer. The flexible substrate is bent from a front side to a back side of the supporting substrate, and a portion of the flexible substrate is disposed on the back side of the supporting substrate. The electronic units are disposed within a display region of the flexible substrate. The conductive pattern layer extends from the display region to the portion of the flexible substrate, and the conductive pattern layer electrically connects at least two of the electronic units.

Disclosed embodiments include alignment apparatuses for circuit boards, inverter assemblies, and methods for fabricating an assembly with a circuit board placed on an alignment apparatus. An illustrative apparatus includes an electrically insulative substrate having a first substantially planar surface and a second substantially planar surface forming an opposing side of the first substantially planar surface. The second substantially planar surface defines therein self-aligning features that are configured to align at least one power module pin with the electrically insulative substrate. The first substantially planar surface has at least one alignment feature configured to align a printed circuit board with the electrically insulative substrate. The apparatus also includes a routing feature coupled to the electrically insulative substrate. The routing feature is configured to route at least one low voltage conductor.

A stackable via package includes a substrate having an upper surface and a trace on the upper surface, the trace including a terminal. A solder ball is on the terminal. The solder ball has a solder ball diameter A and a solder ball height D. A via aperture is formed in a package body enclosing the solder ball to expose the solder ball. The via aperture includes a via bottom having a via bottom diameter B and a via bottom height C from the upper surface of the substrate, where A<B and 0=<C<1/2×D. The shape of the via aperture prevents solder deformation of the solder column formed from the solder ball as well as prevents solder bridging between adjacent solder columns.

The present application discloses a display module and a manufacturing method thereof, and a mobile terminal. The display module includes a printed circuit board connected to a backlight flexible circuit board. A side of the backlight flexible circuit board connected to the printed circuit board comprises at least two first bonding regions, wherein each of the first bonding regions includes at least two first bonding terminals distributed therein, and wherein a distance between any two adjacent first bonding regions is greater than a distance between any two adjacent first bonding terminals in each of the first bonding regions.