A display apparatus including a waveguide is provided. The display apparatus includes a display panel; a backlight configured to provide light to the display panel; a heat sink configured to absorb heat generated by the backlight; a bottom chassis configured to support the backlight and the heat sink; a first circuit board mounted on the bottom chassis; a second circuit board mounted on the bottom chassis; and a waveguide formed between the first circuit board and the second circuit board.

Provided is a display apparatus. The display apparatus includes: a display panel; a chassis supporting the display panel; a printed circuit board on which an electronic component is mounted; and a supporter inserted in the printed circuit board, wherein the printed circuit board includes a first surface facing the chassis, a second surface facing a direction opposite to the first surface, and a through hole penetrating the first surface and the second surface. The supporter includes: a head fixed on the second surface of the printed circuit board; a first body positioned inside the through hole, and extending from the head toward the chassis; and a second body extending from the first body, and protruding from the through hole toward the chassis.

On a conductive plate of an insulated substrate, one open end of a main body part of a cylindrical contact member is bonded by solder. In a hollow part of a hollow cylinder shaped external electrode terminal, a part of the other open end side of the main body part of the cylindrical contact member is inserted from an open end of the external electrode terminal. The other end of the external electrode terminal is separated into branches by cuts inserted in a through-hole insertion part. A column surface of the outside of the branches of the external electrode terminal has an arc shape. Pressure in a direction from inside the external electrode terminal toward the outside is applied to the branches of the through-hole insertion part by an auxiliary wedge. With such a configuration, assembly defects accompanying connection of the external electrode terminal and other members may be eliminated.

A circuit board includes a base substrate, a busbar disposed on a mounting surface of the base substrate; and an electronic component disposed on the mounting surface and including a plurality of terminals. At least one of the terminals is soldered to a component connecting end portion extending from the busbar. The base substrate has an opening into which the component connecting end portion is inserted. A first insertion portion is provided in the component connecting end portion. The terminal is inserted through the first insertion portion. The busbar is fixed to the base substrate so that the component connecting end portion is inserted into the opening with a soldering surface positioned closer to a rear surface of the base substrate than the component mounting surface. The soldering surface is on a side of the component connecting end portion where the terminal inserted through the first insertion portion protrudes.

An electronic device having a display assembly is disclosed. Several layers may combine to form the display assembly. For example, the display assembly may include a touch sensitive layer (or touch detection layer), a display layer that present visual information, and a force sensitive layer (or force detection layer). The display layer may include a bend or curve that allows a portion of the display layer to bend around the force sensitive layer. Also, the connectors (that provide electrical and mechanical connections) may be positioned at different locations of the layers. For example, the display layer may include a connector on a first edge region, and the force sensitive layer may include a connector on a second edge region that is perpendicular, or at least substantially perpendicular, to the first edge region. By positioning the connectors on perpendicular edge regions, the display assembly may reduce its footprint.

An electronic device having a battery assembly is disclosed. Unlike traditional battery assemblies that include rectilinear electrodes with two sides of equal length, the battery assemblies described herein may include electrodes having a shape/configuration resembling an L-shape electrode used to form chemical reactions in order to generate electrical energy. However, other shapes/configurations are possible. The shape/configuration of the housing of the battery assembly confirms to the shape/configuration of the electrodes. Further, in order to accommodate an internal component (such as a circuit board assembly), the shape of the battery assembly provides additional space in the electronic device. In order to form the electrodes, the electrodes may undergo a die cutting operation. Also, the housing may include a channel, or reduced dimension, that accommodates a flexible circuit in the electronic device that passes over the battery assembly at the channel.

A circuit board assembly in an electronic is disclosed. To conserve space in the electronic device, the circuit board assembly includes stacked circuit boards in electrical communication with each other, such as a first circuit board stacked over a second circuit board. Each circuit board may include multiple surfaces that carry operational components. Moreover, the first circuit board may include a first surface and the second circuit board may include a second surface facing the first surface. The first and second surfaces may include operational components in corresponding locations. Also, the operational components may include corresponding shapes such that one component is positioned in another component. The components may electrically connect to each other. Also, the circuit board assembly may include EMI shields around an outer perimeter in order to shield the operational components form EMI and to components in the electronic device from EMI emanating from the operational components.

A thermal distribution assembly for an electronic device is disclosed. The electronic device includes an enclosure defined by a metal band and a non-metal bottom wall formed by glass, sapphire, or plastic. In this regard, the enclosure may include a relatively low thermal conductivity. However, the thermal distribution assembly provides heat transfer capabilities that offset thermal conductivity losses by using a non-metal bottom wall, and also provides added structural support. The thermal distribution assembly may include a first layer, a second layer, and a third layer. The first and third layers provide structural support, while the second layer provides a relatively high thermally conductive layer. The thermal distribution assembly includes sidewalls engaging and thermally coupling to the metal band, allowing the thermal distribution assembly to draw heat from a heat-generating component, and pass the heat to the metal band while minimizing or preventing temperature increases along the non-metal bottom wall.

Methods, systems, devices, and products for manufacturing an electrical assembly, such as a completed downhole circuit board, for use in well logging. Methods include attaching an electrical component to a printed circuit board by mechanically fastening the electrical component to the printed circuit board. Methods may include using a laser to attach a plurality of legs to contact surfaces. Methods may include applying light from the laser to a material of the printed circuit board to produce heat, including mitigating reflection of the light from the material. Methods include forming a connection between a first electrical component of the electrical assembly and a second electrical component of the electrical assembly by causing heating of an additive manufacturing material by applying light from a laser. The connection may be at least one of: i) an electrical connection; ii) a structural connection; iii) an electrical insulation.

A mounting jig for a semiconductor device includes an insulated circuit board positioning jig positioning an insulated circuit board by housing the insulated circuit board at a predetermined position, a tubular contact element positioning jig having a plurality of positioning holes at predetermined positions to insert a plurality of tubular contact elements respectively, and a tubular contact element press-down jig for pressing down the plurality of tubular contact elements inserted into the respective positioning holes in the tubular contact element positioning jig.