Disclosed are a radiant heat circuit board and a method for manufacturing the same. The radiant heat circuit board, which is used to mount a heat emitting device thereon, includes a metallic plate including a metallic protrusion having a solder to which the heat emitting device is attached, a bonding layer on the metallic protrusion, an insulating layer on the metallic plate to expose the metallic protrusion, and a circuit pattern on the insulating layer. Heat emitted from the heat emitting device is directly transferred to the metallic plate by providing the metallic plate including a heat radiation protrusion under the mounting pad, so that heat radiation efficiency is increased. The surface of the heat radiation protrusion is plated with an alloy including copper, thereby improving the adhesive property with respect to the solder, so that the failure rate is reduced.

An electrical component assembly includes a substrate and first and second electrical components attached to the substrate and operably connected with each other via the substrate. In use the first electrical component generates a first amount of heat and the second component generates a second amount of heat. The first component is thermally connected with a heat sink along a first heat path and the second component is connected with the heat sink along a second, different, heat path, such that the thermal conductivity between the first and second components is lower than the thermal conductivity of the first heat path and of the second heat path.

An etching method for manufacturing a substrate structure having a thick electrically conductive layer, and a substrate structure having a thick electrically conductive layer are provided. The etching method includes providing an electrically insulating substrate structure including a thermally conductive and electrically insulating layer, an electrically conductive layer, and a non-photosensitive polymer masking layer, removing one part of the non-photosensitive polymer masking layer and one part of the electrically conductive layer by a machining process to form at least one electrically conductive recess having the electrically conductive layer exposed, forming a predetermined thickness ratio between a thickness of the electrically conductive recess and a thickness of the electrically conductive layer, removing a reserved part of the electrically conductive layer between a bottom wall of the electrically conductive recess and a bottom surface of the electrically conductive layer, and removing a remaining part of the non-photosensitive polymer masking layer.

The disclosure provides an electronic assembly that includes: a carrier element, a circuit carrier having a number of electronic components, a circuit board, which is electrically conductively connected to the circuit carrier, and a covering element for covering the circuit carrier. The covering element is arranged on one flat side of the circuit board and the carrier element is arranged on an opposite flat side of the circuit board. The circuit board is welded respectively to the carrier element and to the covering element. The disclosure further relates to a method for producing such an electronic assembly.

A method of manufacturing a circuit board is provided. The method includes forming an open substrate, in which the open substrate includes a substrate body having a top surface and a bottom surface; an opening in the substrate body, in which the opening has a first sidewall and a second sidewall opposite to the first sidewall; and at least one first fixing portion and at least one second fixing portion extending from the substrate body toward the opening, in which the first fixing portion and the second fixing portion are respectively protruded from the first sidewall and the second sidewall. A heat dissipation block is inserted in the opening to clamp the heat dissipation block between the first fixing portion and the second fixing portion, in which the heat dissipation block includes the heat dissipation block comprises a ceramic or a composite material.

A heat dissipating antenna comprised of a low-attenuating heat spreader bonded to a high frequency antenna or antenna array.

An integrated circuit with a wireless integrated circuit chip, and a heat dissipating antenna coupled to the wireless integrated circuit chip. A method of forming a heat dissipating antenna.

A submount for connecting a semiconductor device to an external circuit, the submount comprising: a planar substrate formed from an insulating material and having relatively narrow edge surfaces and first and second relatively large face surfaces; at least one recess formed along an edge surface; a layer of a conducting material formed on a surface of each of the at least one recess; a first plurality of soldering pads on the first face surface configured to make electrical contact with a semiconductor device; and electrically conducting connections each of which electrically connects a soldering pad in the first plurality of soldering pads to the layer of conducting material of a recess of the at least one recess.

The disclosure relates to an optical transceiver and a manufacturing method thereof. The optical transceiver includes a substrate, a thermal-conductive substrate, a first metal wiring structure, a light-transceiving element and an optical fiber array. The substrate has an opening, and the thermal-conductive substrate is embedded within the opening. The first metal wiring structure is integrally formed on the substrate and the thermal-conductive substrate through an electroplating or a wire-printing process. The light-transceiving element is disposed on the thermal-conductive substrate and is electrically connected to the first metal wiring structure. The optical fiber array is arranged on the thermal-conductive substrate for communication with the light-transceiving element.

Example embodiments relate to electronic packages and electronic devices that include the same. One embodiment includes an electronic package. The electronic package includes a package body. The electronic package also includes a heat-conducting substrate arranged inside the package body and having a bottom surface that is exposed to an outside of the package body. Additionally, the electronic package includes an electronic circuit arranged inside the package body and including a semiconductor die that has a bottom surface with which it is mounted to the heat-conducting substrate and an opposing upper surface. Further, the electronic package includes one or more leads partially extending from outside the package body to inside the package body and over the minimum bounding box, each lead having a first end that is arranged inside the package body. In addition, the electronic package includes one or more bondwires for connecting the first end(s) to the electronic circuit.

Provided is a display device including a display panel including a plurality of first pads, and a plurality of second pads spaced apart from the first pads, a first circuit board including first circuit pads respectively bonded to the first pads, a first driving chip electrically connected to the first circuit pads, and a first heat radiation member, and a second circuit board including second circuit pads respectively bonded to the second pads, and a second driving chip electrically connected to the second circuit pads, wherein the first heat radiation member overlaps the first driving chip and the second driving chip.