Abstract: A circuit board with a heat-recovery function includes a substrate, a heat-storing device, and a thermoelectric device. The heat-storing device is embedded in the substrate and connected to a processor for performing heat exchange with the processor. The thermoelectric device embedded in the substrate includes a first metal-junction surface and a second metal-junction surface. The first metal-junction surface is connected to the heat-storing device for performing heat exchange with the heat-storing device. The second metal-junction surface is joined with the first metal-junction surface, in which the thermoelectric device generates an electric potential by a temperature difference between the first metal-junction surface and the second metal-junction surface.

Abstract: A vehicle door opening warning system including a control unit, a projection unit and a detection unit is provided. The control unit is disposed at a door of a vehicle. The projection unit is disposed at the door and is electrically coupled to the control unit. The detection unit is disposed outside of the vehicle and is electrically coupled to the control unit. When the detection unit detects a moving object existing within 5 to 30 meters of the vehicle, the detection unit produces a signal. The control unit receives the signal and controls the projection unit to project a warning message according to the signal. A vehicle door opening warning method is also provided.

Abstract: An optical component including a multi-layer substrate, an optical waveguide element, and two optical-electro assemblies is provided. The multi-layer substrate includes a dielectric layer, two circuit layers, and two through holes passing through the dielectric layer. The optical waveguide element is located on the multi-layer substrate and between the through holes. The optical-electro assemblies are respectively inserted into the corresponding through holes and correspondingly located at two opposite ends of the optical waveguide element. One of the optical-electro assemblies transforms an electrical signal into a light beam and provides the light beam to the optical waveguide element, and the other one of the optical-electro assemblies receives the light beam transmitted from the optical waveguide element and transforms the light beam into another electrical signal. A manufacturing method of the optical component and an optical-electro circuit board having the optical component are also provided.

Abstract: An optical component including a multi-layer substrate, an optical waveguide element, and two optical-electro assemblies is provided. The multi-layer substrate includes a dielectric layer, two circuit layers, and two through holes passing through the dielectric layer. The optical waveguide element is located on the multi-layer substrate and between the through holes. The optical-electro assemblies are respectively inserted into the corresponding through holes and correspondingly located at two opposite ends of the optical waveguide element. One of the optical-electro assemblies transforms an electrical signal into a light beam and provides the light beam to the optical waveguide element, and the other one of the optical-electro assemblies receives the light beam transmitted from the optical waveguide element and transforms the light beam into another electrical signal. A manufacturing method of the optical component and an optical-electro circuit board having the optical component are also provided.

Abstract: An optical component including a multi-layer substrate, an optical waveguide element, and two optical-electro assemblies is provided. The multi-layer substrate includes a dielectric layer, two circuit layers, and two through holes passing through the dielectric layer. The optical waveguide element is located on the multi-layer substrate and between the through holes. The optical-electro assemblies are respectively inserted into the corresponding through holes and correspondingly located at two opposite ends of the optical waveguide element. One of the optical-electro assemblies transforms an electrical signal into a light beam and provides the light beam to the optical waveguide element, and the other one of the optical-electro assemblies receives the light beam transmitted from the optical waveguide element and transforms the light beam into another electrical signal. A manufacturing method of the optical component and an optical-electro circuit board having the optical component are also provided.

Abstract: A method for assembling an opto-electronic circuit board is described as follows. A bottom cladding layer, a core layer and a top cladding layer are formed on the base orderly such that a waveguide is completed. A first light-guide hole is formed in a base material, and a light source is disposed on the base material thereby forming an emission component. A second light-guide hole is formed in another base material, and then an optic receiver is disposed on another base material thereby forming a receiver component. A circuit substrate is processed in order to form a first cavity, a second cavity and a third cavity on a first circuit layer of the substrate. The waveguide, the emission component and the receiver component are disposed respectively in the first cavity, the second cavity and the third cavity.

Abstract: A preparation method of a conductive sponge includes the following steps. First, a sponge substrate is dipped in a metal solution and then taken out. A first drying process is performed. Next, the sponge substrate plated with metal particles is dipped in a carbon nanomaterial suspension and then taken out. Then, a second drying process is performed.

Abstract: A manufacturing method for a multi-layer circuit board includes the following steps. Firstly, a substrate having two surfaces opposite to each other and a via connecting there between is provided. Next, a patterned circuit layer is formed on each of the surfaces by using the via as an alignment target. Each patterned circuit layer includes a concentric-circle pattern. Next, a first stacking layer is formed on each of the surfaces. Then, a first through hole penetrating regions of the first stacking layer and the substrate where a first concentric circle from the center of the concentric-circle pattern is orthogonally projected thereon is formed. Next, a second stacking layer is formed on each first stacking layer. Afterward, a second through hole penetrating regions of the first, the second stacking layers and the substrate where a second concentric circle from the center of the concentric-circle pattern is orthogonally projected thereon is formed.

Abstract: A manufacturing method of multilayer flexible circuit structure including the following steps is provided. Two first flexible substrates are correspondingly bonded on two sides of a release film, and two conductive materials are correspondingly formed on the two first flexible substrates. The two conductive materials are patterned to form two first inner-layer circuits. Two outer build-up structures are bonded on the two corresponding first flexible substrates. The release film is removed, so as to separate the two first flexible substrates. An outer-layer circuit is formed on each of the first flexible substrates and the corresponding outer build-up structure, wherein the outer-layer circuit is connected to the corresponding first inner-layer circuit, and each of the first flexible substrates, the corresponding first inner-layer circuit, the outer build-up structure and the outer-layer circuit correspondingly form a multilayer flexible circuit structure.

Abstract: A manufacturing method of circuit structure embedded with heat-dissipation block including the following steps is provided. A core board including a first dielectric layer and two first conductive layers located on two opposite sides of the first dielectric layer is provided. A through hole penetrated the core board is formed. A heat-dissipation block is disposed into the through hole. Two inner-layer circuits are formed on two opposite sides of the core board. At least one build-up structure is bonded on the core board, wherein the build-up structure includes a second dielectric layer and a second conductive layer, and the second dielectric layer is located between the second conductive layer and the core board. A cavity is formed on a predetermined region of the build-up structure, and the cavity is communicated with the corresponding inner-layer circuit. Another manufacturing method of circuit structure embedded with heat-dissipation block is also provided.

Abstract: An optical component including a multi-layer substrate, an optical waveguide element, and two optical-electro assemblies is provided. The multi-layer substrate includes a dielectric layer, two circuit layers, and two through holes passing through the dielectric layer. The optical waveguide element is located on the multi-layer substrate and between the through holes. The optical-electro assemblies are respectively inserted into the corresponding through holes and correspondingly located at two opposite ends of the optical waveguide element. One of the optical-electro assemblies transforms an electrical signal into a light beam and provides the light beam to the optical waveguide element, and the other one of the optical-electro assemblies receives the light beam transmitted from the optical waveguide element and transforms the light beam into another electrical signal. A manufacturing method of the optical component and an optical-electro circuit board having the optical component are also provided.

Abstract: A method for assembling an opto-electronic circuit board is described as follows. A bottom cladding layer, a core layer and a top cladding layer are formed on the base orderly such that a waveguide is completed. A first light-guide hole is formed in a base material, and a light source is disposed on the base material thereby forming an emission component. A second light-guide hole is formed in another base material, and then an optic receiver is disposed on another base material thereby forming a receiver component. A circuit substrate is processed in order to form a first cavity, a second cavity and a third cavity on a first circuit layer of the substrate. The waveguide, the emission component and the receiver component are disposed respectively in the first cavity, the second cavity and the third cavity.

Abstract: A manufacturing method of an embedded wiring board is provided. The method includes the following steps. First, an insulation layer and a lower wiring layer are provided, wherein the insulation layer includes a polymeric material. Then, the plural catalyst grains are distributed in the polymeric material. A groove and an engraved pattern are formed on the upper surface. A blind via is formed on a bottom surface of the groove to expose the lower pad. An upper wiring layer is formed in the engraved pattern. Some catalyst grains are exposed and activated in the groove, the engraved pattern and the blind via. A first conductive pillar is formed in the groove. Finally, a second conductive pillar is formed in the blind via.

Abstract: A manufacturing method for a multi-layer circuit board includes the following steps. Firstly, two core layers are compressed to form a substrate having two surfaces opposite to each other. Then, a via connecting the surfaces is formed. A patterned circuit layer including a concentric-circle pattern is then formed on each surface by using the via as an alignment target. Next, a first stacking layer is formed on each surface. Then, a first through hole penetrating regions of the first stacking layer and the substrate where a first concentric circle from the center of the concentric-circle pattern is orthogonally projected thereon is formed. A second stacking layer is then formed on each first stacking layer. Afterward, a second through hole penetrating regions of the first, the second stacking layers and the substrate where a second concentric circle from the center of the concentric-circle pattern is orthogonally projected thereon is formed.

Abstract: An opto-electronic circuit board includes a substrate, a cavity, blind vias, metal layers, a first chip, a second chip, and the optical component. The substrate includes a first circuit layer, a second circuit layer, and a dielectric layer disposed between the first circuit layer and the second circuit layer. The cavity is disposed on the dielectric layer, in which the cavity extends from the first circuit layer to the second circuit layer. The blind vias are disposed at opposite sides of the cavity. The first chip is disposed on the second circuit layer with corresponding to one of the blind vias. The second chip is disposed on the second circuit layer with corresponding to the other one of the blind vias. The optical component is disposed in the cavity, in which the second surface of the optical component is connected to the first circuit layer.

Abstract: A method for manufacturing an embedded wiring board is provided. An activating insulation layer is formed. The activating insulation layer includes a plurality of catalyst particles, and covers a first wiring layer. An intaglio pattern and at least one blind via partially exposing the first wiring layer are formed on the activating insulation layer, in which some of the catalyst particles are activated and exposed in the intaglio pattern and the blind via. The activating insulation layer is dipped in a first chemical plating solution, and a solid conductive pillar is formed in the blind via through electroless plating. The activating insulation layer is dipped in a second chemical plating solution after the solid conductive pillar is formed, and a second wiring layer is formed in the intaglio pattern through the electroless plating. Components of the first chemical plating solution and the second chemical plating solution are different.

Abstract: A manufacturing method for a multi-layer circuit board includes the following steps. Firstly, a substrate having a first via penetrating the substrate is provided. Next, a patterned circuit layer is formed on a surface of the substrate by using the first via as an alignment target. The first patterned circuit layer includes a first concentric-circle pattern surrounding the first via. Next, a first stacking layer is formed on the surface. Then, a first through hole penetrating regions where a first concentric circle from the center of the concentric-circle pattern is orthogonally projected on the first stacking layer and the substrate is formed. Next, a second stacking layer is formed on the first stacking layer. Afterward, a second through hole penetrating regions where a second concentric circle from the center of the concentric-circle pattern is orthogonally projected on of the first, the second stacking layers and the substrate is formed.

Abstract: A process for fabricating a wiring board is provided. In the process, a wiring carrying substrate including a carry substrate and a wiring layer is formed. Next, at least one blind via is formed in the wiring carrying substrate. Next, the wiring carrying substrate is laminated to another wiring carrying substrate via an insulation layer. The insulation layer is disposed between the wiring layers of the wiring carrying substrates and full fills the blind via. Next, parts of the carry substrates are removed to expose the insulation layer in the blind via. Next, a conductive pillar connected between the wiring layers is formed. Next, the rest carry substrates are removed.

Abstract: A manufacturing method for a multi-layer circuit board includes the following steps. Firstly, a substrate having a first via penetrating the substrate is provided. Next, a patterned circuit layer is formed on a surface of the substrate by using the first via as an alignment target. The first patterned circuit layer includes a first concentric-circle pattern surrounding the first via. Next, a first stacking layer is formed on the surface. Then, a first through hole penetrating regions where a first concentric circle from the center of the concentric-circle pattern is orthogonally projected on the first stacking layer and the substrate is formed. Next, a second stacking layer is formed on the first stacking layer. Afterward, a second through hole penetrating regions where a second concentric circle from the center of the concentric-circle pattern is orthogonally projected on of the first, the second stacking layers and the substrate is formed.

Abstract: A manufacturing method for a multi-layer circuit board includes the following steps. Firstly, a substrate having two surfaces opposite to each other and a via connecting there between is provided. Next, a patterned circuit layer is formed on each of the surfaces by using the via as an alignment target. Each patterned circuit layer includes a concentric-circle pattern. Next, a first stacking layer is formed on each of the surfaces. Then, a first through hole penetrating regions of the first stacking layer and the substrate where a first concentric circle from the center of the concentric-circle pattern is orthogonally projected thereon is formed. Next, a second stacking layer is formed on each first stacking layer. Afterward, a second through hole penetrating regions of the first, the second stacking layers and the substrate where a second concentric circle from the center of the concentric-circle pattern is orthogonally projected thereon is formed.