Abstract: A circuit board includes: an insulating layer; a capacitor which is provided in the insulating layer and which includes a dielectric layer, a first conductor layer provided on a first surface of the dielectric layer and including an opening part, and a second conductor layer provided on a second surface opposite to the first surface of the dielectric layer and including a recess part at a position corresponding to the opening part; and a conductor via provided in the insulating layer, penetrating the dielectric layer, the opening part and the recess part, being in contact with the recess part, and being smaller than the opening part in plan view.

Abstract: A semiconductor package includes a VLSI semiconductor die and one or more output circuits connected to supply power to the die mounted to a package substrate. The output circuit(s), which include a transformer and rectification circuitry, provide current multiplication at an essentially fixed conversion ratio, K, in the semiconductor package, receiving AC power at a relatively high voltage and delivering DC power at a relatively low voltage to the die. The output circuits may be connected in series or parallel as needed. A driver circuit may be provided outside the semiconductor package for receiving power from a source and driving the transformer in the output circuit(s), preferably with sinusoidal currents. The driver circuit may drive a plurality of output circuits. The semiconductor package may require far fewer interface connections for supplying power to the die.

Abstract: A semiconductor device has a first substrate. A first semiconductor component is disposed on a first surface of the first substrate. A second substrate includes a vertical interconnect structure on a first surface of the second substrate. A second semiconductor component is disposed on the first surface of the second substrate. The first semiconductor component or second semiconductor component is a semiconductor package. The first substrate is disposed over the second substrate with the first semiconductor component and second semiconductor component between the first substrate and second substrate. A first encapsulant is deposited between the first substrate and second substrate. A SiP submodule is disposed over the first substrate or second substrate opposite the encapsulant. A shielding layer is formed over the SiP submodule.

Abstract: A filter includes: first and second parallel resonant circuits including a first capacitor, a first line, a second capacitor, and a second line that are shunt-connected to a series pathway connecting the input and output terminals; and first to sixth vias penetrating through a second dielectric layer on which the first and second lines are disposed, the first via connecting the first line to the series pathway, the second via connecting the first line to the ground terminal, the third via connecting the first line at a position between the first and second vias to the first connection line at a first position, the fourth via connecting the second line to the series pathway, the fifth via connecting the second line to the ground terminal, the sixth via connecting the second line at a position between the fourth and fifth vias to the first connection line at a second position.

Abstract: A composite electronic component includes: a first electronic component including a ceramic body having a main surface caused to face a circuit board at a time of mounting and first and second end surfaces orthogonal to the main surface, and a first external electrode and a second external electrode respectively provided to the first end surface and the second end surface and respectively extending from the first end surface and the second end surface to the main surface; and a second electronic component including a functional film provided to the main surface, and a first electrode film and a second electrode film provided to both end portions of the functional film separately from the first external electrode and the second external electrode, the second electronic component being configured to fit within a thickness of each of the first external electrode and the second external electrode from the main surface.

Abstract: Some embodiments include an integrated assembly having a capacitive unit which includes a plurality of capacitive subunits. A first conductive structure is under a first group of the capacitive subunits and is coupled with them. A second conductive structure is under a second group of the capacitive subunits and is coupled with them. A third conductive structure is over the capacitive subunits and is coupled with all of the capacitive subunits. A resistive structure extends under the first and second conductive structures. The resistive structure has a first-end-region under the first conductive structure and coupled with the first conductive structure. The resistive structure includes resistive lines extending from the first-end-region to second-end-regions.

Abstract: A method of manufacturing a semiconductor substrate includes: forming a barrier metal layer on a semiconductor substrate; forming a resist mask on the barrier metal layer; performing dry etching on a portion of the barrier metal layer, which is exposed from an opening portion of the resist mask, so that the dry etching is prevented from reaching a top surface of a layer immediately under the barrier metal layer; performing wet etching on a portion of the barrier metal layer exposed by the dry etching so that the wet etching reaches the top surface of the layer immediately under the barrier metal layer and a portion of the barrier metal layer remains; and stripping the resist mask.

Abstract: Semiconductor memory devices and methods for manufacturing semiconductor memory devices are provided herein, An example method includes forming a first silicon layer on a bottom conductive layer, transforming the first silicon layer into a first polysilicon layer, forming a second silicon layer stacked on the first polysilicon layer, and a third silicon layer stacked on the second silicon layer, transforming the second and third silicon layers into second and third polysilicon layers, forming an amorphous silicon layer on the third polysilicon layer, forming the amorphous silicon layer into a silicide layer on at least a portion of the third polysilicon layer, depositing an oxide onto at least a portion of the first, second, and third polysilicon layers, selectively trimming the silicide layer, and forming a top conductive layer on at least a portion of the trimmed silicide layer.

Abstract: A semiconductor device has a first substrate. A first semiconductor component is disposed on a first surface of the first substrate. A second substrate includes a vertical interconnect structure on a first surface of the second substrate. A second semiconductor component is disposed on the first surface of the second substrate. The first semiconductor component or second semiconductor component is a semiconductor package. The first substrate is disposed over the second substrate with the first semiconductor component and second semiconductor component between the first substrate and second substrate. A first encapsulant is deposited between the first substrate and second substrate. A SiP submodule is disposed over the first substrate or second substrate opposite the encapsulant. A shielding layer is formed over the SiP submodule.

Abstract: A system and a method of manufacture thereof of integrated circuit packaging system, including: a pillar; a conductive buildup attached to the pillar; and a molded body encapsulating the conductive buildup, the pillar extending out of the molded body.

Abstract: A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a first substrate, a second substrate, an interposer substrate, a semiconductor chip, a package body and a first antenna layer. The first substrate comprises a grounding segment. The interposer substrate is disposed between the second substrate and the first substrate. The semiconductor chip is disposed on the second substrate. The package body encapsulates the second substrate, the semiconductor chip and the interposer substrate, and has a lateral surface and an upper surface. The first antenna layer is formed on the lateral surface and the upper surface of the package body, and electrically connected to the grounding segment.

Abstract: A packaging substrate is provided, including a substrate body having a plurality of conductive pads, an insulating protective layer formed on the substrate body for the conductive pads to be exposed therefrom, and a plurality of conductive pillars disposed on the conductive pads. Each of the conductive pillars has a bottom end and a top end narrower than the bottom end, thereby forming a cone-shaped structure that does not have a wing structure. Therefore, the distance between contact points is reduced and the demands for fine-pitch and multi-joints are satisfied.

Abstract: A surface-mountable electronic device free of leads has a plurality of solderable connection surfaces at its lower side, with at least one of the connection surfaces having a rectangular portion. The outline of this rectangular portion corresponds to a connection surface of the JEDEC Standard MO-236 or of any other standard according to which the respective connection surface should not extend directly up to a side edge of the lower device side. The at least one connection surface furthermore has an extension section which extends, starting from the rectangular portion, in the direction of a side edge of the lower side of the device.

Abstract: A high-frequency module has a multilayer board formed by laminating a plurality of sheets made of a thermoplastic resin material and subjecting the laminated sheets to thermocompression bonding, and an IC chip placed in a cavity provided in the multilayer board. A gap is provided between a side of the IC chip and an inner wall of the cavity. The multilayer board includes a via-hole conductor provided near the inner wall of the cavity for preventing the resin sheets from being softened and flowing into the cavity upon thermocompression bonding.

Abstract: A multi layer interconnecting substrate has at least two spaced apart metal layers with a conductive pad on each one of the metal layers. Two different types of insulating layers are placed between the metal layers. The placement is such that one of the two different types of insulating layers is placed between the conductive pads and the other type of insulating layer is placed between the two spaced apart metal layers.

Abstract: Disclosed herein is a printed circuit board having electronic components embedded therein. The printed circuit board having electronic components embedded therein includes: a metal core layer connected to a ground terminal of an external power supply to be grounded and having a cavity or a groove part formed thereon; an electronic component accommodated in the cavity and having a plurality of terminals, a ground terminal included in the plurality of terminals being connected to the metal core layer; an internal insulating layer stacked on both sides of the metal core layer; and circuit patterns formed on an external surface of the internal insulating layer.

Abstract: A multilayered printed wiring board includes a plurality of insulating layers; a plurality of wiring layers which are located between the corresponding adjacent insulating layers; and a plurality of interlayer connection conductors for electrically connecting the wiring layers through the insulating layers; wherein a cavity is formed through one or more of the insulating layers so as to insert a first electric/electronic component and an area for embedding a second electric/electronic component is defined for the insulating layers.

Abstract: A method of manufacturing a printed circuit board (PCB) having an embedded bare chip includes attaching a tape to one side of an insulated substrate having a penetration hole formed therein, and attaching the bare chip onto the tape inside the penetration hole such that electrode pads of the bare chip face the tape; filling up the penetration hole with a filler, and removing the tape; laminating a metal layer onto a surface of the filler and the insulated substrate from which the tape is removed; and forming electrode bumps by removing portions of the metal layer. The forming of electrode bumps further includes simultaneously removing portions of the metal layer and forming an circuit pattern on one side of the insulated substrate. The circuit pattern is formed directly on the upper side of the insulated substrate and the electrode bumps are formed on the surface of the electrode pads.

Abstract: In a first conductive layer and a third conductive layer that are respectively closest to a core layer having a storage portion that penetrates therethrough, four first penetrating holes and four first penetrating holes are formed so as to overlap part of an opening edge of the storage portion that is projected onto the first conductive layer and the third conductive layer, respectively.

Abstract: An electronic device may contain components such as flexible printed circuits and rigid printed circuits. Electrical contact pads on a flexible printed circuit may be coupled electrical contact pads on a rigid printed circuit using a coupling member. The coupling member may be configured to electrically couple contact pads on a top surface of the flexible circuit to contact pads on a top surface of the rigid circuit. The coupling member may be configured to bear against a top surface of the flexible circuit so that pads on a bottom surface of the flexible circuit rest against pads on a top surface of the rigid circuit. The coupling member may bear against the top surface of the flexible circuit. The coupling member may include protrusions that extend into openings in the rigid printed circuit. The protrusions may be engaged with engagement members in the openings.

Abstract: An apparatus includes a coreless substrate with an embedded die that is integral to the coreless substrate, and at least one device assembled on a surface that is opposite to a ball-grid array disposed on the coreless substrate. The apparatus may include an over-mold layer to protect the at least one device assembled on the surface.

Abstract: An embedded chip-on-chip package includes a printed circuit board having a recessed semiconductor chip mounting unit constituted by a recess in the printed circuit board and a circuit pattern at the bottom of the recess, a first semiconductor chip embedded in the recessed semiconductor chip mounting unit and electrically connected to the circuit pattern at the bottom of the recess, and a second semiconductor chip mounted to the recessed semiconductor chip mounting unit and electrically connected to the first semiconductor chip and the printed circuit board independently of each other.

Abstract: The present disclosure relates to reducing unwanted RF noise in a printed circuit board (PCB) containing an RF device. An isolation filter is embedded in a PCB containing an RDF device. By placing the isolation filter as close as possible to the RF device in order to dramatically reduce unwanted RF noise due to unavoidable coupling between Vias and planes in the PCB structure.

Abstract: A method for manufacturing a printed circuit board includes forming an opening portion in a substrate, positioning chip capacitors in the opening portion of the substrate such that the chip capacitors are accommodated in the opening portion of the substrate, forming a buildup structure including an interlayer resin insulating layer and a conductive layer over a surface of the substrate and the chip capacitors accommodated in the opening portion of the substrate, and forming on a surface of the buildup structure bump structures positioned to mount an IC chip such that the chip capacitors in the opening portion of the substrate are positioned directly below the IC chip.

Abstract: A printed circuit board including a core substrate including a first resin substrate, a second resin substrate having an opening and a third resin substrate in a multilayer manner while interposing bonding plates, insulating layers and conductive circuit layers alternately laminated on the core substrate, solder bumps formed on an outer surface of the printed circuit board, a first capacitor formed in the opening of the second resin substrate, a conductive pad formed on the first resin substrate and connected to an electrode of the first capacitor, a via hole formed in the first resin substrate and directly connected to the conductive pad and a conductive circuit on the core substrate, and a second capacitor mounted on a surface of the printed circuit board.

Abstract: The present invention provides a method for embedding a power modification component such as a capacitance inside of an adaptor board located to extend over and beyond the vias of the main circuit board so that a portion of the interposer board containing the embedded capacitance is located beyond where the vias or blind vias are located. This permits that via to conduct through the opening. In this way, the capacitance and the resistance will have a closer contact point to the electrical component. With this methodology a resistance can also be embedded in an opening in the adaptor board and be vertically aligned within the opening to make contact with a pad on top of the adaptor board and a pad at the bottom of the adaptor board so that electricity conducts through the embedded component.

Abstract: A printed circuit board that include: an electronic component having a plating electrode pad having a predetermined thickness; an insulating resin layer that exposes a lower surface of the electrode pad, receives the electronic component, and embodies the electronic component so that the center of the base body forming the electronic component is positioned at the center of the insulating resin layer; and circuit layers that include a circuit pattern disposed on the electrode pad, form inter-layer connection, and are disposed on both surfaces of the insulating resin layer, respectively, the plating electrode pad having a thickness that conforms to a thickness from an upper surface of the electronic component to an upper surface of the insulating resin.

Abstract: A printed circuit board includes an accommodating layer, chip capacitor devices accommodated in the accommodating layer, and a buildup structure formed on the accommodating layer such that the buildup structure covers the chip capacitor devices in the accommodating layer. The buildup structure has mounting conductor structures positioned to mount an IC chip device on a surface of the buildup structure such that the IC chip device is mounted directly over the chip capacitor devices, each of the chip capacitor devices has a dielectric body having a surface facing the buildup structure, a first electrode formed on the dielectric body and extending on the surface of the dielectric body, and a second electrode formed on the dielectric body and extending on the surface of the dielectric body, and the dielectric body is interposed between the first electrode and the second electrode.

Abstract: Embedding a power modification component such as a capacitance inside of an adaptor board located to extend over and beyond the vias of the main circuit board so that a portion of the interposer board containing the embedded capacitance is located beyond where the vias or blinds are located. This permits that via to conduct through the opening. In this way, the capacitance and the resistance will have a closer contact point to the electrical component. A resistance can also be embedded in an opening in the adaptor board and be vertically aligned within the opening to make contact with a pad on top of the adaptor board and a pad at the bottom of the adaptor board so that electricity conducts through the embedded component.

Abstract: Methods for manufacturing a light source circuit board having one or more light emitting components that include providing at least one circuit component on a light source circuit board, wherein the at least one circuit component has an electrical circuit constant that specifies one or more performance parameters for the light source. The methods also include measuring the electrical circuit constant of the at least one circuit component. The methods also include identifying one or more performance parameters for the light source based on the measured electrical constant.

Abstract: A printed circuit board includes a core substrate having an opening portion, an electronic component provided in the opening portion of the core substrate and including a dielectric body, a first electrode formed over the dielectric body, and a second electrode formed over the dielectric body such that the dielectric body is interposed between the first electrode and the second electrode, and a resin filling a gap between the core substrate and the electronic component in the opening portion of the core substrate. The resin filling the gap includes a filler.

Abstract: A circuit board having a semiconductor chip embedded therein includes: a core board having opposing first and second surfaces and a through-hole; a semiconductor chip received in the through-hole and having a first active surface and an opposing second active surface, wherein first electrode pads comprising signal pads, power pads, and ground pads are provided on the first active surface; a first dielectric layer provided on the first surface of the core board and the first active surface of the semiconductor chip and configured to fill a gap between the through-hole and the semiconductor chip so as to secure the semiconductor chip in position to the through-hole; and a first circuit layer disposed in the first dielectric layer so as to be flush with the first dielectric layer, provided with first conductive vias disposed in the first dielectric layer, and electrically connected to the first electrode pads.

Abstract: A multilayer printed circuit board, wherein, on a resin-insulating layer that houses a semiconductor element, another resin-insulating layer and a conductor circuit are formed with conductor circuits electrically connected through a via hole, wherein an electromagnetic shielding layer is formed on a resin-insulating layer surrounding a concave portion for housing a semiconductor element or on the inner wall surface of the concave portion, and the semiconductor element is embedded in the concave portion.

Abstract: Disclosed are an embedded capacitor and a method of fabricating the same. The capacitor includes a metallic substrate, a metallic oxide layer on the metallic substrate, a first electrode layer on a first surface of the metallic oxide layer, and a second electrode layer on a second surface of the metallic oxide layer.

Abstract: An electronic module including a substrate having at least one structure that reduces stress flow through the substrate, wherein the structure comprises at least one trench in a surface of the substrate.

Abstract: A circuit board assembly includes two external circuit boards, at least one electrical connector, at least one electronic component, and at least one hollow substrate. Each external circuit board includes an external electromagnetic shielding layer, a circuit layer and a dielectric layer. In each external circuit board, the dielectric layer is located between the external electromagnetic shielding layer and the circuit layer. The electrical connector is connected between the circuit layers located between the external electromagnetic shielding layers. The electronic component is disposed between the external circuit boards and connected with one of the circuit layers. The hollow substrate with plural openings is disposed between the external circuit boards. The electronic component and the electrical connector are located in the openings. Both a thickness of the electronic component and a height of the electrical connector are smaller than or equal to a thickness of the hollow substrate.

Abstract: Provided is a circuit board including a resin base, and a resistance element formed above the resin base. The resistance element includes a resistance pattern including an electrode portion and an extending portion, and an electrode formed on the electrode portion of the resistance pattern and including a foot portion reduced in thickness toward the extending portion.

Abstract: An assembly carrying a radioisotope power source for attaching to a printed circuit board.

Abstract: A semiconductor device includes a semiconductor substrate, first and second penetration electrodes each penetrating the semiconductor substrate, a multi-level wiring structure formed on the semiconductor substrate, the multi-level wiring structure including a lower-level wiring, an upper-level wiring and an interlayer insulating film between the lower-level wiring and the upper-level wiring, a first wiring pad formed as the lower-level wiring and electrically connected to the first penetration electrode, a second wiring pad formed as the upper-level wiring, a plurality of first through electrodes each formed in the interlayer insulating film to form an electrical connection between the first and second wiring pads, a third wiring pad formed as the lower-level wiring and electrically connected to the second penetration electrode, a fourth wiring pad formed as the upper-level wiring, and a plurality of second through electrodes each formed in the interlayer insulating film.

Abstract: Provided is a ceramic chip assembly configured to economically and reliably insulate an exposed portion of a metal lead wire from an environmental change. The ceramic chip assembly includes a ceramic base having electrical characteristics, a pair of external electrodes that are disposed on a pair of surfaces of the ceramic base, respectively, the surfaces of the ceramic base being opposed to each other, a pair of metal lead wires as single cores having first ends that are electrically and mechanically connected to the external electrodes, respectively, by an electrical conductive adhesive member, an insulation sealant sealing the ceramic base, the external electrodes, and the first ends of the metal lead wires to expose second ends of the metal lead wires, and an insulation polymer coating layer continuously formed on both the insulation sealant and portions of the metal lead wires exposed out of the insulation sealant.

Abstract: A printed wiring board semiconductor package or PWB power core comprising singulated capacitors embedded on multiple layers of the printed wiring board semiconductor package wherein at least a part of each embedded capacitor lies within the die shadow and wherein the embedded, singulated capacitors comprise at least a first electrode and a second electrode. The first electrodes and second electrodes of the embedded singulated capacitors are interconnected to the Vcc (power) terminals and the Vss (ground) terminals respectively of a semiconductor device. The size of the embedded capacitors are varied to produce different self-resonant frequencies and their vertical placements within the PWB semiconductor package are used to control the inherent inductance of the capacitor-semiconductor electrical interconnections so that customized resonant frequencies of the embedded capacitors can be achieved with low impedance.

Abstract: A capacitor comprising: a capacitor body including a plurality of laminated dielectric layers, a plurality of inner electrode layers which are respectively disposed between mutually adjacent ones of the dielectric layers, a first main surface located in a laminated direction of the dielectric layers, and a second main surface opposite to the first main surface; a first outer electrode formed on the first main surface of the capacitor body and electrically connected to the inner electrode layers; a second outer electrode formed on the second main surface of the capacitor body and electrically connected to the inner electrode layers; a first dummy electrode formed on the first main surface of the capacitor body; and a second dummy electrode formed on the second main surface of the capacitor body.

Abstract: A multi-layer semiconductor element package structure with surge protection function includes a substrate unit, an insulated unit, a one-way conduction unit and a protection unit. The substrate unit has at least one top substrate, at least one middle substrate and at least one bottom substrate. The insulated unit has at least one first insulated layer filled between the top substrate and the middle substrate and at least one second insulated layer filled between the middle substrate and the bottom substrate. The one-way conduction unit has a plurality of one-way conduction elements electrically disposed between the top substrate and the middle substrate and enclosed by the first insulated layer. The protection unit has at least one protection element with anti surge current or anti surge voltage function electrically disposed between the middle substrate and the bottom substrate and enclosed by the second insulated layer.

Abstract: A solid state drive includes a printed circuit board, at least one memory and a controller. The at least one memory stores data. The at least one memory is embedded in the substrate of the printed circuit board. The controller controls the at least one memory to perform a write operation or a read operation. The controller is also embedded in the substrate of the printed circuit board.

Abstract: A manufacturing method of a semiconductor device include forming a capacitor by forming an oxide film on a surface of a valve metal based on anodic oxidization and by forming a conductive part made of a conductive material on the oxide film; adhering the capacitor on a semiconductor element mounted on a supporting substrate; and coupling the capacitor to the supporting substrate via an outside connection terminal.

Abstract: An integrated circuit board includes a bridging filtering capacitor, a bypass capacitor, a thermistor, and a varistor. The integrated circuit board further includes an electrolytic capacitor set having a plurality of electrolytic capacitors, which are arranged in parallel and adjacent to each other, and a mounting frame for grouping the electrolytic capacitors. The present invention uses the above elements to reduce the vertical height, the horizontal width, and the occupied area. Therefore, the overall dimension of the circuit board can be reduced to make the electronic devices smaller, especially for thin electronic devices such as LCD TVs and screens.

Abstract: A semiconductor module having one or more integrated antennas in a single package is provided herein to comprise a bonding interconnect structure having a plurality of individual bonding elements that are confined to a relatively small area of the bottom of a package. In particular, the semiconductor module comprises a bonding interconnect structure configured to connect an integrated package to a printed circuit board (PCB), wherein the integrated antenna structures are located at greater center-to-center distance from the IC device than the three dimensional interconnect structures. Therefore, the bonding interconnect structures are confined to a connection area that causes a part of the package containing the one or more antenna structures to extend beyond the bonding interconnect structure as a cantilevered structure. Such a bonding interconnect structure result in a package that is in contact with a PCB at a relatively small area that supports the load of the package.

Abstract: Disclosed are methods of making a semiconductor package comprising at least one thin-film capacitor embedded into at least one build-up layer of said semiconductor package. A thin-film capacitor is provided wherein the thin-film capacitor has a first electrode and a second electrode separated by a dielectric. A temporary carrier layer is applied to the first electrode and the second electrode is patterned. A PWB core and a build-up material are provided, and the build-up material is placed between the PWB core and the patterned second electrode of said thin-film capacitor. The patterned electrode side of the thin-film capacitor is laminated to the PWB core by way of the build-up material, the temporary carrier layer is removed, and the first electrode is patterned.

Abstract: A multilayered printed wiring board includes a plurality of insulating layers; a plurality of wiring layers which are located between the corresponding adjacent insulating layers; and a plurality of interlayer connection conductors for electrically connecting the wiring layers through the insulating layers; wherein a cavity is formed through one or more of the insulating layers so as to insert a first electric/electronic component and an area for embedding a second electric/electronic component is defined for the insulating layers.

Abstract: Disclosed herein are an electromagnetic bandgap structure and a printed circuit board having the same. The bandgap structure includes a conductive layer including a plurality of conductive plates, a first metal layer disposed under the conductive layer and including a first stitching pattern electrically connected to a first conductive plate of the plurality of conductive plates, and a second metal layer disposed under the first metal layer and including a second stitching pattern electrically connected to both the first stitching pattern and a second conductive plate of the plurality of conductive plates. The bandgap to structure includes stitching patterns formed in two layers different from the conductive layer, thus offering a stop-band having a desired bandwidth in a compact structure.