Abstract: An apparatus for the placement of a semiconductor chip on a substrate is provided.

Abstract: A power supply device including a capacitance partition, a control partition, a power switching partition, a thermal conduction partition, a magnetic partition. The thermal conduction partition includes electrical connections to connect other partitions. The thermal conduction partition provides for magnetic shielding of the magnetic partition and thermal dissipation in a substantially orthogonal direction to the electrical connections. The layering arrangement allows automated production and/or testing.

Abstract: A method of forming a component-embedded printed circuit board includes: preparing a first layered structure; preparing a second layered structure that includes an adhesive film and a releasable film; attaching the second layered structure to the first layered structure to form a layered stack, the releasable film releasably covering a mounting region of the first layered structure; heating and pressing the layered stack; cutting the second layered structure through the adhesive film; removing the releasable film together with a portion of the adhesive film from the mounting region to form a hole in the second layered structure; and mounting an electronic component in the hole.

Abstract: The present invention relates to a driving circuit for a display panel and the driving module thereof and a display device and the method for manufacturing the same. The present invention comprises a power generating module, a plurality of signal generating units, a power generating circuit, and a scan control circuit. The power generating module generates a supply power source according to an input power source. The plurality of signal generating units are coupled to the power generating module and generate a plurality of control signals according to the supply power source and a plurality of input signals. The power generating circuit generates a driving power source. The scan control circuit is coupled to the power generating circuit and the plurality of signal generating unit, and generates a plurality of scan signals according to the driving power source and at least one of the plurality of control signals.

Abstract: The purpose of the invention is to provide a mounting apparatus that can mount a part such as a chip, etc. on a substrate effectively and precisely. A wafer is placed on the upper surface of turntable, which has opening section, and a backup section and a head section that hold a chip are lifted up and lowered respectively, at opening section. The wafer and the chip are contacted, pinched and held locally, and then they are heat-bonded. After that, the backup section and the head section are removed. Lift arms equipped on a holding table are inserted between the wafer and turntable, the wafer is lifted up, and opening section is moved relative to the wafer when turntable is rotated. The wafer is placed on turntable again and the bonding process is performed.

Abstract: A method of forming an electrical component is provided. The method comprises preparing a subassembly by electrically connecting an integrated circuit to a flexible circuit; and attaching the subassembly to a multilayer ceramic capacitor having a mounting surface with a curvature deviation exceeding 0.008 inches per inch.

Abstract: A land grid array (LGA) socket uses a series of inclined engagement features to transfer a lateral load into a normal load to retain the LGA package in the socket. The number and position of the engagement features along the side of the socket permits a more uniform transfer of load to the solder ball array as compared to current mechanisms.

Abstract: A computing device has a motherboard circuit substrate having at least one layer of electrical interconnects and a socket arranged to receive a main processor for the computing device, the socket electrically coupled to at least a portion of the layer of electrical interconnects, wherein the circuit substrate has no memory interconnects.

Abstract: An optical communication system comprising: an optical circuit board comprising an optical interface having a transmission region, an optical coupling device comprising: a first optical interface having a first transmission region optically coupled to a corresponding transmission region of the optical interface of the optical circuit board, a second optical interface having a second transmission region adapted to be optically coupled to a corresponding transmission region of an optical interface of a mating optical device, a fixation part, wherein the optical communication system comprises a support element glued to the fixation part of the optical coupling device and removably mounted on the optical circuit board.

Abstract: Devices and methods for constructing low-profile, minimal-thickness electronic devices using existing production techniques are disclosed in this application. An electronic component and interposer form a sub-assembly. The sub-assembly is placed in an aperture in a circuit board with the interposer providing interconnections between the electronic component and the circuit board. The circuit board is coupled to the electronic component at least by one or more fluidic channels included in the interposer. The sub-assembly placed in the aperture in the circuit board as described herein conceals the thickness of the integrated circuit within the thickness of the circuit board, reducing overall thickness.

Abstract: Techniques for reducing resonance in contact fingers of a connector are described herein. An example of a device in accordance with the present techniques includes an add-in-card that includes a circuit board and an edge contact finger disposed on an outer surface of the circuit board. The add-in-card also includes a resonator disposed in an internal layer of the circuit board and coupled to the edge contact finger, wherein the resonator reduces a resonance in the edge contact finger.

Abstract: A surface treated copper foil which is well bonded to a resin and achieves excellent visibility when observed through the resin, and a laminate using the same are provided.

Abstract: Disclosed herein is a method for applying a fluid to a component during a placement cycle. The method includes providing a component placement machine including a housing having a frame attached thereto, the frame having a pick and place head. The method includes providing a fluid application station contiguous with the housing and adapted to apply fluid to the component, moving the housing to a pick location, picking the component from a supply of components using the pick and place head, moving the housing to a location, applying fluid to the picked component, and placing the picked component with the fluid applied onto the printed circuit board at the location. The fluid application step is accomplished during the moving step or placing step. The method may further include repeating the steps for another component where the fluid application step is accomplished during the repeated picking step of the additional component.

Abstract: A welding system component includes a circuit board for the welding system component. An interface has a main riser portion with a fastener passageway formed therethrough. The interface has an extension portion with a terminal passageway formed therethrough. The extension portion is electrically connected to the circuit board with a terminal disposed in the terminal passageway. The extension portion is spaced away from a surface of the circuit board. A capacitor is electrically connected to the main riser portion with a fastener disposed in the fastener passageway.

Abstract: An electronic component embedded printed circuit board and a method for manufacturing the same. The printed circuit board includes: a core having a cavity formed therein; an electronic component unit embedded in the cavity, including a plurality of electronic components, and having a coating layer formed on an outer peripheral surface of the electronic component unit to fix the plurality of electronic components; and an insulating layer laminated at least on the top of the core. An outer layer circuit pattern may be formed on the insulating layer.

Abstract: When bump electrodes 26 of a semiconductor light-emitting element 2 and electrode portions 21 of a mounting board 3 are joined to each other, power is supplied to the electrode portions 21 of the mounting board 3 to allow the semiconductor light-emitting element 2 to emit light, the optical properties of the semiconductor light-emitting element 2 having emitted light are detected, and the detected value of optical properties is processed to obtain the joining state of the bump electrodes 26 of the semiconductor light-emitting element 2 and the electrode portions 21 of the mounting board 3, so that the completion of joining is determined. Thus, the semiconductor light-emitting element can be satisfactorily joined to the electrode portions on the mounting board via the metal electrodes formed on the semiconductor light-emitting element.

Abstract: A manufacturing method of a package structure is provided. In the manufacturing method, a metal substrate having a seed layer is provided. A patterned circuit layer is formed on a portion of the seed layer. A first patterned dry film layer is formed on the other portion of the seed layer. A surface treatment layer is electroplated on the patterned circuit layer with use of the first patterned dry film layer as an electroplating mask. The first patterned dry film layer is removed. A chip bonding process is performed to electrically connect a chip to the surface treatment layer. An encapsulant is formed on the metal substrate. The encapsulant encapsulates the chip, the surface treatment layer, and the patterned circuit layer. The metal substrate and the seed layer are removed to expose a bottom surface of the encapsulant and a lower surface of the patterned circuit layer.

Abstract: A heart activity sensor structure includes a flexible textile substrate, and at least two electrodes with an electric insulation between each of the at least two electrodes. The at least two electrodes are applied on one side of the flexible textile substrate and configured to be placed against a skin of an exerciser in order to measure biosignals related to heart activity. The heart activity sensor also includes an electrostatic discharge shield applied on one side of the flexible textile substrate for protecting the at least two electrodes from static electricity.

Abstract: In one preferred aspects, methods are provided to produce a three-dimensional feature, comprising: (a) providing a nano-manipulator device; (b) positioning an article with the nano-manipulator device; and (c) manipulating the article to produce the three-dimensional feature. The invention relates to production of nanoscale systems that can be tailored with specific physical and/or electrical characteristics or need to have these characteristics modified. Methods and apparatus are presented that can construct three-dimensional nanostructures and can also modify existing nanostructures in three dimensions.

Abstract: A circuit board assembly includes a circuit board, at least one pad formed on the circuit board, and at least one connection line. Each of the at least one connection line includes a connection end connected to a respective one of the at least one pad and has the same resistance value as the respective pad.

Abstract: A heat sinking device for a component mounted on an electronic circuit board, including: a hollow body, of straight cylindrical or prismatic form, including a first material, arranged vertically on top of the electronic circuit board, the useful volume of the body including at least the component, a resin including a second material, at least partially filling the internal volume of the body so as to contain the component. The heat sinking device can be arranged on an insulating separator element, the resin can be introduced in the liquid state.

Abstract: A circuit board includes a wiring board on which is mounted first and second laminated ceramic capacitors near or adjacent to each other, arranged along a direction parallel or substantially parallel to a main surface of the wiring board, and electrically connected in series or in parallel via a conductive pattern provided on the wiring board. One width direction side surface of the first laminated ceramic capacitor and one length direction end surface of the second laminated ceramic capacitor oppose each other perpendicularly or approximately perpendicularly.

Abstract: An electronic module includes a substrate, which includes a dielectric material having multiple sides, including first and second sides, and first and second cavities indented respectively within the first and second sides. First and second conductive contacts within the first and second cavities are configured for contact with at least first and second electronic components that are mounted respectively in the first and second cavities. Conductive traces within the substrate are in electrical communication with the first and second conductive contacts.

Abstract: A control panel for proximity and force sensing, includes a cover layer, a first electrode layer including a first force sensor electrode, a second force sensor electrode positioned in a second electrode layer or on a support layer, and a dielectric substrate at least a portion of which is compressible and is positioned between the first and second force sensor electrodes. The support layer is positioned to support at the vicinity of the second force sensor electrode support location so that compression of the dielectric substrate and the separation of the first and second force sensor electrodes depends on the magnitude of a force applied to the cover layer. Touch sensor electrodes are positioned on one or more of the electrode layers such that their capacitance depends on proximity of an object such as a finger. Controllers measure the capacitance of the force and touch sensor electrodes respectively and output force and touch proximity signals.

Abstract: A disk drive read circuit is disclosed comprising a read element for generating a read signal, and a sense amplifier comprising an input terminal coupled through a first capacitor to the read element and an output terminal coupled through a second capacitor to a transmission line, wherein the sense amplifier is for amplifying the read signal.

Abstract: This is directed to methods and apparatus for shielding a circuitry region of an electronic device from interference (e.g., EMI). A conductive dam may be formed about a periphery of the circuitry region. A non-conductive or electrically insulating fill may then be applied to the circuitry region within the dam. Next, a conductive cover may be applied above the fill. The cover may be electrically coupled to the dam. The dam may include two or more layers of conductive material stacked on top of one another. In some embodiments, the conductive cover may be pad printed or screen printed above the fill. In other embodiments, the conductive cover may be a conductive tablet that is melted above the fill.

Abstract: Embodiments of the invention provide a method of manufacturing an embedded printed circuit board, which includes the following operations in the order presented: a first operation of forming a first cavity and a third cavity, disposing a first device in the first cavity and disposing a third device in the third cavity; a second operation of forming a second cavity and a fourth cavity, disposing a second device in the second cavity; a third operation of providing an insulating member; a fourth operation of disposing a first base substrate and a second base substrate and pressure laminating the first base substrate, the second base substrate, and the insulating member together; and a fifth operation of forming a first copper clad laminate and forming a second copper clad laminate.

Abstract: In a component mounting device (1) which includes a first mounting lane (L1) and a second mounting lane (L2) and for which an independence mounting mode and an alternation mounting mode are selectable, a first limited movable area (R1A) and a first limited movable area (R1B) in which the movements in the horizontal direction of a first mounting head (13A) and a second mounting head (13B) of the mounting lanes are permitted in the independence mounting mode, are set as areas different from second limited movable areas in the alternation mounting mode, to prevent the mounting head of the mounting lane which is continuously operating from entering into the area of the mounting lanes for which the device type changing operation is being performed.

Abstract: When performing the device type changing operation with the change of the board type to undergo mounting, the component mounting device, which has a first mounting lane and a second mounting lane and which is structured so as to be able to select either an independent mounting mode or an alternate mounting mode, moves a mounting head of the mounting lane to and thereafter positions and fixes to a previously-set predetermined withdraw position [P] where entry of a portion of a body of an operator by way of an opening (19) formed in a protective cover (18a) can be prevented and where safety of the operator is not impaired even if a mounting head of a mounting lane on the other side has undergone collision.

Abstract: A nozzle placement history data management method is accomplished by an electronic component mounting apparatus having an adsorption nozzle detachably placed on a mount head. The presence or absence of the adsorption nozzle is detected by a flow rate sensor. A board recognition camera provides identification information of the nozzle with the result that the nozzle placement history data can be updated, managed and updated.

Abstract: There is provided a power module production method that is capable of stably producing a power module with highly reliable properties, and so forth. The power module production method produces a power module 1 by stacking a cooler 5, an insulating resin sheet 4, a heat sink block 3, and a semiconductor chip 2, wherein a first insulating resin sheet 41, which forms a lower layer of the insulating resin sheet 4, is first bonded to the cooler 5 by thermal compression. Next, with a second insulating resin sheet 42, which forms an upper layer of the insulating resin sheet 4, interposed between the first insulating resin sheet 41 and the heat sink block 3, the second insulating resin sheet 42 is bonded to the first insulating resin sheet 41 by thermal compression, and the heat sink block 3 is bonded to the second insulating resin sheet 42 by thermal compression. The semiconductor chip 2 is then soldered onto the heat sink block 3.

Abstract: In accordance with embodiments of the present disclosure, a circuit board may include a stub corresponding to a portion of a trace running proximate to an edge of the circuit board, wherein the stub is configured to electrically couple to a plating bar for plating electrical paths of the circuit board with a conductive metal and a termination pad electrically coupled to the stub and configured to electrically couple to a termination resistor for resistively terminating the stub.

Abstract: An electronic device includes a dielectric substrate having a first surface, a conductive circuit deposited on the first surface and having a printed conductive ink trace on the first surface, and a conductive interposer mechanically coupled to the substrate. The conductive interposer is electrically coupled to the conductive circuit. The conductive interposer has a separable contact interface configured to be mechanically and electrically connected to a removable contact. Optionally, the conductive interposer may include a main body and a flexible element extending between the main body and the conductive circuit. The flexible element electrically connects the conductive circuit with the main body.

Abstract: Systems and methods electrically connect a first electronic device or electrical component, having a external electrical connector, to a circuit board of a second electronic device. A low-cost, user-installable connection system isolates mechanical stresses imposed on the external electrical connector to within the user-installable connection system, thereby preventing the mechanical stresses from reaching the circuit board in the second electronic device. If the connection becomes faulty, only the low-cost, user-installable connection system must be replaced.

Abstract: An optical device board 2 is set to be a printed circuit board in which an optical device 6 is bonded into a predetermined position of a printed wiring board 5. The optical device board 2 is bonded to a base board 3 provided with a plurality of wiring terminals 7. A lens barrel 4 is bonded to the optical device board 2. The optical device 6 is bonded into a position calculated from an actual measured dimension of the printed wiring board 5, and the calculated position is held and positioning is carried out in such a manner that a central axis of the lens barrel 4 is coincident with the calculated position when the lens barrel 4 is to be bonded to the optical device board 2.

Abstract: A manufacturing method of heat conductive device for an LED has steps of forming a heat sink and an engagement recess in the heat sink by cold forge, punching a heat-conducting disc to form an LED carrier having a mounting portion and a heat-conducting wall formed around the mounting portion, soldering multiple LEDs on the LED carrier, and heating the heat sink to thermally expand the heat sink and assembling the LED carrier and the heat sink so that the heat-conducting wall is assembled with the engagement recess and further chilling the heat sink to thermally retract and tightly hold the LED carrier. The manufacturing method increases contact area and reduces air gaps between the LED carrier and the heat sink to effectively enhance the heat-conducting efficiency of the LED carrier so that the LEDs are operated at a suitable operating temperature to secure a prolonged life duration.

Abstract: Electronic devices having a multi-layer structure that provides enhanced conductivity (thermal and/or electrical conductivity) are disclosed. The multi-layer structure can have a plurality of adjacent layers. At least one layer can primarily provide structural rigidity, and at least another layer can primarily provide enhanced conductivity. The layer of high conductivity can serve to provide the electronic device with greater ability to disperse generated heat and/or to provide an accessible voltage potential (e.g., ground plane). Advantageously, the multi-layer structure can provide enhanced conductivity using an otherwise required structural component and without necessitating an increase in thickness.

Abstract: A printed circuit board is provided. The printed circuit board includes a base having a top and a bottom. The top has a first circuit area, a second circuit area and a slotted area disposed between the first circuit area and the second circuit area. The slotted area includes a first row of a plurality of first slots, each first slot of the plurality of first slots has a first length and is separated from an adjacent first slot by a first space. The slotted area includes a second row of a plurality of second slots that is positioned parallel with respect to the first row. Each second slot of the plurality of second slots has a second length that is different than the first length and is separated from an adjacent second slot by a second space. The second space includes a different length than the first space.

Abstract: The present invention discloses an Oven Controlled Crystal Oscillator and a manufacturing method thereof. The Oven Controlled Crystal Oscillator comprises a thermostatic bath, a heating device, a PCB and a signal generating element, where the signal generating element is used for generating a signal of a certain frequency, the heating device, the PCB and the signal generating element are mounted in the thermostatic bath, the signal generating element is mounted in a groove formed on one side of the PCB, while the heating device is mounted against the other side of the PCB that is opposite to the groove. The signal generating element may be a passive crystal resonator or an active crystal oscillator. The Oven Controlled Crystal Oscillator according to the invention is advantageous for a small volume and a high temperature control precision.

Abstract: An assembly (600) includes a substrate (601), an electrical component (1202), and a shield (400). The electrical component is disposed beneath the shield, with both being coupled to a major face (602) of the substrate. The shield can include an upper surface (401) including one or more indentations (408,409) disposed above, and extending toward, the electrical component. A shim (1106) or an injected material (1209) can be substituted for, or used with, the indentations.

Abstract: At least one implementation provides a hold down for an electronic device. The electronic device includes a support frame, a circuit board coupled to the support frame and having at least one component, a thermal pad thermally coupled to the component, and a heat sink associated with the thermal pad. The hold down includes a generally planar portion adapted to be positioned over a surface of the heat sink. The hold down also includes a plurality of connecting structures extending angularly from the generally planar portion. The connecting structures and configured to engage the support frame to cause the hold down to apply the biasing force to retain the thermal pad against at least one of the heat sink or the component when the heat sink and the thermal pad are positioned between the hold down and the support frame. A method is also provided for attaching the hold down.

Abstract: An electronic device package 100 comprising a lead frame 105 having at least one lead 110 with a notch 205. The notch includes at least one reentrant angle 210 of greater than 180 degrees and the notch is located distal to a cut end 1010 of the lead.

Abstract: A multilayer laminate package and a method of manufacturing the same are provided. The multilayer laminate package includes a cavity layer, a non-cavity layer, an electronic component, and a metalized blind via. The cavity layer includes a first adhesive layer and two first circuit layers, which are stacked with the first adhesive layer between, and an opening. The non-cavity layer includes a second adhesive layer and a second circuit layer. The non-cavity layer is bonded to the cavity layer with the second adhesive layer so as to close one side of the opening. The electronic component is mounted in the opening and is electrically connected to the non-cavity layer exposed through the opening. The metalized blind via electrically connects the non-cavity layer to one of the circuit layers of the cavity layer.

Abstract: Methods and systems for manufacturing a swallowable sensor device are disclosed. Such a method includes mechanically coupling a plurality of internal components, wherein the plurality of internal components includes a printed circuit board having a plurality of projections extending radially outward. A cavity is filled with a potting material, and the mechanically coupled components are inserted into the cavity. The cavity may be pre-filled with the potting material, or may be filled after the mechanically coupled components have been inserted therein. A distal end of each projection abuts against a wall of the cavity thereby preventing the potting material from covering each distal end. The cavity is sealed with a cap causing the potting material to harden within the sealed cavity to form a housing of the swallowable sensor device, wherein the distal end of each projection is exposed to an external environment of the swallowable sensor device.

Abstract: A method of manufacturing radiation tomography apparatus in this invention includes a step of fixing a detector array to a holding member by adjusting relative positions of the detector array and the holding member the base by spacing a scintillator apart from a base through contact of the scintillator of the detector array to a supporting device. Such configuration may realize provision of radiation tomography apparatus with higher spatial resolution by manufacturing a group of detectors having the scintillators of suppressed deviation in arrangement and being arranged regularly upon arranging radiation detectors for forming the group of detectors.

Abstract: A multi-chip socket includes a first cavity having a first support surface to support a first component including a first chip, the first support surface arranged to contact and support the first chip. A second cavity has a second support surface to support a second component including a second chip, the second support surface arranged to contact and support the second chip. The first support surface is in a first plane, and the second support surface is in a second plane, where the first plane is angled with respect to the second plane.

Abstract: An apparatus includes a component bay having an operational height and an expanded height. The component bay is moveable between the operational height and the expanded height. A thermal element divides the component bay into one or more compartments, each compartment configured to receive a system component. The component bay at the operational height provides thermal contact between the received system component and the thermal element.

Abstract: Modular microfluidic channel structures for conducting liquid from a reservoir include a sensor for monitoring a parameter (such as flow rate or pressure) relating to liquid flowing therethrough. The microfluidic channel generally comprises a thermally insulating substrate made of one or more materials such as, e.g., glass, fused silica, parylene, and/or silicone.

Abstract: In accordance with an aspect of the present inventive subject matter, a lighting device includes light-emitting elements that are mounted in a circular mounting area to be directed in a same direction in the circular mounting area between a first connecting electrode and a second connecting electrode disposed on a substrate, the light-emitting elements are divided into groups each including the same number of light-emitting elements, the light-emitting elements within each group are electrically connected in series with one another by metallic wires and electrically connected in series to the first connecting electrode and to the second connecting electrode. The groups each include the same number of light-emitting elements that are electrically connected in parallel between the first connecting electrode and the second connecting electrode. As another aspect of the present inventive subject matter, a method of manufacturing a lighting device is disclosed.

Abstract: According to one embodiment of the invention, a method for manufacturing a circuit board comprises covering with a metal layer a surface of a first resin layer including polyimide resin; forming a plurality of conductive layers arranged on the metal layer with the conductive layers apart from each other in a planer view; roughening surfaces of the conductive layers with an alkaline aqueous solution; and etching a part of the metal layer between the conductive layers in the planer view to expose the surface of the first resin layer after roughening the surfaces of the conductive layers.