Abstract: The present invention provides a metallic laminate and a method for preparing the same. The metallic laminate includes a metal layer, and at least one polymide resin layer. The polymide resin layer has a modulus of elasticity of 70 Mpa at 400° C.

Abstract: A circuit structure and a fabrication method thereof manly use a plurality of wires to connect in series a plurality of pads to form a stretchable circuit. Each of the wires has a first end, a second end and an intermediate segment located between the first end and the second end, wherein the first end and the second end are respectively connected to different pads, and the position of the intermediate segment is higher than the positions of the first end and the second end. Since the connection manner of the wires and the pads has 3-D freedoms, the circuit structure can withstand both horizontal and vertical deformations and has an outstanding reliability.

Abstract: It is an object of the present invention to provide a flexible multilayer wiring board that can be easily reduced in thickness and that also has sufficient durability against repeated bending or heat shock. A preferred mode of the flexible multilayer wiring board comprises a flexible inner layer board obtained by forming an inner layer wiring on both sides of an insulating layer, an outer layer wiring situated on at least one side of the inner layer board, and insulating adhesive sheets lying between the inner layer board and outer layer wiring. One of the insulating adhesive sheets are composed of an imide group-containing polymer.

Abstract: A method is for making an electronic device and includes forming an interconnect layer stack on a sacrificial substrate and having a plurality of patterned electrical conductor layers, and a dielectric layer between adjacent patterned electrical conductor layers. The method also includes laminating and electrically joining through an intermetallic bond a liquid crystal polymer (LCP) substrate to the interconnect layer stack on a side thereof opposite the sacrificial substrate. The method further includes removing the sacrificial substrate to expose a lowermost patterned electrical conductor layer, and electrically coupling at least one first device to the lowermost patterned electrical conductor layer.

Abstract: A method of making an electronic device includes forming a circuit layer on a liquid crystal polymer (LCP) substrate and having at least one solder pad. The method also includes forming an LCP solder mask having at least one aperture therein alignable with the at least one solder pad. The method further includes aligning and laminating the LCP solder mask and the LCP substrate together, then positioning solder paste in the at least one aperture. At least one circuit component may then be attached to the at least one solder pad using the solder paste.

Abstract: A method for making an electronic device includes forming an interconnect layer stack on a rigid wafer substrate having a plurality of patterned electrical conductor layers, a dielectric layer between adjacent patterned electrical conductor layers, and at least one solder pad on an uppermost patterned electrical conductor layer. An LCP solder mask having at least one aperture therein alignable with the at least one solder pad is formed. The LCP solder mask and interconnect layer stack are aligned and laminated together. Solder is positioned in the at least one aperture. At least one circuit component is attached to the at least one solder pad using the solder.

Abstract: A flexible display apparatus including a first flexible film, a second flexible film, and a flexible display panel is provided. The second flexible film is disposed over the first flexible film, wherein a channel exists between the first flexible film and the second flexible film. The flexible display panel is disposed on the second flexible film. A fabrication method of a flexible display apparatus is also provided.

Abstract: A flat display panel is disclosed. In one embodiment, the flat display panel includes i) a first substrate on which a display unit is formed, ii) a second substrate formed to face the first substrate, iii) a resin layer formed on the second substrate; a window formed on the resin layer, iv) a flexible printed circuit (FPC) and a spacer formed between the window and the first end of the FPC. A first end of the FPC is combined with the second substrate, and a second end of the FPC is combined with the first substrate, so that the first substrate and the second substrate are electrically connected to each other.

Abstract: A circuit board assembly includes a circuit board, a fixing device, and a color-changing layer. The fixing device is capable of holding and securing the circuit board and includes a main body and a cover. The cover is rotatably hinged to the main body. The color-changing layer is located on either or both of the circuit board and cover. When the circuit board is assembled at a predetermined position of the fixing device and is secured on the main body by the cover, the cover exerts a pressure to form protruding points on the color-changing layer at the positions corresponding to the elastic contacts, the color-changing generates an electric field and changes color, which is easily and quickly verifiable by a worker.

Abstract: The present invention provides a high-performance flexible circuit board having excellent flexibility, a fine wiring pattern, and fine electric contacts, and a manufacturing method thereof. In a flexible circuit board (20), a second insulating layer (24) made of an inorganic material is positioned between a wiring layer (25) and a first insulating layer (23) made of an inorganic material.

Abstract: Electrical components such as integrated circuits may be mounted on a printed circuit board. To prevent the electrical components from being subjected to electromagnetic interference, a radio-frequency shielding structure may be mounted over the electrical components. The radio-frequency shielding structure may be formed from a printed circuit that includes a ground plane such as a flex circuit or rigid printed circuit board that includes at least one blanket layer of metal. The printed circuit board to which the electrical components are mounted may include a recess in which the electrical components are mounted. Additional components may be mounted to the interior and exterior surface of the radio-frequency shielding structure. The radio-frequency shielding structure may be formed from a flex circuit that has slits at its corners to accommodate folding.

Abstract: An FPCB and a method of manufacturing the same, in which an electrical signal-conductive portion of the FPCB is subjected to little stress so as not to be broken by fatigue in spite of repeated bending of the FPCB, thereby increasing the lifetime of the FPCB.

Abstract: Disclosed is a rigid-flexible circuit board, which includes a rigid region and a flexible region, the rigid region including a flexible substrate having a first circuit layer on both surfaces thereof, a metal core substrate formed on the flexible substrate and having a second circuit layer on both surfaces thereof, and an adhesive layer disposed between the flexible substrate and the metal core substrate, wherein the metal core substrate includes a metal core having a through hole, and an insulating layer formed on a surface of the metal core, so that the rigid region and the flexible region are thermally separated from each other and heat dissipation properties of the rigid region are improved. A method of manufacturing the rigid-flexible circuit board is also provided.

Abstract: Some embodiments of the invention include thin film capacitors formed in a package substrate of an integrated circuit package. At least one of the thin film capacitors includes a first electrode layer, a second electrode layer, and a dielectric layer between the first and second electrode layers. Each of the first and second electrode layers and the dielectric layer is formed individually and directly on the package substrate. Other embodiments are described and claimed.

Abstract: A golden finger for flexible printed circuitboard, comprises: a frame with a tail, being composed of a stiffening plate, a bottom substrate, a bottom copper layer, a cover layer, and a top copper layer while enabling the bottom copper layer to be formed with at least one first routing and at least one second routing, and enabling the top copper layer to be formed with at least one first pin and at least one second pin; at least one first via hole, each being filled with a conductive material and disposed at a position between its corresponding first pin and first routing for connecting the first pin to the first routing electrically; and at least one second via hole, each filled with a conductive material and being disposed at a position between the its corresponding second pin and second routing for connecting the second pin to the second routing electrically.

Abstract: A method of manufacturing a flexible printed circuit board having an insulation layer, a first signal wiring layer including a microstrip line, a second signal wiring layer including a signal connection terminal for allowing the microstrip line to connect the exterior connector electrically, and a ground conductive section having a ground connection terminal for connecting the exterior connector. The microstrip line and the signal connection terminal are connected to each other by a wiring via hole. The wiring via hole passes through the insulation layer, the first signal wiring layer, and the second signal wiring layer. The microstrip line has a taper section which gradually enlarges a width of the microstrip line toward the wiring via hole in the vicinity of the wiring via hole. The ground conductive section that corresponds to the microstrip line has a taper section with a shape matching the taper section of the microstrip line.

Abstract: The invention relates to a resin film having a high adhesiveness to other materials, an adhesive sheet, a circuit board and an electronic apparatus in which an adhesive layer and the resin film are firmly adhered. A resin film (1) includes a plurality of projected portions (10) each having a filler (9) in an apex portion (10a) and a resin material. The projected portions (10) are formed on at least one surface of a sheet portion (16).

Abstract: A resonant circuit for use with a radio-wave detection system for the prevention of shoplifting or the like, which is formed on a flexible substrate and has a coil and capacitor circuit whereby the capacitor has an indented area in the dielectric of the capacitor to promote disablement of the circuit when exposed to a strong electromagnetic field. Upon exposure to a strong electromagnetic field, an electrical short forms across the dielectric of capacitor in the indented area. Because the short is fragile and can be opened by flexure of the circuit, an island of reinforcing material is formed in the indented area, such that when the substrate is flexed, the indented area remains rigid to protect the short. The indented area can be further stress-relieved by introducing a gap in the conductors forming the capacitor plates.

Abstract: A wiring body connection structure includes a first wiring body and a second wiring body, the first wiring body having a first base material made of an elastomer and a first wiring containing an elastomer and a conductive material, the second wiring body having a second base material and a second wiring. In the wiring body connection structure, a laminated section is partitioned where a first end of the first wiring body and a second end of the second wiring body overlap in a front-rear direction. The wiring body connection structure further includes a cover member arranged on a front surface of the first wiring body, and a conductive adhesive layer bonding the first end and the second end in the laminated section while ensuring a conductive property. The cover member is interposed between a frontmost end of the second end and the first wiring in the laminated section.

Abstract: A method of producing an electronic device includes a holding of a circuit board and a decoration sheet in a cavity of a mold, and a filling and solidifying of thermosetting resin in the cavity. A casing is molded by the solidified thermosetting resin so as to seal electronic parts and a first face of the circuit board having the electronic parts. Further, the decoration sheet is integrated with the casing by the solidified thermosetting resin. An outer surface of the casing is defined by a second face of the circuit board opposite from the first face and the decoration sheet.

Abstract: A microelectronic substrate, a method of forming the same, and a system including the same. The microelectronic substrate comprises: a conductive layer; a spacer layer disposed onto the conductive dielectric layer; a dielectric build-up layer disposed onto the spacer layer, the spacer layer being made of a material that has a lower shrinkage than a material of the embedding dielectric-build-up layer during curing, and a higher viscosity than a material of the embedding dielectric build-up layer in its pre-cure form and during curing; and active or passive microelectronic components embedded within the dielectric build-up layer.

Abstract: An electronic apparatus includes a substrate, electronic components mounted on the substrate, an antenna mounted on the substrate, and a resin material containing a dielectric constant adjusting material added therein, and sealing the electronic components and the antenna.

Abstract: A flexible printed circuit board includes a base and a coverlay. The base includes a main portion and a distal portion connecting with the main portion. The distal portion has a first part and a second exposed part. The coverlay is formed on the base and covers the main portion and the first part of the distal portion. The second exposed part of the distal portion is uncovered by the coverlay. The coverlay includes a curved edge serving as an interface between the first part and second part of the distal portion.

Abstract: A method of manufacturing a heat radiation substrate having a metal core, including injection-molding mixed powder of carbon nanotubes and metal in a die to fabricate a metal core having through holes; molding the entire metal core including the through holes with an insulating resin to fabricate a metal core substrate; processing the insulating resin provided in the through holes to form connection holes; and forming a circuit pattern on the metal core substrate in which the connection holes are formed.

Abstract: The invention relates to flexible circuits and more particularly to flexible printed circuits having cover layers. The cover layers may be a chemically-etchable adhesive polyimide. The cover layers may be patterned after they are applied to the flexible circuit substrate.

Abstract: A conductor carrier includes a base insulating film, a contact insulating film, at least one first printed conductor and one second printed conductor. The contact insulating film includes at least one first recess and one second recess. The printed conductors are embedded between the two insulating films and each forms a first overlapping region with the first or second recess of the contact insulating film. The conductor carrier also includes an insulating region which separates the first printed conductor from the second printed conductor in an insulating manner due to the contact insulating film being less raised than outside the insulating region, and extends between the first and second recesses of the contact insulating film in a meandering manner. A configuration having the conductor carrier is also provided.

Abstract: Some embodiments teach a method of preparing a flexible substrate assembly. The method can include: (a) providing a carrier substrate; (b) providing a cross-linking adhesive; (c) providing a plastic substrate; and (d) coupling the carrier substrate to the plastic substrate using the cross-linking adhesive. Other embodiments are disclosed in this application.

Abstract: A flexible printed circuit board wherein the insulative substrate 34 having a plurality of conductive layers 36b covered with a protective layer 38 is encircled by a mesh-cloth member 32.

Abstract: A flexible sheet of organic polymer material, may include a monolithically fabricated array of one or more types of cells juxtaposed among them to form a multi-cell sheet. Each cell may include a self consistent, organic base integrated circuit, replicated in each cell of same type of the array, and shares, in common with other cells of same type, at least a conductor layer of either an electrical supply rail of the integrated circuit or of an input/output of the integrated circuit. A piece of the multi-cell, sheet including any number of self consistent integrated circuit cells, may be severed from the multi-cell sheet by cutting the sheet along intercell boundaries or straight lines, with a reduced affect on the operability of any cell spared by the cutting.

Abstract: A liquid crystal display module includes a liquid crystal display panel and a backlight unit under the liquid crystal display panel. The backlight unit includes at least one light emitting diode. The liquid crystal display module further comprises a bottom frame surrounding the backlight unit. The bottom frame comprises a printed circuit board and the at least one light emitting diode is disposed on the printed circuit board. The liquid crystal display module also includes a main frame surrounding the liquid crystal display panel and a top frame surrounding a front edge of the liquid crystal display panel and combined with the bottom frame through the main frame.

Abstract: An electro-optic apparatus includes an electro-optic panel, a wiring board, and an integrated circuit unit. The integrated circuit unit including a heat radiating member arranged so as to overlap at least partly with the integrated circuit unit.

Abstract: A housing comprising a liquid-tight electric bushing is provided. The housing comprises an opening and a printed circuit board comprising at least first and second layers. The first layer is a top side of the printed circuit board and spans the opening. A first contact element is disposed on the top side and in a blind bore through the first layer that extends to the second layer. The second layer is a conductor track in the interior of the printed circuit board.

Abstract: The FPC that is designed to have the special shape, an elastic portion, can shorten its length by elastic force after it is turned over to the reverse side of the light source unit for achieving the purposes without wasting any space of the LCD module and incurring the inconvenience of user.

Abstract: A package of an environmental sensitive element including a flexible substrate, an environmental sensitive element, a flexible sacrificial layer and a packaging structure is provided. The environmental sensitive element is disposed on the flexible substrate. The flexible sacrificial layer is disposed on the environmental sensitive element, wherein the environmental sensitive element includes a plurality of first thin films and the flexible sacrificial layer includes a plurality of second thin films. The bonding strength between two adjacent second thin films is substantially equal to or lower than the bonding strength between two adjacent first thin films. Further, the packaging structure covers the environmental sensitive element and the flexible sacrificial layer.

Abstract: Provided is a process for producing a glass plate with a conductive printed wire, which does not require a screen plate for each model, facilitates adjustments for desired heat generation performance or antenna performance, has an excellent adhesion to a glass plate surface, and minimizes surface roughness. The process for producing a glass plate with a conductive printed wire is characterized in that a laminate comprising a layer obtained by electro printing a first conductive toner having a number standard average particle size (D50) of 10 ?m<D50?50 ?m and a layer obtained by electro printing a second conductive toner having a particle size (D50) of 5 ?m?D50?10 ?m is formed on a surface of a glass plate and the glass plate is heated to fire the toners to thereby form a conductive printed wire having a predetermined pattern on the surface of the glass plate.

Abstract: A flexible printed circuit and a display module comprising the flexible printed circuit are disclosed. The display module comprises a display panel, a printed circuit board, and a flexible printed circuit. The flexible printed circuit electrically connects the display panel and the printed circuit board, and further comprises a flexible substrate and a cover lay. The flexible substrate has an upper surface and two opposite end portions. The cover lay is disposed on the upper surface of the flexible substrate and extends along a lengthwise direction of the flexible substrate. The cover lay further has two opposite sides each also extending along the lengthwise direction of the flexible substrate. Each of the sides has at least a partially continuous contour which is formed with a discontinuous status on at least one of the end portions.

Abstract: A main body for attaching an electronic component, for example, a transponder, on a rubber article, such as a tire, a conveyor belt, or the like. The mount has a connecting layer made, in one embodiment, of uncured, curable rubber material which is covered by an adhering protection film prior to use. A main body made of cured or uncured rubber material is permanently connected with this connecting layer and has a recess for accommodating the electronic component. A cover preferably made of the main body material, serves for fixing the electronic component in the recess in the main body.

Abstract: Disclosed herein is a method of manufacturing a heat radiation substrate, including injection-molding mixed powder of carbon nanotubes and metal in a die to fabricate a metal core having through holes; molding the entire metal core including the through holes with an insulating resin to fabricate a metal core substrate; processing the insulating resin provided in the through holes to form connection holes; and forming a circuit pattern on the metal core substrate in which the connection holes are formed.

Abstract: The present invention relates to partially rigid flexible circuits having both rigid portions and flexible portions and methods for making the same.

Abstract: A microelectronic substrate, a method of forming the same, and a system including the same. The microelectronic substrate comprises: a conductive layer; a spacer layer disposed onto the conductive dielectric layer; a dielectric build-up layer disposed onto the spacer layer, the spacer layer being made of a material that has a lower shrinkage than a material of the embedding dielectric-build-up layer during curing, and a higher viscosity than a material of the embedding dielectric build-up layer in its pre-cure form and during curing; and active or passive microelectronic components embedded within the dielectric build-up layer.

Abstract: A stretchable electronic circuit that includes a stretchable base substrate having a plurality of stretchable conductors formed onto a surface thereof, with both the stretchable base substrate and conductors being bendable together about two orthogonal axes. The stretchable circuit also includes a stretchable sensor layer attached to the base substrate with a cavity formed therein which has a contact point exposing one of the plurality of stretchable conductors. The stretchable electronic circuit further includes a surface mount device (SMD) package with a conductor contact protrusion installed into the cavity, and wherein a substantially constant electrical connection is established between the conductor contact protrusion and the stretchable conductor at the contact point by tensile forces interacting between the stretchable base substrate and the stretchable sensor layer.

Abstract: It is configured to comprise a semiconductor chip 110, a resin member 106 for forming a cavity 109 in which this semiconductor chip 110 is installed, and wiring 105 constructed of pattern wiring 105b formed so as to be exposed to an upper surface 106b of this resin member 106 and also connected to the semiconductor chip 110 and a post part 105a in which one end is connected to the pattern wiring 105b and also the other end is formed so as to be exposed to a lower surface 106a of the resin member 106.

Abstract: A circuit including a flexible substrate and at least one electric element attached to the substrate, the substrate including at least one cavity arranged near the electric element and helping to break or distort the electric element in response to a flexion or stretching of the substrate. Application in particular is to the manufacture of tear-proof electronic micromodules.

Abstract: An exemplary adhesive layer includes an adhesive main body having a first adhesive surface and a second adhesive surface on an opposite side of the adhesive main body to the first adhesive surface. The adhesive main body defines a number of through-holes between the first adhesive surface and the second adhesive surface therein. The through-holes are filled with an inner adhesive that has a higher adhesion than the adhesive main body. Adhesiveness of the first adhesive surface and the second adhesive surface of the adhesive main body can be improved, thereby preventing a printed circuit board having the adhesive layer from distortion.

Abstract: An electronic parts packaging structure including an insulating layer acting as a flexible substrate, an electronic parts buried in the insulating layer in a state that a whole electronic parts is covered with the insulating layer, and a wiring layer buried in the insulating layer and connected electrically to a connection pad of the electronic parts. A structure body in which a plurality of electronic parts are buried in the insulating layer may be folded and electronic parts may be connected electrically.

Abstract: A metal base circuit board to be used for a hybrid integrated circuit, including circuits provided on a metal plate via an insulating layer, a power semiconductor mounted on the circuit, and a control semiconductor to control the power semiconductor, provided on the circuit. A low capacitance portion is embedded under a circuit portion on which the control semiconductor is mounted, preferably. The low capacitance portion is made of a resin containing an inorganic filler and has a dielectric constant of from 2 to 9.

Abstract: A flexible printed circuit board has an insulation layer, a first signal wiring layer including a microstrip line, a second signal wiring layer including a signal connection terminal for allowing the microstrip line to connect the exterior connector electrically, and a ground conductive section having a ground connection terminal for connecting the exterior connector. The microstrip line and the signal connection terminal are connected to each other by a wiring via hole. The wiring via hole passes through the insulation layer, the first signal wiring layer, and the second signal wiring layer. The microstrip line has a taper section which gradually enlarges a width of the microstrip line toward the wiring via hole in the vicinity of the wiring via hole. The ground conductive section that corresponds to the microstrip line has a taper section with a shape matching the taper section of the microstrip line.

Abstract: A display device is arranged such that a voice device is laminated on a liquid crystal panel so as to be confined in a planar area of the liquid crystal panel, and a voice-system circuit block which drives the voice device is formed on the thin film substrate of the liquid crystal panel. A signal is inputted into the voice-system circuit block through an FPC which is connected to the thin film substrate and which inputs a video signal, and the signal processed at the voice-system circuit block is conducted through the FPC. A connecting terminal part is provided in a middle portion of the FPC and adhered to an FPC. One end of the FPC is connected to the voice device. In this way, a multifunctional display device can be achieved at low cost by efficiently using a limited space around the display element without sacrificing the advantages of a lightweight and thin-shaped flat display device.

Abstract: A composite sandwich structure carrying an externally applied structural load and having embedded electronics, that in one embodiment includes two multilayered composite facesheet laminates, a central core, embedded electronic components within the central core region, embedded electrical conductors within the central core region, and two multilayer printed circuit laminates that are secondarily bonded or cured to the inner surface of the sandwich facesheet laminates. The electronic components and electrical conductors, which are located in the central core region of the sandwich element, are attached to one or both of the two circuit laminates.

Abstract: Compositions and processes for the preparation of printed circuits from epoxy compositions are provided. The epoxy compositions exhibit low viscosity in the uncured state and low coefficient of thermal expansion in the cured state. The low dielectric constant compositions of the invention are well-suited for use in multi-layer printed circuit boards.