Abstract: A flexible electronic reading device, the device comprising a display part and a handle, wherein said display part comprises: a display backplane on a flexible substrate; and a display mounted over said display backplane; wherein said handle is located at one edge of said display backplane and contains display interface electronics for said display; and wherein said display part of said electronic reading device comprises a unitary, continuous structure lacking a separate housing.

Abstract: A flexible printed circuit board with multiple layers includes an inner wiring substrate and at least one outer wiring plate. Each outer wiring plate is connected to one surface of the inner wiring substrate, and defines at least one through hole which passes through the outer wiring plate to expose the inner wiring substrate. Each outer wiring plate further includes an adhesive plate connected to the inner wiring substrate. The adhesive plate includes a stepped portion extending towards a center of the through hole.

Abstract: A printed circuit board includes a plurality of layers including attachment layers and routing layers; and via patterns formed in the plurality of layers, each of the via patterns including first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; ground vias extending through at least the attachment layers, the ground vias including ground conductors; and shadow vias located adjacent to each of the first and second signal vias, wherein the shadow vias are free of conductive material in the attachment layers. The printed circuit board may further include slot vias extending through the attachment layers and located between via patterns.

Abstract: A non-planar printed circuit board has an interior surface and an exterior surface. Between the interior surface and exterior surfaces are layers of conductive and dielectric materials. Passive and active electrical components are embedded within the interior and exterior surfaces. A hollow region is defined by the interior surface of the non-planar circuit board. The non-planar printed circuit board is manufactured on a mandrel having a non-planar shape such as, for example, a cylinder or sphere so as to form a hollow, curved non-planar structure.

Abstract: A circuit board includes an inorganic material insulating layer, a first circuit pattern layer formed on a surface of the inorganic material insulating layer, a first build-up insulating layer formed on the inorganic material insulating layer and formed of an organic material, and a second circuit pattern layer formed on a surface of the first build-up insulating layer.

Abstract: There are provided an insulating film, a printed circuit board including the insulating film, and a method of manufacturing the printed circuit board. The insulating film includes a first insulating material; a second insulating material; and a metal thin film disposed between the first insulating material and the second insulating material.

Abstract: A receiving device includes a shield case which is in a hollow box shape that is open on one side. The shield case reduces external interfering signals which interfere with an input signal of a broadcast wave. A printed wiring board includes a conductive portion that is electrically connected with an electronic component. A soldered portion is formed along a protrusion-free linearly extending side of an opening edge of the shield case. The soldered portion electrically connects with solder the shield case and the conductive portion.

Abstract: There is provided a flexible display having a plurality of innovations configured to allow bending of a portion or portions to reduce apparent border size and/or utilize the side surface of an assembled flexible display.

Abstract: According to one embodiment, a suspension assembly includes a support plate, a trace member on the support plate and a drive element mounted on the trace member. The trace member includes a metal plate, and a multilayered member on the metal plate. The multilayered member includes a first insulating layer, a conductive layer stacked on the first insulating layer, a second insulating layer stacked on the conductive layer. The multilayered member includes a mount portion on which the drive element is mounted, and a branching portion arranged along the mount portion with a gap therebetween. At least one portion of the branching portion is formed into a thin portion having a thickness less than other portions of the multilayered member.

Abstract: The present invention relates to a flexible display panel for suppressing a problem in which a crack such as disconnection on an internal circuit layer or the like is generated or a required warpage level is not attainable in a warped area while bending an edge portion thereof. According to an embodiment of the present invention, the layer structure of a signal line portion for electrically connecting elements provided within a display area and a non-active area may be simplified, and a protective member may be formed thereon, thereby obtaining the effect of minimizing the damage of the layer structure due to bending.

Abstract: The present invention generally relates to deformable polymer composites, and more particularly to, deformable polymer composites with controlled electrical performance during deformation through tailored strain-dependent conductive filler contact. According to embodiments, a deformable elastomeric conductive material includes: an elastomeric polymer matrix; and conductive filler material uniformly dispersed in the elastomeric polymer matrix sufficient to render the material electrically or thermally conductive. The conductive filler material comprises a plurality of substantially non-entangled particles having an aspect ratio sufficiently large to enable the particles to substantially remain in contact and/or in close proximity with adjacent particles so as to maintain conductive pathways in the material when the material is subjected to deformation up to and exceeding 10% strain.

Abstract: A circuit board has a flexible board with a principal surface, and a ground conductor provided in the flexible board. The flexible board is cut in at least one portion. The flexible board is bent using the cut portion, so that the flexible board has a first portion and a second portion at a different height from the first portion, and the ground conductor has a gap made by the cutting. At least one ground terminal is provided on the ground conductor near at least one end of the gap to electrically connect the circuit board to a ground provided in an external circuit.

Abstract: A rigid flex circuit board is provided, including a flexible circuit board, which includes a core layer, first and second cover layers, first and second bonding layers, first and second dielectric layers, and first and second superposition layers. The core layer includes first and second core circuit layers. The first and second cover layers cover a portion of the first and second core circuit layers. The first and second bonding layers cover a portion of the first and second cover layers. The first and second dielectric layers cover a portion of the first and second core circuit layers and the first and second cover layers. The first superposition layer is disposed on the first bonding layer and the first dielectric layer, and the second superposition layer is disposed on the second bonding layer and the second dielectric layer.

Abstract: A receiving device includes a shield case which is in a hollow box shape that is open on one side. The shield case reduces external interfering signals which interfere with an input signal of a broadcast wave. A printed wiring board includes a conductive portion that is electrically connected with an electronic component. A soldered portion is formed along a protrusion-free linearly extending side of an opening edge of the shield case. The soldered portion electrically connects with solder the shield case and the conductive portion.

Abstract: An electronic circuit device having a circuit stack, such as an electronic display device with a display stack, includes a protective backing having multiple layers or with a graded layer that protects the electronic circuits from both low velocity impacts and high velocity impacts. The protective backing may have an elastic layer and a viscoelastic layer or have a graded layer with a graded structure that gradually transitions between an elastic region on a first side and a viscoelastic region on a second side. The elastic first layer or region protects the display stack from low velocity impacts while the viscoelastic layer or region protects the display stack from high velocity impacts. The elastic layer or region may be arranged such that it does not add substantial stiffness to the overall circuit stack when it is flexed relatively slowly under normal use.

Abstract: The present invention is a mobile device capable of transmitting or receiving wireless signals and incorporating an FPC shielded RF signal conductor for connecting transmitter and/or receiver circuitry to an associated RF antenna or antennas. In some embodiments FCP may incorporate the antenna in an unshielded section of the FPC. In some embodiments a single FPC may provide for multiple RF carrier conductors each with their own associated shielding.

Abstract: A flexible printed circuit which includes a flexible substrate, a plurality of conductive pads, and a plurality of conductive traces that conductively connect to at least two conductive pads. The plurality of conductive pads and traces are defined on the flexible substrate. The flexible substrate has a first portion and a second portion. The first portion has at least two sets of conductive pads. The second portion has at least one set of conductive pads and is configured to conductively connect to a testing device. After the flexible printed circuit is tested, the second portion of the flexible substrate is detached from the first portion of the flexible substrate.

Abstract: An image capturing assembly for use in an endoscope includes a manifold with a base and a casing extending outward from the base, a partially enclosed housing adapted to physically attach to the manifold, a foldable LED carrier substrate capable of carrying a plurality of LEDs, a flexible optical carrier substrate capable of carrying a plurality of camera sensors, and a tip cover adapted to cover the manifold, housing, LED carrier substrate, and optical carrier substrate. The manifold includes at least one continuous channel extending throughout its length. The foldable LED carrier substrate includes a central, forward facing portion, adapted to carry at least one illuminator for a front viewing element, and a pair of arms extending proximally from the central portion. Each arm includes at least one foldable protrusion adapted to carry an illuminator for a side viewing element.

Abstract: Embodiments are directed to semiconductor packaging having reduced sized plated through hole (PTH) pads by eliminating the margin of the pad-to-PTH alignment and enabling finer traces on the core of the substrate.

Abstract: An electronic device housing may have conductive walls and planar metal internal housing structures. A display in the electronic device may have a touch sensor layer such as an array of capacitive touch sensor electrodes. The display may have display layers in a plastic chassis structure and a metal chassis structure. A display layer may have a conductive surface. Conductive tape may be used to couple the touch sensor to the metal chassis structure and a metal radio-frequency shielding structure. Conductive tape may also be used to short the conductive surface of the display layer to the internal metal housing structure. Segments of conductive tape may run along each of the four edges of a display and may overlap at display corners. Conductive foam structures may be used to short the segments to adjacent portions of the conductive housing walls.

Abstract: A server control method and a chassis controller are proposed. The server control method includes: determining whether the chassis controller is connected to a blade server when a power of the chassis controller is on; when the chassis controller is connected to the blade serve, further determining whether the blade server operates normally; when the blade server operates normally, switching the chassis controller to a slave device of the blade server, and controlling a just a bunch of disk (JBOD) system in response to a control command of the blade server.

Abstract: A flexible board includes: a base film, on which a wiring pattern is formed; a first cover film, which is located on one surface of the base film; and a second cover film, which is located on the other surface of the base film. The bending portion, which is bent when mounting the flexible board on an electronic apparatus, includes both edges on which the first cover film is formed and a central portion from which the base film is exposed.

Abstract: A L-Bending PCB includes a straight portion and a bending portion connecting to the straight portion, the straight portion has a metal substrate bottom, an insulation layer, a conductive layer and a protective layer. The insulation layer is disposed on a partial surface of the metal substrate bottom, the conductive layer is disposed on the insulation layer and the protective layer is disposed on the conductive layer.

Abstract: A flexible board includes a first sheet section including a first principal surface, a second sheet section including a second principal surface and provided in a different position from the first principal surface in a normal direction to the first principal surface, at least one first bent sheet section configured to connect ends of the first and second sheet sections, the first bent sheet section including a third principal surface not parallel to the first and second principal surfaces, and at least two second bent sheet sections each including a fourth principal surface and provided in different positions from the third principal surface in a normal direction to the third principal surface. The second bent sheet sections are positioned so as to sandwich the first bent sheet section therebetween when viewed in a plan view in the normal direction to the third principal surface.

Abstract: A substrate includes a first pattern on which terminals are formed; a second pattern on which terminals are formed; and a third pattern on which terminals are formed. A distance between a first pair of terminals which are configured by one terminal of the first pattern and one terminal of the second pattern is equal to a distance between a second pair of terminals which are configured by another terminal of the first pattern and one terminal of the third pattern, and a distance between a third pair of terminals which are configured by another of the terminals of the third pattern and another of the terminals of the second pattern is equal to a distance between a fourth pair of terminals which are configured by the other of the terminal of the third pattern and the other of the terminal of the first pattern.

Abstract: A golden finger and a board edge interconnecting device are disclosed. The golden finger includes a printed circuit board (PCB) surface layer and at least one PCB inner layer, where a metal foil of the PCB inner layer is connected to a metal foil of the PCB surface layer through a current-carrying structure, so that a current-carrying channel of the golden finger passes through the PCB surface layer and the PCB inner layer. The board edge interconnecting device includes the foregoing golden finger. In the embodiments, a current-carrying capacity of a PCB in the golden finger is increased without increasing a size and thickness of a copper foil of the PCB in the golden finger, thereby effectively improving the current-carrying capacity of the PCB in the golden finger.

Abstract: An electronic device connection system includes a first electrical device and a second electrical device. The first electrical device includes a plurality of electrical connectors disposed in, on, or about at least a portion of an exterior surface of the first electrical device. The second electrical device includes a plurality of electrical contacts disposed in, on, or about at least a portion of an exterior surface of the second electrical device. A mechanical compressor exerts a force on at least one of the first electrical device or the second electrical device such that the electrical connections on the first electrical device physically and conductively couple to the electrical contacts on the second electrical device. The device casing may function as the mechanical compressor. The electrical connectors and/or electrical contacts may include injection molded connectors that include a conductive material dispersed in a thermoplastic matrix.

Abstract: A device including a semiconductor, a substrate, and an interposer. The interposer is attached between the semiconductor and the substrate to absorb stresses between the semiconductor and the substrate.

Abstract: A flexible display is disclosed. In one aspect, the flexible display includes a flexible display panel including: a first flat portion, a bending portion connected to the first flat portion, and a second flat portion connected to the bending portion and opposing the first flat portion. The flexible display also includes a guide member fixed to the flexible display panel and arranged between the first and second flat portions and a housing supporting the flexible display panel and the guide member and arranged between the first and second flat portions. The flexible display further comprises a sliding member connected to the housing and the guide member and configured to move the second flat portion by substantially the same distance as and in an opposite direction to the first flat portion when the first flat portion is moved.

Abstract: An in-cell touch panel is disclosed. The in-cell touch panel includes an array substrate, and a plurality of signal lines arranged at one side of the array substrate. Each signal line includes a transient lead and includes one of a display pin and a touch pin connected to the transient lead. The in-cell touch panel also includes an insulating layer covering the transient lead, and a first wire formed on the insulating layer of at least one transient lead, where the first wire is electrically connected with the transient lead via a first through-hole in the insulating layer.

Abstract: A printed circuit board includes at least two rigid printed circuit board parts which are connected to one another by at least one flexible connecting part which is thinner than the rigid printed circuit board parts. The at least two rigid printed circuit board parts can be moved toward one another by bending the flexible connecting part. A groove, which is produced by the different thickness of the rigid printed circuit board parts relative to the flexible connecting part, is filled with an elastic material.

Abstract: A flexible circuit board includes a center “rigid” section, such as a printed circuit stack, and an adjoining flexible multi-layer body that are fabricated from a common interconnect layer. A transition material is included at the interface between the center rigid section and the flexible multi-layer body to minimize ripping and cracking of the interconnect layer. The transition material can also be added at stress areas not related to the interface. The transition material is attached at the interface and stress areas of the flexible circuit board in order to strengthen the flexible circuit board in general and in particular the transition material included therein. The transition material layer is formed and deposited at one or more locations on or within the flexible circuit board in order to minimize, reduce, if not prevent cracking and ripping of the flexible circuit board as it is bent, flexed and/or twisted.

Abstract: An electronic device may have a signal cable formed from a flexible printed circuit. A service loop may be formed in the signal cable. The bend may be formed in a desired location on the flexible printed circuit by contraction of an elastic member having ends attached to the flexible printed circuit. The elastic member may be conductive to carry signals and provide shielding. Structures may be attached to the flexible printed circuit to promote bending in a desired location and direction. A crease or other bending promotion feature may be applied to the flexible printed circuit at a desired bend location. Overbending prevention structures such as overmolded elastomeric structures may be applied to the flexible printed circuit at the bend. Integral strain relief features may prevent overbending of the flexible printed circuit upon exiting the elastomeric structures. Overmolded structures may serve as protective bumpers.

Abstract: A circuit panel of an electronic device is disclosed. The circuit panel includes a substantially flat surface including an active area of the electronic device; a bent border area contiguous with and extending from the active area of the substantially flat surface; and a plurality of traces coupled to the active area and routed in the bent border area.

Abstract: The present disclosure relates to a surface-treated copper foil which exhibits excellent affinity for an active material layer that is applied to the copper foil in the manufacture of a negative electrode (anode), for use in secondary lithium-ion batteries. The copper foil is plated with chromium and zinc and subsequently subjected to an organic treatment. The surface-treated copper has a surface tension of 34 to 58 dyne/cm and a surface roughness (Rz) of 0.8 to 2.5 ?m, and comprises: (a) copper foil; (b) a zinc-chromium layer plated one or both sides of the copper foil, wherein the zinc content in the zinc-chromium layer is from 10 to 120 ?g/dm2 and the chromium content in the zinc-chromium layer is from 10 to 35 ?g/dm2; and (c) an organic hydrophobic layer applied to the zinc-chromium layer.

Abstract: A flexible display panel comprises a display element (100) and a drive unit (50) disposed on a first surface (A) of a flexible base (20) and a supporting substrate (200) disposed on a second surface (B), opposite to the first surface (A), of the flexible base (20). The position of the supporting substrate (200) corresponds to a bonding position (C) of the drive unit (50). The flexible display panel can avoid a bonding alignment deviation caused by a deformation of the flexible display panel during a bonding process.

Abstract: Some features pertain to an integrated device that include a first integrated circuit (IC) package comprising a first laminated substrate, a flexible connector coupled to the first laminated substrate, and a second integrated circuit (IC) package comprising a second laminated substrate. The second laminated substrate is coupled to the flexible connector. The flexible connector includes a dielectric layer and an interconnect. The dielectric layer and the interconnect substantially extend into the first laminated substrate and the second laminated substrate. In some implementations, the dielectric layer and the interconnect of the flexible connector, contiguously extend into the first laminated substrate and the second laminated substrate. In some implementations, the dielectric layer extends into a substantial portion of the first laminated substrate. In some implementations, the dielectric layer includes polyimide (PI) layer.

Abstract: An LED tube light having LED light sources, a light tube, end cap, power supply, and an LED light bar is disclosed. LED light bar is a bendable circuit board. One end of the light tube is attached to the end cap; a power supply disposed in end cap and the LED light bar is disposed inside light tube, LED light sources are mounted on LED light bar, the LED light sources and the power supply are electrically connected. LED light bar being bendable circuit board, includes a conductive layer, electrically connected to power supply, and a dielectric layer, the two layers are stackingly arranged, dielectric layer is disposed on the conductive layer away from the LED light sources, and fixed to an inner circumferential surface of the light tube. Bendable circuit board, at two ends thereof, is not fixed to an inner circumferential surface of the light tube.

Abstract: To improve noise immunity of a semiconductor device. A wiring substrate of a semiconductor device includes a first wiring layer where a wire is formed to which signals are sent, and a second wiring layer that is mounted adjacent to the upper layer or the lower layer of the first wiring layer. The second wiring layer includes a conductor plane where an aperture section is formed at a position overlapped with a portion of the wire 23 in the thickness direction, and a conductor pattern that is mounted within the aperture section of the conductor plane. The conductor pattern includes a main pattern section (mesh pattern section) that is isolated from the conductor plane, and plural coupling sections that couple the main pattern section and the conductor plane.

Abstract: The invention discloses an insulating body (1) which is provided for receiving and/or electrically contacting at least one conductor of a cable to be connected or for fitting onto a printed circuit board, the insulating body (1) being adapted to be introduced into a dedicated chamber of a plug connector housing and having at least one recess (11) for at least one contact element (13) which can be connected to the individual conductor of the cable to be connected or to a conductor track of the printed circuit board, and including a shielding element (20) by which the contact element is electromagnetically shielded, the insulating body (1) being formed of at least one first component (2) and one second component (10), the first component (2) containing a doping so that the surface of the first component (2) can be provided with a conducting coating (6) by an electroplating process, the shielding element (20) being formed from the conducting coating of the first component (2).

Abstract: The present invention provides electronic circuits, devices and device components including one or more stretchable components, such as stretchable electrical interconnects, electrodes and/or semiconductor components. Stretchability of some of the present systems is achieved via a materials level integration of stretchable metallic or semiconducting structures with soft, elastomeric materials in a configuration allowing for elastic deformations to occur in a repeatable and well-defined way. The stretchable device geometries and hard-soft materials integration approaches of the invention provide a combination of advance electronic function and compliant mechanics supporting a broad range of device applications including sensing, actuation, power storage and communications.

Abstract: Provided is an electrode substrate, including: a substrate; a first pattern unit on the substrate; and a second pattern unit on the substrate.

Abstract: A system and method of manufacture of an integrated circuit device system includes: a carrier having a first side; a base device mounted on the first side; a first riser mounted on the first side; a second riser mounted on the first side and adjacent to the first riser; a peripheral elevated device mounted on the first riser, the peripheral elevated device having a device overhang above the base device; and an inner elevated device mounted on the second riser, the inner elevated device having the device overhang above the base device.

Abstract: A method of forming a light bulb core, and a light bulb or lamp incorporating the core. The method includes forming a heat sink having at least six working facets located equally on opposite sides of a central plane, and then mounting a light source on each of the working facets. The light sources are mounted on circuit boards, each circuit board corresponding to a respective one of the working facets. The boards are then applied to respective working facets. The bulb is composed of a screw base, an external heat sink mounted in the screw base, and the light bulb core mounted in and extending from the external heat sink. The light source comprises a plurality of light emitting diodes.

Abstract: A panel of rectangular shape comprising a plurality of electric devices spread over the panel, a control unit including a microprocessor and a power supply, drivers for driving the electric devices based on control information received from the control unit and electric wiring connecting the control unit, the drivers and the electric devices, the shape of the panel being adaptable by removing one or more parts of the panel by cutting, sawing, milling, drilling or other suitable methods, wherein the control unit and the drivers are positioned closer to a first side of the panel than to a second side opposite the first side. The drivers and electric devices are partitioned into groups that each comprises one driver that exclusively drives the electric devices in that group.

Abstract: The present disclosure is directed to a circuit board having a first imaged metal layer, a first electrically insulating layer, a second imaged metal layer, a polyimide bondply derived from 100 mole % 3,3?,4,4?-biphenyl tetracarboxylic dianhydride, 20 to 90 mole % 2,2?-bis(trifluoromethyl)benzidine, and 10 to 80 mole % 4,4?-oxydianiline, a third imaged metal layer, a second electrically insulating layer and a forth imaged metal layer. The circuit board does not have an adhesive layer between the second imaged metal layer and the polyimide bondply or the third imaged layer and the polyimide bondply.

Abstract: An apparatus includes active layers, and a first high resistive layer disposed between the active layers. The apparatus further includes second and third high resistive layers disposed on respective surfaces of the active layers, the second and third high resistive layers including first and second strip conductors, respectively, the first strip conductors being connected at an end by a first connecting conductor, the second strip conductors being connected at an end by a second connecting conductor, and the first connecting conductor being disposed perpendicularly to the second connecting conductor. The apparatus further includes first contact pads disposed on respective ends of the first connecting conductor, and second contact pads disposed on respective ends of the second connecting conductor. The apparatus further includes matching layers disposed on respective surfaces of the second and third high resistive layers.

Abstract: A method for co-designing a flip-chip and an interposer is provided. Information regarding I/O pads, power pins and IR constraints of the flip-chip is obtained. A bump planning procedure is performed to obtain a total number of micro bumps of the flip-chip according to the information, and obtain a minimum conductance of each of the power pins of the flip-chip according to a bump placement of the micro bumps of the flip-chip. A chip-interposer routing procedure is performed to obtain a Re-Distribution Layer (RDL) routing of the flip-chip and an interposer routing of the interposer according to the minimum conductance of the power pins of the flip-chip.

Abstract: The present disclosure is directed to a circuit board having a first polyimide coverlay, a first imaged metal layer, a first electrically insulating layer, a second imaged metal layer, a polyimide bondply, a third imaged metal layer, a second electrically insulating layer, a forth imaged metal layer and a second polyimide coverlay. The first polyimide coverlay, the polyimide bondply and the second polyimide coverlay are derived from 100 mole % 3,3?,4,4?-biphenyl tetracarboxylic dianhydride, 20 to 90 mole % 2,2?-bis(trifluoromethyl) benzidine, and 10 to 80 mole % 4,4?-oxydianiline.

Abstract: Electronic devices may have housings in which components are mounted. Some of the components may be sensitive to moisture. Other components may be insensitive to moisture and may form openings in a device housing that allow moisture to escape from within the housing. Components may be mounted on substrates such as printed circuit board substrates. Moisture repelling layers and moisture attracting layers may be patterned to form channels and other structures that guide moisture away from sensitive components towards insensitive components. Moisture repelling and attracting layers may also be used to limit the lateral spread of a conformal coating layer when coating components.