Abstract: In some embodiments, an apparatus includes a first substrate, a second substrate, a first coupler, and a second coupler. The first substrate is formed from a first material and includes an electrical pad. The second substrate is formed from a second material and includes an electrical pad. The first coupler is configured to mechanically couple the first substrate to the second substrate without a soldered connection. The second coupler includes a first end portion, configured to be soldered to the electrical pad of the first substrate, and a second end portion, configured to be soldered to the electrical pad of the second substrate. The second coupler configured to electrically couple the first substrate to the second substrate.

Abstract: High density electronic device assemblies and techniques for forming high density electronic device assemblies are disclosed. These assemblies and techniques can be used to form compact electronic devices. In one embodiment, substrate arrangements that include a multiple-part substrate can be used to form a high density electronic device assembly. In another embodiment, one or more clips can be used in a high density electronic device assembly to provide mechanical and electrical interconnection between electrical structures that are to be removably coupled together as parts of the high density electronic device assembly. In still another embodiment, a removable cap (and a method for forming the removable cap) can be used for an electronic device housing.

Abstract: A communication module includes: a plurality of receiving filters that are connected between an antenna terminal and a receiving terminal and have a receive band different from each other; and a passive circuit that is commonly connected to at least two of the plurality of receiving filters and makes a receive band of one of said at least two of the plurality of receiving filters suppressed when making another receive band of said at least two of the plurality of receiving filters transitable, wherein receiving terminals of said at least two of the plurality of receiving filters are commonalized through the passive circuit.

Abstract: An example of an electronic device includes a mother board and a slave board. The mother board is electrically connected to the slave board via one cable. The electronic device further includes a first filter element and a second filter element. The first filter element is connected between a first end of the cable and ground. The second filter element is connected between a second end of the cable and the ground. The first filter element and the second filter element cooperatively filter electromagnetic waves generated by the cable.

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

Abstract: The present invention relates to an electric and/or electronic circuit including a printed circuit board (20), at least one separate circuit board (10) and at least one power connector (12) for said printed circuit board (20). The at least one power connector (12) is connected or connectable to a corresponding counterpart. A number of electric and/or electronic components (22) is sold at the separate circuit board (10). The at least one separate circuit board (10) is connected to the printed circuit board (20) by a number of solder joints (16). The solder joints (16) are connected to the separate circuit board (10) by a through-hole-technology. The solder joints (16) are connected to the printed circuit board (20) by SMD (surface mount device) technology. At least one power connector (12) is fastened at the separate circuit board (10) by the through-hole-technology.

Abstract: This is directed to connecting two or more elements using an intermediate element constructed from a material that changes between states. An electronic device can include one or more components constructed by connecting several elements. To provide a connection having a reduced or small size or cross-section and construct a component having high tolerances, a material can be provided in a first state in which it flows between the elements before changing to a second state in which it adheres to the elements and provides a structurally sound connection. For example, a plastic can be molded between the elements. As another example, a composite material can be brazed between the elements. In some cases, internal surfaces of the elements can include one or more features for enhancing a bond between the elements and the material providing the interface between the elements.

Abstract: This interposer provides interconnections between stacked layers of circuits, which may include integrated circuits, PC boards, and hybrid substrates. Fabricated as an integrated circuit itself using readily available process steps, this interposer uses single and dual-damascene layers to increase the density of usable interconnections on both its top and bottom surfaces. Access from a top surface to a bottom surface is provided by conductive through-vias that may be placed at a high density. For even greater density, interconnections may be routed within silicon trenches, while damascene processing reduces the total number of steps required for fabrication. The described techniques may be used to create double-sided integrated circuits.

Abstract: A multilayer wiring board includes a signal electrode, a first power supply electrode, and a ground electrode, which are connected to a first element that outputs a signal, an electrode connected to a second element that receives the signal, a ground layer that serves as a return path for a return current of the signal, a first power supply layer that is disposed adjacent to the ground layer with a dielectric layer interposed therebetween and supplies electric power to the first element, and a second power supply layer that is provided independently of the first power supply layer and supplies electric power to the second element. The first power supply layer causes the return current to return to the first element through the first power supply electrode as a displacement current between the ground layer and the first power supply layer.

Abstract: A semiconductor device comprising a plurality of semiconductor chips and a plurality of through-line groups is disclosed. Each of the through-line groups consists of a unique number of through-lines. The numbers associated with the through-line groups are mutually coprime to each other. When one of the through-lines is selected for the each through-line group, one of the semiconductor chip is designated by a combination of the selected through-lines of the plurality of the through-line groups.

Abstract: An interface module has an integrated component for replacing a component on a circuit board, the terminal contacts on the bottom side of the interface module being designed as provided for the contacts of the component on the circuit board, the interface module being divided into an adaptor part as a base module and a protocol converter part as a tool access module.

Abstract: In an example embodiment, a circuit interconnect includes a first printed circuit board (PCB), a second PCB, a spacer, and an electrically conductive solder joint. The first PCB includes a first electrically conductive pad. The second PCB includes a second electrically conductive pad. The spacer is configured to position the first PCB relative to the second PCB such that a space remains between the first PCB and the second PCB after the first electrically conductive pad and the second electrically conductive pad are conductively connected in a soldering process. The electrically conductive solder joint conductively connects the first electrically conductive pad and the second electrically conductive pad.

Abstract: An isolated switching power converter includes a power isolation transformer having at least one primary winding, at least one secondary winding and a plurality of sides, a first power board mechanically coupled to a first side of the transformer, and a second power board mechanically coupled to a second side of the transformer. The first power board includes a primary side circuit electrically coupled to the at least one primary winding, and the second power board includes a secondary side circuit electrically coupled to the at least one secondary winding.

Abstract: A multi-layer printed circuit board has a number of landing pads that are configured to engage a connector secured thereto. Between the landing pads associated with different signals is at least one micro via that is electrically connected to a ground plane on an outer surface of the multi-layer printed circuit board, and a ground plane on an inner layer of the multi-layer printed circuit board.

Abstract: A DIMM riser card that includes a PCB having a first edge, a second edge, and one or more faces. The first edge of the PCB is configured for insertion into a main board DIMM socket. The first edge includes electrical traces that electrically couple to a memory bus. The DIMM riser card includes an angled DIMM socket mounted on one face of the PCB, where the angled DIMM socket is configured to accept a DIMM at an angle not perpendicular to the PCB and electrically couple the DIMM to the memory bus. The DIMM riser card includes a straddle mount DIMM socket mounted on the second edge of the PCB. The straddle mount DIMM socket is configured to accept a DIMM and electrically couple the DIMM to the memory bus through the electrical traces on the first edge of the PCB.

Abstract: Microelectronic packages with leadframes, including leadframes configured for stacked die packages, and associated systems and methods are disclosed. A system in accordance with one embodiment includes a support member having first package bond sites electrically coupled to leadframe bond sites. A microelectronic die can be carried by the support member and electrically coupled to the first packaged bond sites. A leadframe can be attached to the leadframe bond sites so as to extend adjacent to the microelectronic die, with the die positioned between the leadframe and the support member. The leadframe can include second package bond sites facing away from the first package bond sites. An encapsulant can at least partially surround the leadframe and the microelectronic die, with the first and second package bond sites accessible from outside the encapsulant.

Abstract: A packaging board of the type having board terminals soldered on a printed board and including an insulation support member made of a resin disposed on a printed board having tubular support portions configured to receive board terminals, visual recognition windows configured for visually recognizing soldering portions of the board terminals inserted into the printed board through the windows, and engaging portions that engage the board terminals and define insertion amounts of the board terminals.

Abstract: An electronic module package that includes an electronic module configured to receive input signals and process the input signals to provide output signals. The module package also includes an interposer having a board substrate with opposite mounting and substrate surfaces. The mounting surface has a mounting array of electrical contacts. The substrate surface has a module array of electrical contacts and a component array of electrical contacts. The electronic module is attached to the substrate surface and electrically coupled to the module array. The interposer includes first conductive pathways that electrically couple the module array and the mounting array and also includes second conductive pathways that electrically couple the module array and the component array.

Abstract: A printed circuit includes a number of conductive wires. Each of the conductive wires includes a first conductive wire section, a second conductive wire section, and a first connection section. The first connection section includes a first end and a second end opposite to the first end, the first end of the first connection section is connected to the first conductive wire section, and the second end of the first connection section is connected to the second conductive wire section. An angle between the first conductive wire section and the first connection section can be in a range from about 90 degrees to about 180 degrees.

Abstract: This relates to systems and methods for providing one or more vias through a module of an electrical system. For example, in some embodiments, the module can include one or more passive elements and/or active of the electrical system around which a packaging has been plastic molded. The module can be stacked under another component of the electrical system. Vias can then be provided that extend through the module. The vias can include, for example, electrically conductive pathways. In this manner, the vias can provide electrical pathways for coupling the component stacked on top of the module to other entities of an electronic device including the electrical system. For example, the component can be coupled to other entities such as other components, other modules, printed circuit boards, other electrical systems, or to any other suitable entity.

Abstract: A folded stacked package and a method of manufacturing the same are provided. The folded stacked package includes a flexible board or substrate comprising first, second and third device packaging units, and first and second folding unit units. The flexible board has wiring patterns formed thereon; one or more active devices disposed in at least one of the first, second, and third device packaging units; and one or more passive devices disposed on a surface of each of the first and second device packaging units. The passive devices include one or more first passive devices disposed on the surface of the first device packaging unit and one or more second passive devices disposed on the surface of the second device packaging unit. The first and second passive devices do not overlap each other when the flexible board is folded at the folding unit.

Abstract: A printed circuit board (PCB) includes two power supply units, a central processing unit (CPU), two inductors and a temperature compensation resistor. One of the inductor is electrically connected between one power supply unit and the CPU, the other inductor is electrically connected between another power supply unit and the CPU. The temperature compensation resistor is electrically connected between the power supply units and ground, and is positioned between the two inductors to adjust output voltage from the CPU.

Abstract: A serial advanced technology attachment (SATA) dual-in-line memory module (DIMM) includes a circuit board. A control chip and a number of storage chips are arranged on the circuit board. First and second extending boards extend from an end of the circuit board and are coplanar with the circuit board. A space is defined between the first and the second extending boards. A first edge connector is arranged on the first extending board and connected to the control chip. A second edge connector is arranged on bottom edges of the second extending board and the circuit board. A third edge connector is arranged on a top edge of the circuit board opposite to the bottom edge of the circuit board.

Abstract: A fixing mechanism includes a base, a substrate and a latch. The base includes a constraining component and a contacting component. The substrate is slidably disposed on the base. The substrate includes a body, a fixing hole structure and a connecting portion. The base and the body respectively hold circuit boards. The fixing hole structure is disposed on the body for sheathing the constraining component. The fixing hole structure includes a first opening and a second opening, the second opening is connected to the first opening in a linearly stretching manner. The latch is rotatably disposed on the substrate. The latch includes a bar and a driving portion. The driving portion is disposed on an end of the bar and movably contacts against the contacting component. The driving portion slides relative to the contacting component with rotation of the bar to connect the connectors of the circuit boards.

Abstract: A module is configured for connection with a microelectronic assembly having terminals and a microelectronic element. The module includes a circuit panel bearing conductors configured to carry command and address information, co-support contacts coupled to the conductors, and module contacts coupled to the conductors. The co-support contacts include first contacts having address and command information assignments arranged in a first predetermined arrangement for connection with a first type of microelectronic assembly in which the microelectronic element is configured to sample command and address information coupled thereto through the first contacts at a first sampling rate, and in a second predetermined arrangement for connection with a second type of the microelectronic assembly in which the microelectronic element is configured to sample the command and address information coupled thereto through a subset of the first contacts at a second sampling rate greater than the first sampling rate.

Abstract: A rack-mounted console module includes a lower unit slideably mounted on a rail and an upper unit pivotally coupled to the lower unit. A locking mechanism includes a first part moveably disposed in the lower unit and a second part fixedly disposed on the rail. When the upper unit is closed and the lower unit slides along the rail to a target position, the first part of the locking mechanism changes from a released state to a locked state where it engages the second part of the locking mechanism to lock the lower unit. When the upper unit is opened, the first part changes from the locked state to a ready-to-released state. When the upper unit is subsequently closed, the first part changes from the ready-to-released state to a released state where it disengages from the second part, and the console module can be slid back into the rack.

Abstract: An electronic device provided with a plurality of circuit boards uses a support member for supporting the circuit boards as the transmission path of a wireless signal. For example, the electronic device is provided with a first printed circuit board for processing a millimeter-wave signal, a second printed circuit board which is signal-coupled to the printed circuit board and receives the millimeter-wave signal to subject the received signal to signal processing, and a waveguide which is disposed with a predetermined dielectric constant between the printed circuit boards, wherein the waveguide constitutes the dielectric transmission path, and the waveguide supports the printed circuit boards. This configuration makes it possible to receive the electromagnetic wave based on a millimeter-wave signal radiated from one end of the waveguide constituting the dielectric transmission path, at the other end thereof.

Abstract: A multi-chip module includes a chip stack package including at least one pair of stacked dies, the dies having overlapping opposing faces, and at least one capacitive proximity communication (CPC) interconnect between the pair of stacked dies. The CPC interconnect includes a first capacitor plate at a first one of the overlapping opposing faces and a second capacitor plate at a second one of the overlapping opposing faces spaced from and aligned with the first capacitor plate. The CPC interconnect further includes an inductive element connected in series with the first capacitor plate and second capacitor plate, wherein the capacitor plates form part of a capacitor and the capacitor cooperates with the inductor element to form a LC circuit having a resonant frequency.

Abstract: A component is configured for connection with a microelectronic assembly having terminals and a microelectronic element connected with the terminals. The component includes a support structure bearing conductors configured to carry command and address information, and a plurality of contacts coupled to the conductors and configured for connection with the terminals. The contacts have address and command information assignments arranged in a first predetermined arrangement for connection with a first type of microelectronic assembly in which the microelectronic element is configured to sample command and address information coupled thereto through the contacts at a first sampling rate, and in a second predetermined arrangement for connection with a second type of microelectronic assembly in which the microelectronic element is configured to sample the command and address information coupled thereto through a subset of the contacts at a second sampling rate greater than the first sampling rate.

Abstract: An electric apparatus is adapted to be electrically coupled to a target platform. The electric apparatus includes a first printed circuit including a first surface parallel to a first plane and a second surface parallel to a second plane perpendicular to the first plane. The first surface has a first area and the second surface has a second area smaller than the first area. A multitude of conductive traces are formed in a layer of the first printed circuit parallel to the first plane. First and second contact regions respectively overlay first and second portions of the second surface. The first and second contact regions are electrically connected to first and second ones of the multitude of conductive traces respectively. The first printed circuit is coupled to the target platform at the first and second contact regions when the first printed circuit is electrically coupled to the target platform.

Abstract: Various circuit board sockets and methods of manufacturing and using the same are disclosed. In one aspect, a method of manufacturing is provided that includes forming a socket that is operable to receive a circuit board. The socket includes a surface for seating a first portion of a circuit board, a floor and a first support structure projecting away from the floor to support a second portion of the circuit board. The support structure includes a plurality of nested frames.

Abstract: An integrated structure for interconnection of electrical components is provided. In one embodiment, the integrated structure includes a through mold via (TMV) module having a substrate and at least one component coupled to the substrate. A flexible printed circuit board (flex-PCB) is integrated with the substrate of the TMV module. A TMV is provided through a body of the module to allow the flex-PCB to couple with a logic board.

Abstract: A motherboard assembly includes a motherboard and an expansion card. The motherboard includes an expansion slot, a storage device interface, a power connector, and a central processing unit (CPU). The expansion slot includes a protrusion, first signal pins connected to the CPU, first power pins connected to the power connector. The expansion card includes a circuit board. A storage unit, a display unit, a power circuit, and a serial advanced technology attachment (SATA) connector connected to the storage unit and the storage device interface of the motherboard are all arranged on the circuit board. A notch is defined in a bottom edge of the circuit board, to receive the protrusion. An edge connector is arranged on a bottom edge of the circuit board and includes second power pins connected to the power circuit, and second signal pins connected to the display unit.

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

Abstract: The present invention provides a laminate printed board having a novel structure that is able to ensure alignment accuracy of the interboard terminals soldered to one printed board and that is also able to achieve a simplification of the process of soldering the interboard terminals. Through-hole lines in which a plurality of through-holes extend in lines are formed on a first printed board. Additionally, a press-fitting fastener hole is formed within the through-hole lines and a first end of an interboard terminal is press-fitted and fastened to the press-fitting fastener hole. Additionally, first ends of others of the interboard terminals are inserted through and flow soldered to through-holes on the first printed board.

Abstract: A motherboard assembly includes a serial advanced technology attachment dual-in-line memory module (SATA DIMM) with a circuit board, a memory slot, a platform controller hub (PCH), a storage device interface, and a storage controller connected to the PCH and the storage device interface. An edge connector is set on a bottom edge of the circuit board. A port is arranged on the circuit board, and connected to the storage chips and the storage device interface, enabling a motherboard to communicate with the SATA DIMM module.

Abstract: The present disclosure describes techniques for scalable embedded memory programming. In some aspects data is received at a first communication interface from a host device, at least a portion of the data is stored to a memory device supported by a printed circuit board, and the data is transmitted to a target device via a second communication interface.

Abstract: A mounting apparatus for an expansion card includes a bottom plate, a circuit board, and mounting bracket. The bottom plate defines mounting hole. The circuit board is secured to the bottom plate, and a gap is defined between the bottom plate and the circuit board. The mounting bracket includes a base secured to the bottom plate. The base includes two positioning pieces and an elastically deformable mounting portion. The two positioning pieces are received in the gap, to prevent the mounting bracket from moving along a first direction substantially perpendicular to the bottom plate, and the elastically deformable mounting portion is engaged in the mounting hole, to prevent the mounting bracket from moving along a second direction substantially parallel to the bottom plate.

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

Abstract: A connector for connecting surface mount devices, such as light emitting diodes (LEDs), to printed circuit boards (PCBs). The connector may be prepackage with an LED assembly or on a PCB to which the LED assembly will be mounted. Connection complexity can be moved from the PCB to the connector, and LED assemblies may be customized differently for different customers. One to many and many to one connections are readily supported with variations on the connector.

Abstract: An electronic component to be mounted on a substrate, including an electronic component-side land that faces a substrate-side land provided on the substrate when the electronic component is mounted on the substrate. A non-soldered region is provided on a surface of the electronic component-side land, facing the substrate-side land, so that a shape of the substrate-side land is different from a shape of the electronic component-side land facing the substrate-side land.

Abstract: A microelectronic assembly includes a dielectric element having first and second surfaces, first and second apertures extending between the first and second surfaces and defining a central region of the first surface between the first and second apertures, first and second microelectronic elements, and leads extending from contacts exposed at respective front surfaces of the first and second microelectronic elements to central terminals exposed at the central region. The front surface of the first microelectronic element can face the second surface of the dielectric element. The front surface of the second microelectronic element can face a rear surface of the first microelectronic element. The contacts of the second microelectronic element can project beyond an edge of the first microelectronic element. At least first and second ones of the leads can electrically interconnect a first central terminal of the central terminals with each of the first and second microelectronic elements.

Abstract: A system includes a microelectronic assembly having terminals and a microelectronic element, and a component for connection with the microelectronic assembly. The component includes a support structure bearing conductors configured to carry command and address information, and contacts coupled to the conductors and connected with the terminals of the microelectronic assembly. The contacts have address and command information assignments arranged in a first predetermined arrangement for connection with a first type of microelectronic assembly in which the microelectronic element is configured to sample command and address information coupled thereto through the contacts at a first sampling rate, and in a second predetermined arrangement for connection with a second type of microelectronic assembly in which the microelectronic element is configured to sample the command and address information coupled thereto through a subset of the contacts at a second sampling rate greater than the first sampling rate.

Abstract: Provided is a printed circuit board stack having a structure that connects between printed wirings of printed circuit boards that are arranged so as to face each other across a gap. A first printed circuit board and a second printed circuit board are arranged so as to face each other across a gap; a first fork terminal soldered to a printed wiring is vertically provided on the first printed circuit board, whereas a second fork terminal soldered to a printed wiring is vertically provided on the second printed circuit board. The printed wiring of the first printed circuit board and the printed wiring of the second printed circuit board are electrically connected to each other via a conductive member with a pair of connection portions that each are pressure-contacted between pressure contact blades of a respective one of the first fork terminal and the second fork terminal.

Abstract: Electrical components in an electronic device are mounted on substrates such as printed circuits. Printed circuits contain signal paths formed from metal traces. The signal lines in the signal paths of the printed circuits are coupled together using electrical connection structures such as printed circuit board-to-board connectors, contacts joined by anisotropic conductive film, or contacts joined using solder. Electrical connection structures may be surrounded by conductive resilient ring-shaped structures such as conductive foam structures or spring structures. The conductive foam structures may be provided with a metal layer with which the conductive foam structures are soldered to a ring of metal on a printed circuit. Strain relief structures may be formed from an elastomeric ring that surrounds the electrical connection structures or an overmolded plastic structure.

Abstract: A chip stacking structure including a plurality of microbump structures, a plurality of first substrates, at least one first space layer, a plurality of second substrates and at least one second space layer is provided. The first substrates are stacked upon each other by a portion of the microbump structures, and each of the first substrates includes at least one first redistribution layer. The first space layer is located between the stacked first substrates. The second substrates are stacked on at least one of the first substrates by another portion of the microbump structures, and each of the second substrates includes at least one second redistribution layer. The second space layer is located between the stacked first and second substrates. The first redistribution layers, the second redistribution layers and the microbump structures form a plurality of impedance elements, and the impedance elements provide a specific oscillation frequency.

Abstract: A flat flexible-printed-circuit cable is provided that is designed to route high speed digital bus signals across various printed circuit boards without substantial signal attenuation. The flat flexible-printed-circuit cable can include a polyimide substrate; a first layer of copper being a solid ground plane over the polyimide substrate; a dielectric continuous layer; a second layer of copper being a routing layer for high speed digital bus signals across various printed circuit boards; and connectors at ends of the cable having ground terminals to which the first layer contacts.

Abstract: Provided is a flexible substrate wherein a connection portion between the flexible substrate and an electric circuit board meets requirements of narrow wiring pitch and low resistance at the connection portion. An electric circuit structure, which has the flexible substrate and the electric circuit board to which the flexible substrate is connected, is also provided. A wiring pattern (22) is formed on a flexible base film (21), a connection terminal (25) connected electrically to an electrode terminal of another electric circuit board is arranged at an end portion of the wiring pattern (22), and the connection terminal (25) includes wide connection terminals (25b, 25c) having a terminal width extending across plural lines of the wiring pattern (22).

Abstract: A laminate circuit board with a multi-layer circuit structure which includes a substrate, a first circuit metal layer, a second circuit metal layer, a first nanometer plating layer, a second nanometer plating layer and a cover layer is disclosed. The first circuit metal layer is embedded in the substrate or formed on at least one surface of the substrate which is smooth. The first nanometer plating layer with a smooth surface covers the first circuit metal layer. The second nanometer plating layer is formed on the other surface of the substrate and fills up the opening in the cover layer to electrically connect the first circuit metal layer. The junction adhesion is improved by the chemical bonding between the nanometer plating layer and the cover layer/the substrate. Therefore, the circuit metal layer does not need to be roughened and the density of the circuit increases.

Abstract: An electric apparatus for connecting to a first printed circuit includes a second printed circuit, which includes a first surface substantially parallel to a first plane and a second surface substantially parallel to a second plane perpendicular to the first plane. The first surface includes a first area and the second surface includes a smaller second area. The second printed circuit includes conductive traces in a layer of the second printed circuit. The electric apparatus further includes first and second conductive pins including first and second longitudinal axes, respectively. First and second notches in the second printed circuit include respective first and second openings through the second surface adapted to receive portions of the first and second pins and adapted to electrically connect the pins to first and second respective ones of the conductive traces. The first and second longitudinal axes are installed substantially parallel to the first plane.