A signal transmission circuit packaging structure is disclosed. The signal transmission circuit packaging structure includes a body, a main circuit unit, power pins, input pins, output pins, control pins and ground pins. The main circuit unit is arranged in the center of the body. The power pins are arranged in the center of the body. The input pins are arranged at a first side of the body and are electrically connected to the main circuit unit. The output pins are arranged at a side of the body opposite to the first side and are electrically connected to the main circuit unit. The control pins are arranged at a second side of the body and are electrically connected to the main circuit unit. The ground pins are arranged at corners of the body to separate the input pins, the output pins and the control pins.

A low passive intermodulation (PIM) coaxial-to-printed circuit board (PCB) interface and method of constructing the same. According to one aspect, a coaxial-to-PCB interface couples signals between an electrical conductor trace in the PCB and an inner conductor of a coaxial structure having an insulator surrounded by an outer conductor. A metallic cylinder is inserted over the outer conductor of the coaxial structure and positioning the coaxial structure with respect to the PCB so that the outer conductor and insulator of the coaxial structure lie below a lower surface of the PCB. The inner conductor of the coaxial structure is inserted into a via extending from the lower surface of the PCB to an upper surface of the PCB. Solder is deposited in the via to provide an electrically conductive path between the electrical conductor trace of the PCB and the inner conductor of the coaxial structure.

A semiconductor package including a circuit board including a first wiring region, a die mounting region surrounding the first wiring region, and a second wiring region surrounding the die mounting region; a plurality of wiring balls on the first wiring region and the second wiring region and spaced apart from one another, the plurality of wiring balls including a plurality of first wiring balls on the first wiring region and a plurality of second wiring balls on the second wiring region; a die on the die mounting region, the die including a plurality of unit chips spaced apart from one another, and a die-through region corresponding to the first wiring region and exposing the first wiring balls; and a plurality of die balls on the die and the die mounting region, the plurality of die balls being spaced apart from one another and electrically coupled to the circuit board.

A mounting structure for mounting inductors to suppress cross talk and a stub effect due to a mounting land, and reduce deterioration of signal transmission characteristics. A first Bias-T inductor is mounted on a circuit board with one electrode terminal connected to a first mounting land with an axial direction of the first Bias-T inductor oriented perpendicular to the first mounting land and the one electrode terminal extends along the first mounting land. A second Bias-T inductor is mounted on the circuit board in the vicinity of the first Bias-T inductor with one electrode terminal connected to a second mounting land with an axial direction of the second Bias-T inductor inclined by 90° with respect to the axial direction of the first Bias-T inductor and the second Bias-T inductor is oriented perpendicular to the second mounting land and the one electrode terminal extends along the second mounting land.

A paddle card includes a printed circuit board and a twin-axial cable. The PCB includes a first signal pad on a top surface of the PCB and a second signal pad on a bottom surface of the PCB. The second signal pad is directly below the first signal pad. The twin-axial cable includes a first signal conductor coupled to the first signal pad and a second signal conductor coupled to the second signal pad.

To reduce crosstalk between bond wires, one illustrative integrated circuit includes an array of photoemitters arranged along a centerline, with adjacent photoemitters having contact pads on opposite sides of the centerline. An illustrative assembly includes an integrated circuit chip having an array of photoemitter contact pads; a printed circuit board having a recess in which the integrated circuit chip is mounted; and bond wires connecting the contact pads with respective contact pads on the printed circuit board. An illustrative cable connector includes a module that optically couples optical fibers to an array of photoemitters on an integrated circuit chip mounted to a printed circuit board. Each photoemitter has contact pads connected to the printed circuit board contact pads by bond wires, the bond wires for each photoemitter being routed in an opposite direction relative to the bond wires for any adjacent photoemitters in the array.

A circuit board includes a first circuit board portion and a second circuit board portion. The first circuit board portion is provided with a first transmission line for a low-frequency signal or a low-speed signal, and the second circuit board portion is provided with a second transmission line for a high-frequency signal or a high-speed signal. The second circuit board portion is located on the first circuit board portion in a positional relationship in which the first transmission line and the second transmission line are side-by-side with each other. With this structure, signal leakage and interference between different signals are reduced or prevented in a line that transmits signals with different frequencies and different transmission speeds.

Methods, systems, and devices for crosstalk cancellation for signal lines are described. In some examples, a device (e.g., a host device or a memory device) may generate a first signal and may invert the first signal to obtain an inverted first signal. The device may obtain a second signal based on attenuating a first range of frequencies of the inverted first signal and a second range of frequencies of the inverted first signal, where the first range of frequencies is below a first threshold frequency and the second range of frequencies is above a second threshold frequency that is greater than the first threshold frequency. The device may transmit the first signal via a first signal line of a set of signal lines and the second signal line via a second signal line of the set of signal lines.

A method of fabricating an electromagnet includes obtaining a first flexible PCB that includes one or more first conductive coiled traces and obtaining a second flexible PCB that includes one or more second conductive coiled traces. The first flexible PCB is bent into a shape having at least one curve or corner. With the first flexible PCB having been bent into the shape, the second flexible PCB is then bent into the shape: the second flexible PCB is positioned adjacent to the first flexible PCB to conform with the first flexible PCB. The second flexible PCB may substantially surround the first flexible PCB. An electrostatic deflector may be disposed concentrically with the first and second flexible PCBs.

A multi-layer printed circuit board having a first landing pad in a first layer and along a first axis arranged to receive a positive signal and a second landing pad in the first layer and along a second axis that is spaced away from the first axis longitudinally in the first layer and where the second landing pad arranged to receive a negative signal. A first buried in a second layer and along the first axis is spaced away from the first landing pad along the first axis. A second buried in the second layer and along the second axis is spaced away from the second landing pad along the second axis. A first signal connector provides a first electrical connection between the first landing pad and the second buried via and a second signal connector provides a second electrical connection between the second landing pad and the first buried via.